00.00.00 GENERAL 
01.00.00 Communication, education, history, and philosophy 
01.10.-m Announcements, news, and organizational activities 
01.10.Cr Announcements, news, and awards 
01.10.Fv Conferences, lectures, and institutes 
01.10.Hx Physics organizational activities 
01.20.+x Communication forms and techniques (written, oral, electronic, etc.) 
01.30.-y Physics literature and publications 
01.30.Bb Publications of lectures (advanced institutes, summer schools, etc.) 
01.30.Cc Conference proceedings 
01.30.Ee Monographs and collections 
01.30.Kj Handbooks, dictionaries, tables, and data compilations 
01.30.L- Physics laboratory manuals 
01.30.la Secondary schools 
01.30.lb Undergraduate schools 
01.30.M- Textbooks 
01.30.mm Textbooks for graduates and researchers 
01.30.mp Textbooks for undergraduates 
01.30.mr Textbooks for students in grades 9-12 
01.30.mt Textbooks for students in grades K-8 
01.30.Os Books of general interest to physics teachers 
01.30.Rr Surveys and tutorial papers; resource letters 
01.30.Tt Bibliographies 
01.30.Vv Book reviews 
01.30.Xx Publications in electronic media (for the topic of electronic publishing, see 01.20.+x)
01.40.-d Education 
01.40.Di Course design and evaluation 
01.40.E- Science in school 
01.40.eg Elementary school 
01.40.ek Secondary school 
01.40.Fk Research in physics education 
01.40.G- Curricula and evaluation 
01.40.gb Teaching methods and strategies 
01.40.gf Theory of testing and techniques 
01.40.Ha Learning theory and science teaching 
01.40.J- Teacher training 
01.40.jc Preservice training 
01.40.jh Inservice training 
01.50.-i Educational aids 
01.50.F- Audio and visual aids 
01.50.fd Audio devices 
01.50.ff Films; electronic video devices 
01.50.fh Posters, cartoons, art, etc. 
01.50.H- Computers in education 
01.50.ht Instructional computer use 
01.50.hv Computer software and software reviews 
01.50.Kw Techniques of testing 
01.50.Lc Laboratory computer use (see also 01.50.Pa)
01.50.My Demonstration experiments and apparatus 
01.50.Pa Laboratory experiments and apparatus (see also 01.50.Lc)
01.50.Qb Laboratory course design, organization, and evaluation 
01.50.Rt Physics tournaments and contests 
01.50.Wg Physics of toys 
01.50.Zv Errors in physics classroom materials 
01.52.+r National and international laboratory facilities 
01.55.+b General physics 
01.60.+q Biographies, tributes, personal notes, and obituaries 
01.65.+g History of science 
01.70.+w Philosophy of science 
01.75.+m Science and society (for science and government, see 01.78.+p)
01.78.+p Science and government (funding, politics, etc.) 
01.80.+b Physics of games and sports 
01.85.+f Careers in physics and science 
01.90.+g Other topics of general interest (restricted to new topics in section 01) 
02.00.00 Mathematical methods in physics 
02.10.-v Logic, set theory, and algebra 
02.10.Ab Logic and set theory 
02.10.De Algebraic structures and number theory 
02.10.Hh Rings and algebras 
02.10.Kn Knot theory 
02.10.Ox Combinatorics; graph theory 
02.10.Ud Linear algebra 
02.10.Xm Multilinear algebra 
02.10.Yn Matrix theory 
02.20.-a Group theory (for algebraic methods in quantum mechanics, see 03.65.Fd; for symmetries in elementary particle physics, see 11.30.-j)
02.20.Bb General structures of groups 
02.20.Hj Classical groups 
02.20.Qs General properties, structure, and representation of Lie groups 
02.20.Rt Discrete subgroups of Lie groups 
02.20.Sv Lie algebras of Lie groups 
02.20.Tw Infinite-dimensional Lie groups 
02.20.Uw Quantum groups 
02.30.-f Function theory, analysis 
02.30.Cj Measure and integration 
02.30.Em Potential theory 
02.30.Fn Several complex variables and analytic spaces 
02.30.Gp Special functions 
02.30.Hq Ordinary differential equations 
02.30.Ik Integrable systems 
02.30.Jr Partial differential equations 
02.30.Ks Delay and functional equations 
02.30.Lt Sequences, series, and summability 
02.30.Mv Approximations and expansions 
02.30.Nw Fourier analysis 
02.30.Oz Bifurcation theory (see also 47.20.Ky in fluid dynamics)
02.30.Px Abstract harmonic analysis 
02.30.Rz Integral equations 
02.30.Sa Functional analysis 
02.30.Tb Operator theory 
02.30.Uu Integral transforms 
02.30.Vv Operational calculus 
02.30.Xx Calculus of variations 
02.30.Yy Control theory 
02.30.Zz Inverse problems 
02.40.-k Geometry, differential geometry, and topology (see also section 04 Relativity and gravitation)
02.40.Dr Euclidean and projective geometries 
02.40.Ft Convex sets and geometric inequalities 
02.40.Gh Noncommutative geometry 
02.40.Hw Classical differential geometry 
02.40.Ky Riemannian geometries 
02.40.Ma Global differential geometry 
02.40.Pc General topology 
02.40.Re Algebraic topology 
02.40.Sf Manifolds and cell complexes 
02.40.Tt Complex manifolds 
02.40.Vh Global analysis and analysis on manifolds 
02.40.Xx Singularity theory (see also 05.45.-a Nonlinear dynamics and chaos)
02.40.Yy Geometric mechanics (see also 45.20.Jj in formalisms in classical mechanics)
02.50.-r Probability theory, stochastic processes, and statistics (see also section 05 Statistical physics, thermodynamics, and nonlinear dynamical systems)
02.50.Cw Probability theory 
02.50.Ey Stochastic processes 
02.50.Fz Stochastic analysis 
02.50.Ga Markov processes 
02.50.Le Decision theory and game theory 
02.50.Ng Distribution theory and Monte Carlo studies 
02.50.Sk Multivariate analysis 
02.50.Tt Inference methods 
02.60.-x Numerical approximation and analysis 
02.60.Cb Numerical simulation; solution of equations 
02.60.Dc Numerical linear algebra 
02.60.Ed Interpolation; curve fitting 
02.60.Gf Algorithms for functional approximation 
02.60.Jh Numerical differentiation and integration 
02.60.Lj Ordinary and partial differential equations; boundary value problems 
02.60.Nm Integral and integrodifferential equations 
02.60.Pn Numerical optimization 
02.70.-c Computational techniques; simulations (for quantum computation, see 03.67.Lx; for computational techniques extensively used in subdivisions of physics, see the appropriate section; for example, see 47.11.-j Computational methods in fluid dynamics)
02.70.Bf Finite-difference methods 
02.70.Dh Finite-element and Galerkin methods 
02.70.Hm Spectral methods 
02.70.Jn Collocation methods 
02.70.Ns Molecular dynamics and particle methods 
02.70.Pt Boundary-integral methods 
02.70.Rr General statistical methods 
02.70.Ss Quantum Monte Carlo methods 
02.70.Tt Justifications or modifications of Monte Carlo methods 
02.70.Uu Applications of Monte Carlo methods (see also 02.50.Ng in probability theory, stochastic processes, and statistics, and 05.10.Ln in statistical physics)
02.70.Wz Symbolic computation (computer algebra) 
02.90.+p Other topics in mathematical methods in physics (restricted to new topics in section 02) 
03.00.00 Quantum mechanics, field theories, and special relativity (see also section 11 General theory of fields and particles)
03.30.+p Special relativity 
03.50.-z Classical field theories 
03.50.De Classical electromagnetism, Maxwell equations (for applied classical electromagnetism, see 41.20.-q)
03.50.Kk Other special classical field theories 
03.65.-w Quantum mechanics [see also 03.67.-a Quantum information; 05.30.-d Quantum statistical mechanics; 31.30.J- Relativistic and quantum electrodynamics (QED) effects in atoms, molecules, and ions in atomic physics]
03.65.Ca Formalism 
03.65.Db Functional analytical methods 
03.65.Fd Algebraic methods (see also 02.20.-a Group theory)
03.65.Ge Solutions of wave equations: bound states 
03.65.Nk Scattering theory 
03.65.Pm Relativistic wave equations 
03.65.Sq Semiclassical theories and applications 
03.65.Ta Foundations of quantum mechanics; measurement theory (for optical tests of quantum theory, see 42.50.Xa)
03.65.Ud Entanglement and quantum nonlocality (e.g. EPR paradox, Bell's inequalities, GHZ states, etc.) (for entanglement production and manipulation, see 03.67.Bg; for entanglement measures, witnesses etc., see 03.67.Mn; for entanglement in Bose-Einstein condensates, see 03.75.Gg)
03.65.Vf Phases: geometric; dynamic or topological 
03.65.Wj State reconstruction, quantum tomography 
03.65.Xp Tunneling, traversal time, quantum Zeno dynamics 
03.65.Yz Decoherence; open systems; quantum statistical methods (see also 03.67.Pp in quantum information; for decoherence in Bose-Einstein condensates, see 03.75.Gg)
03.67.-a Quantum information (see also 42.50.Dv Quantum state engineering and measurements; 42.50.Ex Optical implementations of quantum information processing and transfer in quantum optics)
03.67.Ac Quantum algorithms, protocols, and simulations 
03.67.Bg Entanglement production and manipulation (for entanglement in Bose-Einstein condensates, see 03.75.Gg)
03.67.Dd Quantum cryptography and communication security 
03.67.Hk Quantum communication 
03.67.Lx Quantum computation architectures and implementations 
03.67.Mn Entanglement measures, witnesses, and other characterizations (see also 03.65.Ud Entanglement and quantum nonlocality; 42.50.Dv Quantum state engineering and measurements in quantum optics)
03.67.Pp Quantum error correction and other methods for protection against decoherence (see also 03.65.Yz Decoherence; open systems; quantum statistical methods; for decoherence in Bose-Einstein condensates, see 03.75.Gg)
03.70.+k Theory of quantized fields (see also 11.10.-z Field theory)
03.75.-b Matter waves (for atom interferometry, see 37.25.+k; see also 67.85.-d ultracold gases, trapped gases in quantum fluids and solids)
03.75.Be Atom and neutron optics 
03.75.Dg Atom and neutron interferometry 
03.75.Gg Entanglement and decoherence in Bose-Einstein condensates 
03.75.Hh Static properties of condensates; thermodynamical, statistical, and structural properties 
03.75.Kk Dynamic properties of condensates; collective and hydrodynamic excitations, superfluid flow 
03.75.Lm Tunneling, Josephson effect, Bose-Einstein condensates in periodic potentials, solitons, vortices, and topological excitations 
03.75.Mn Multicomponent condensates; spinor condensates 
03.75.Nt Other Bose-Einstein condensation phenomena 
03.75.Pp Atom lasers 
03.75.Ss Degenerate Fermi gases 
04.00.00 General relativity and gravitation (for astrophysical aspects, see 95.30.Sf Relativity and gravitation; for relativistic aspects of cosmology, see 98.80.Jk)
 ... ... Special relativity, see 03.30.+p 
04.20.-q Classical general relativity (see also 02.40.-k Geometry, differential geometry, and topology)
04.20.Cv Fundamental problems and general formalism 
04.20.Dw Singularities and cosmic censorship 
04.20.Ex Initial value problem, existence and uniqueness of solutions 
04.20.Fy Canonical formalism, Lagrangians, and variational principles 
04.20.Gz Spacetime topology, causal structure, spinor structure 
04.20.Ha Asymptotic structure 
04.20.Jb Exact solutions 
04.25.-g Approximation methods; equations of motion 
04.25.D- Numerical relativity 
04.25.dc Numerical studies of critical behavior, singularities, and cosmic censorship 
04.25.dg Numerical studies of black holes and black-hole binaries 
04.25.dk Numerical studies of other relativistic binaries (see also 97.80.-d Binary and multiple stars in astronomy)
04.25.Nx Post-Newtonian approximation; perturbation theory; related approximations 
04.30.-w Gravitational waves (see also 04.80.Nn Gravitational wave detectors and experiments)
04.30.Db Wave generation and sources 
04.30.Nk Wave propagation and interactions 
04.30.Tv Gravitational-wave astrophysics (see also 95.85.Sz Gravitational radiation, magnetic fields, and other observations in astronomy)
04.40.-b Self-gravitating systems; continuous media and classical fields in curved spacetime 
04.40.Dg Relativistic stars: structure, stability, and oscillations (see also 97.60.-s Late stages of stellar evolution)
04.40.Nr Einstein-Maxwell spacetimes, spacetimes with fluids, radiation or classical fields 
04.50.-h Higher-dimensional gravity and other theories of gravity (see also 11.25.Mj Compactification and four-dimensional models, 11.25.Uv D branes)
04.50.Cd Kaluza-Klein theories 
04.50.Gh Higher-dimensional black holes, black strings, and related objects 
04.50.Kd Modified theories of gravity 
04.60.-m Quantum gravity (see also 11.25.-w Strings and branes)
04.60.Bc Phenomenology of quantum gravity 
04.60.Cf Gravitational aspects of string theory 
04.60.Ds Canonical quantization 
04.60.Gw Covariant and sum-over-histories quantization 
04.60.Kz Lower dimensional models; minisuperspace models 
04.60.Nc Lattice and discrete methods 
04.60.Pp Loop quantum gravity, quantum geometry, spin foams 
04.62.+v Quantum fields in curved spacetime 
04.65.+e Supergravity (see also 12.60.Jv Supersymmetric models)
04.70.-s Physics of black holes (see also 97.60.Lf-in astronomy)
04.70.Bw Classical black holes 
04.70.Dy Quantum aspects of black holes, evaporation, thermodynamics 
04.80.-y Experimental studies of gravity 
04.80.Cc Experimental tests of gravitational theories 
04.80.Nn Gravitational wave detectors and experiments (see also 95.55.Ym Gravitational radiation detectors; mass spectrometers; and other instrumentation and techniques)
04.90.+e Other topics in general relativity and gravitation (restricted to new topics in section 04) 
05.00.00 Statistical physics, thermodynamics, and nonlinear dynamical systems (see also 02.50.-r Probability theory, stochastic processes, and statistics)
05.10.-a Computational methods in statistical physics and nonlinear dynamics (see also 02.70.-c in mathematical methods in physics)
05.10.Cc Renormalization group methods 
05.10.Gg Stochastic analysis methods (Fokker-Planck, Langevin, etc.) 
05.10.Ln Monte Carlo methods (see also 02.70.Tt, Uu in mathematical methods in physics; for Monte Carlo methods extensively used in subdivisions of physics, see the appropriate section; for example, see 52.65.Pp in plasma simulation)
05.20.-y Classical statistical mechanics 
05.20.Dd Kinetic theory (see also 51.10.+y Kinetic and transport theory of gases)
05.20.Gg Classical ensemble theory 
05.20.Jj Statistical mechanics of classical fluids (see also 47.10.-g General theory in fluid dynamics)
05.30.-d Quantum statistical mechanics (for quantum fluids aspects, see 67.10.Fj)
05.30.Ch Quantum ensemble theory 
05.30.Fk Fermion systems and electron gas (see also 71.10.-w Theories and models of many-electron systems; see also 67.10.Db Fermion degeneracy in quantum fluids)
05.30.Jp Boson systems (for static and dynamic properties of Bose-Einstein condensates, see 03.75.Hh and 03.75.Kk; see also 67.10.Ba Boson degeneracy in quantum fluids)
05.30.Pr Fractional statistics systems (anyons, etc.) 
05.40.-a Fluctuation phenomena, random processes, noise, and Brownian motion (for fluctuations in superconductivity, see 74.40.+k; for statistical theory and fluctuations in nuclear reactions, see 24.60.-k; for fluctuations in plasma, see 52.25.Gj)
05.40.Ca Noise 
05.40.Fb Random walks and Levy flights 
05.40.Jc Brownian motion 
05.45.-a Nonlinear dynamics and chaos (see also section 45 Classical mechanics of discrete systems; for chaos in fluid dynamics, see 47.52.+j)
05.45.Ac Low-dimensional chaos 
05.45.Df Fractals (see also 47.53.+n Fractals in fluid dynamics; 61.43.Hv Fractals; macroscopic aggregates in structure of solids)
05.45.Gg Control of chaos, applications of chaos 
05.45.Jn High-dimensional chaos 
05.45.Mt Quantum chaos; semiclassical methods 
05.45.Pq Numerical simulations of chaotic systems 
05.45.Ra Coupled map lattices 
05.45.Tp Time series analysis 
05.45.Vx Communication using chaos 
05.45.Xt Synchronization; coupled oscillators 
05.45.Yv Solitons (see 52.35.Sb for solitons in plasma; for solitons in acoustics, see 43.25.Rq-in Acoustics Appendix; see 42.50.Md, 42.65.Tg, 42.81.Dp for solitons in optics; see also 03.75.Lm in matter waves; for solitons in space plasma physics, see 94.05.Fg; for solitary waves in fluid dynamics, see 47.35.Fg)
05.50.+q Lattice theory and statistics (Ising, Potts, etc.) (see also 64.60.Cn Order-disorder transformations, and 75.10.Hk Classical spin models)
05.60.-k Transport processes 
05.60.Cd Classical transport 
05.60.Gg Quantum transport 
05.65.+b Self-organized systems (see also 45.70.-n in classical mechanics of discrete systems)
05.70.-a Thermodynamics (see also section 64 Equations of state, phase equilibria, and phase transitions, and section 65 Thermal properties of condensed matter; for chemical thermodynamics, see 82.60.-s; for thermodynamics of plasmas, see 52.25.Kn; for thermodynamic properties of quantum fluids, see section 67)
 ... ... Thermodynamics of nanoparticles, see 82.60.Qr; 65.80.+n 
 ... ... Thermodynamic processes in astrophysics, see 95.30.Tg 
 ... ... Thermodynamics in volcanology, see 91.40.Pc 
05.70.Ce Thermodynamic functions and equations of state (see also 51.30.+i Thermodynamic properties, equations of state in physics of gases; for equations of state of specific substances, see 64.30.-t; for equations of state of nuclear matter, and of neutron-star matter, see 21.65.Mn and 26.60.Kp respectively; see also 95.30.Tg in astronomy)
05.70.Fh Phase transitions: general studies (see also 64.70.Tg Quantum phase transitions)
05.70.Jk Critical point phenomena 
05.70.Ln Nonequilibrium and irreversible thermodynamics (see also 82.40.Bj Oscillations, chaos, and bifurcations in physical chemistry and chemical physics)
05.70.Np Interface and surface thermodynamics (see also 68.35.Md Surface thermodynamics, surface energies in surfaces and interfaces)
05.90.+m Other topics in statistical physics, thermodynamics, and nonlinear dynamical systems (restricted to new topics in section 05) 
06.00.00 Metrology, measurements, and laboratory procedures (for laser applications in metrology, see 42.62.Eh)
06.20.-f Metrology 
06.20.Dk Measurement and error theory 
06.20.F- Units and standards 
06.20.fa Units 
06.20.fb Standards and calibration 
06.20.Jr Determination of fundamental constants 
06.30.-k Measurements common to several branches of physics and astronomy 
06.30.Bp Spatial dimensions (e.g., position, lengths, volume, angles, and displacements) 
06.30.Dr Mass and density 
06.30.Ft Time and frequency 
06.30.Gv Velocity, acceleration, and rotation 
06.30.Ka Basic electromagnetic quantities (see also 84.37.+q Measurements in electric variables)
06.60.-c Laboratory procedures 
06.60.Ei Sample preparation (including design of sample holders) 
06.60.Jn High-speed techniques (microsecond to femtosecond) 
06.60.Mr Testing and inspecting procedures 
06.60.Sx Positioning and alignment; manipulating, remote handling 
06.60.Vz Workshop procedures (welding, machining, lubrication, bearings, etc.) 
06.60.Wa Laboratory safety procedures 
 ... ... National and international laboratory facilities, see 01.52.+r 
06.90.+v Other topics in metrology, measurements, and laboratory procedures (restricted to new topics in section 06) 
07.00.00 Instruments, apparatus, and components common to several branches of physics and astronomy (see also each subdiscipline for specialized instrumentation and techniques)
07.05.-t Computers in experimental physics 
 ... ... Computers in education, see 01.50.H- and 01.50.Lc 
 ... ... Computational techniques, see 02.70.-c 
 ... ... Quantum computation architectures and implementations, see 03.67.Lx 
 ... ... Optical computers, see 42.79.Ta 
07.05.Bx Computer systems: hardware, operating systems, computer languages, and utilities 
07.05.Dz Control systems 
07.05.Fb Design of experiments 
07.05.Hd Data acquisition: hardware and software 
07.05.Kf Data analysis: algorithms and implementation; data management (for data analysis in nuclear physics, see 29.85.-c)
07.05.Mh Neural networks, fuzzy logic, artificial intelligence 
07.05.Pj Image processing (see also 42.30.Va in optics; 87.57.-s Medical imaging in biological and medical physics; 95.75.Tv Digitization techniques in astronomy)
07.05.Rm Data presentation and visualization: algorithms and implementation 
07.05.Tp Computer modeling and simulation 
07.05.Wr Computer interfaces (for nuclear physics applications, see 29.50.+v)
07.07.-a General equipment 
07.07.Df Sensors (chemical, optical, electrical, movement, gas, etc.); remote sensing 
07.07.Hj Display and recording equipment, oscilloscopes, TV cameras, etc. 
07.07.Mp Transducers 
07.07.Tw Servo and control equipment; robots 
07.07.Vx Hygrometers; hygrometry 
07.10.-h Mechanical instruments and equipment 
07.10.Cm Micromechanical devices and systems (for micro- and nano-electromechanical systems (MEMS/NEMS), see 85.85.+j in electronic and magnetic devices; see also 87.80.Ek Mechanical and micromechanical techniques; 87.85.Ox Biomedical instrumentation and transducers including micro-electro-mechanical systems in biological and medical physics)
07.10.Fq Vibration isolation 
07.10.Lw Balance systems, tensile machines, etc. 
07.10.Pz Instruments for strain, force, and torque 
07.20.-n Thermal instruments and apparatus 
07.20.Dt Thermometers 
07.20.Fw Calorimeters (for calorimeters as radiation detectors, see 29.40.Vj)
07.20.Hy Furnaces; heaters 
07.20.Ka High-temperature instrumentation; pyrometers 
07.20.Mc Cryogenics; refrigerators, low-temperature detectors, and other low-temperature equipment 
07.20.Pe Heat engines; heat pumps; heat pipes 
07.30.-t Vacuum apparatus 
07.30.Bx Degasification, residual gas 
07.30.Cy Vacuum pumps 
07.30.Dz Vacuum gauges 
07.30.Hd Vacuum testing methods; leak detectors 
07.30.Kf Vacuum chambers, auxiliary apparatus, and materials 
07.35.+k High-pressure apparatus; shock tubes; diamond anvil cells 
07.50.-e Electrical and electronic instruments and components 
07.50.Ek Circuits and circuit components (see also 84.30.-r Electronic circuits and 84.32.-y Passive circuit components)
07.50.Hp Electrical noise and shielding equipment 
07.50.Ls Electrometers 
07.50.Qx Signal processing electronics (see also 84.40.Ua in radiowave and microwave technology; 87.85.Ng Biological signal processing in biomedical engineering)
07.55.-w Magnetic instruments and components 
07.55.Db Generation of magnetic fields; magnets (for superconducting magnets, see 84.71.Ba; for beam focusing magnets, see 41.85.Lc in beam optics)
07.55.Ge Magnetometers for magnetic field measurements 
07.55.Jg Magnetometers for susceptibility, magnetic moment, and magnetization measurements 
07.55.Nk Magnetic shielding in instruments 
07.57.-c Infrared, submillimeter wave, microwave and radiowave instruments and equipment (for infrared and radio telescopes, see 95.55.Cs, 95.55.Fw, and 95.55.Jz in astronomy; for biophysical spectroscopic applications, see 87.64.-t)
07.57.Hm Infrared, submillimeter wave, microwave, and radiowave sources (see also 42.72.Ai Infrared sources in optics)
07.57.Kp Bolometers; infrared, submillimeter wave, microwave, and radiowave receivers and detectors (see also 85.60.Gz Photodetectors in electronic and magnetic devices, and 95.55.Rg Photoconductors and bolometers in astronomy)
07.57.Pt Submillimeter wave, microwave and radiowave spectrometers; magnetic resonance spectrometers, auxiliary equipment, and techniques 
07.57.Ty Infrared spectrometers, auxiliary equipment, and techniques 
07.60.-j Optical instruments and equipment (see also 87.64.M- Optical microscopy in biological and medical physics)
 ... ... Optical sources, see 42.72.-g 
 ... ... Optical elements, devices, and systems 42.79.-e 
 ... ... Optoelectronic devices 85.60.-q 
 ... ... Optical telescopes, see 95.55.Cs 
 ... ... Photometric, polarimetric, and spectroscopic instrumentation in astronomy, see 95.55.Qf 
07.60.Dq Photometers, radiometers, and colorimeters 
07.60.Fs Polarimeters and ellipsometers 
07.60.Hv Refractometers and reflectometers 
07.60.Ly Interferometers 
07.60.Pb Conventional optical microscopes (for near-field scanning optical microscopes, see 07.79.Fc; for x-ray microscopes, see 07.85.Tt)
07.60.Rd Visible and ultraviolet spectrometers 
07.60.Vg Fiber-optic instruments (see also 42.81.-i Fiber optics)
07.64.+z Acoustic instruments and equipment (see also 43.58.+z-in acoustics)
07.68.+m Photography, photographic instruments; xerography 
07.75.+h Mass spectrometers (see also 82.80.Ms, 82.80.Nj, and 82.80.Rt in physical chemistry and chemical physics)
07.77.-n Atomic, molecular, and charged-particle sources and detectors 
07.77.Gx Atomic and molecular beam sources and detectors (see also 37.20.+j Atomic and molecular beam sources and techniques, in atomic and molecular physics)
07.77.Ka Charged-particle beam sources and detectors (see also 29.40.-n Radiation detectors in nuclear physics)
07.78.+s Electron, positron, and ion microscopes; electron diffractometers 
07.79.-v Scanning probe microscopes and components (see also 68.37.-d Microscopy of surfaces, interfaces, and thin films)
07.79.Cz Scanning tunneling microscopes 
07.79.Fc Near-field scanning optical microscopes 
07.79.Lh Atomic force microscopes 
07.79.Pk Magnetic force microscopes 
07.79.Sp Friction force microscopes 
07.81.+a Electron and ion spectrometers (see also 29.30.Dn Electron spectroscopy; 29.30.Ep Charged-particle spectroscopy in nuclear physics)
07.85.-m X- and gamma-ray instruments (for x- and gamma-ray telescopes, see 95.55.Ka in astronomy; see also 41.50.+h X-ray beams and x-ray optics)
07.85.Fv X- and gamma-ray sources, mirrors, gratings, and detectors 
07.85.Jy Diffractometers 
07.85.Nc X-ray and gamma-ray spectrometers 
07.85.Qe Synchrotron radiation instrumentation 
07.85.Tt X-ray microscopes 
07.87.+v Spaceborne and space research instruments, apparatus, and components (satellites, space vehicles, etc.) (for instrumentation for space plasma physics, ionosphere, and magnetosphere, see 94.80.+g; see also 95.55.-n and 95.40.+s in astronomy)
07.88.+y Instruments for environmental pollution measurements 
07.89.+b Environmental effects on instruments (e.g., radiation and pollution effects) (for environmental effects on optical elements, devices, and systems, see 42.88.+h)
07.90.+c Other topics in instruments, apparatus, and components common to several branches of physics and astronomy (restricted to new topics in section 07) 
10.00.00 THE PHYSICS OF ELEMENTARY PARTICLES AND FIELDS (for experimental methods and instrumentation for elementary-particle physics, see section 29)
11.00.00 General theory of fields and particles (see also 03.65.-w Quantum mechanics and 03.70.+k Theory of quantized fields)
11.10.-z Field theory (for gauge field theories, see 11.15.-q)
11.10.Cd Axiomatic approach 
11.10.Ef Lagrangian and Hamiltonian approach 
11.10.Gh Renormalization 
11.10.Hi Renormalization group evolution of parameters 
11.10.Jj Asymptotic problems and properties 
11.10.Kk Field theories in dimensions other than four (see also 04.50.-h Higher-dimensional gravity and other theories of gravity; 04.60.Kz Lower dimensional models; minisuperspace models in general relativity and gravitation)
11.10.Lm Nonlinear or nonlocal theories and models (see also 11.27.+d Extended classical solutions; cosmic strings, domain walls, texture)
11.10.Nx Noncommutative field theory 
11.10.St Bound and unstable states; Bethe-Salpeter equations 
11.10.Wx Finite-temperature field theory 
 ... ... Relativistic wave equations, see 03.65.Pm 
11.15.-q Gauge field theories 
11.15.Bt General properties of perturbation theory 
11.15.Ex Spontaneous breaking of gauge symmetries 
11.15.Ha Lattice gauge theory (see also 12.38.Gc Lattice QCD calculations)
11.15.Kc Classical and semiclassical techniques 
11.15.Me Strong-coupling expansions 
11.15.Pg Expansions for large numbers of components (e.g., 1/<i>N</i><sub><i>c</i></sub> expansions) 
11.15.Tk Other nonperturbative techniques 
11.25.-w Strings and branes (for cosmic strings, see 98.80.Cq in cosmology; see also 11.27.+d Extended classical solutions; cosmic strings, domain walls, texture)
11.25.Db Properties of perturbation theory 
11.25.Hf Conformal field theory, algebraic structures 
11.25.Mj Compactification and four-dimensional models 
11.25.Pm Noncritical string theory 
11.25.Sq Nonperturbative techniques; string field theory 
11.25.Tq Gauge/string duality 
11.25.Uv D branes 
11.25.Wx String and brane phenomenology 
11.25.Yb M theory 
11.27.+d Extended classical solutions; cosmic strings, domain walls, texture (see also 98.80.Cq in cosmology; 11.25.-w Strings and branes)
11.30.-j Symmetry and conservation laws (see also 02.20.-a Group theory)
11.30.Cp Lorentz and Poincare invariance 
11.30.Er Charge conjugation, parity, time reversal, and other discrete symmetries 
11.30.Fs Global symmetries (e.g., baryon number, lepton number) 
11.30.Hv Flavor symmetries 
11.30.Ly Other internal and higher symmetries 
11.30.Na Nonlinear and dynamical symmetries (spectrum-generating symmetries) 
11.30.Pb Supersymmetry (see also 12.60.Jv Supersymmetric models)
11.30.Qc Spontaneous and radiative symmetry breaking 
11.30.Rd Chiral symmetries 
11.40.-q Currents and their properties 
11.40.Dw General theory of currents 
11.40.Ex Formal properties of current algebras (see also 12.39.Fe Chiral Lagrangians)
11.40.Ha Partially conserved axial-vector currents 
11.55.-m S-matrix theory; analytic structure of amplitudes 
11.55.Bq Analytic properties of S matrix 
11.55.Ds Exact S matrices 
11.55.Fv Dispersion relations 
11.55.Hx Sum rules 
11.55.Jy Regge formalism (see also 12.40.Nn in strong interactions)
11.80.-m Relativistic scattering theory 
11.80.Cr Kinematical properties (helicity and invariant amplitudes, kinematic singularities, etc.) 
11.80.Et Partial-wave analysis 
11.80.Fv Approximations (eikonal approximation, variational principles, etc.) 
11.80.Gw Multichannel scattering 
11.80.Jy Many-body scattering and Faddeev equation 
11.80.La Multiple scattering 
11.90.+t Other topics in general theory of fields and particles (restricted to new topics in section 11) 
12.00.00 Specific theories and interaction models; particle systematics 
12.10.-g Unified field theories and models (see also 04.50.-h Higher-dimensional gravity and other theories of gravity-in general relativity and gravitation, 11.25.Mj Compactification and four-dimensional models)
12.10.Dm Unified theories and models of strong and electroweak interactions 
12.10.Kt Unification of couplings; mass relations 
12.15.-y Electroweak interactions 
 ... ... Extensions of gauge or Higgs sector, see 12.60.Cn or 12.60.Fr 
12.15.Ff Quark and lepton masses and mixing (see also 14.60.Pq Neutrino mass and mixing)
12.15.Hh Determination of Kobayashi-Maskawa matrix elements 
12.15.Ji Applications of electroweak models to specific processes 
12.15.Lk Electroweak radiative corrections (see also 13.40.Ks Electromagnetic corrections to strong- and weak-interaction processes)
12.15.Mm Neutral currents 
12.20.-m Quantum electrodynamics 
12.20.Ds Specific calculations 
12.20.Fv Experimental tests (for optical tests in quantum electrodynamics, see 42.50.Xa)
12.38.-t Quantum chromodynamics 
 ... ... Quarks, gluons, and QCD in nuclear reactions, see 24.85.+p 
12.38.Aw General properties of QCD (dynamics, confinement, etc.) 
12.38.Bx Perturbative calculations 
12.38.Cy Summation of perturbation theory 
12.38.Gc Lattice QCD calculations (see also 11.15.Ha Lattice gauge theory)
12.38.Lg Other nonperturbative calculations 
12.38.Mh Quark-gluon plasma (see also 25.75.Nq Quark deconfinement, quark-gluon plasma production and phase transitions in relativistic heavy ion collisions; see also 21.65.Qr Quark matter)
12.38.Qk Experimental tests 
12.39.-x Phenomenological quark models 
12.39.Ba Bag model 
12.39.Dc Skyrmions 
12.39.Fe Chiral Lagrangians 
12.39.Hg Heavy quark effective theory 
12.39.Jh Nonrelativistic quark model 
12.39.Ki Relativistic quark model 
12.39.Mk Glueball and nonstandard multi-quark/gluon states 
12.39.Pn Potential models 
12.39.St Factorization 
12.40.-y Other models for strong interactions 
12.40.Ee Statistical models 
12.40.Nn Regge theory, duality, absorptive/optical models (see also 11.55.Jy Regge formalism)
12.40.Vv Vector-meson dominance 
12.40.Yx Hadron mass models and calculations 
12.60.-i Models beyond the standard model 
 ... ... Unified field theories and models, see 12.10.-g 
12.60.Cn Extensions of electroweak gauge sector 
12.60.Fr Extensions of electroweak Higgs sector 
12.60.Jv Supersymmetric models (see also 04.65.+e Supergravity)
12.60.Nz Technicolor models 
12.60.Rc Composite models 
12.90.+b Miscellaneous theoretical ideas and models (restricted to new topics in section 12) 
13.00.00 Specific reactions and phenomenology 
13.15.+g Neutrino interactions 
13.20.-v Leptonic, semileptonic, and radiative decays of mesons 
13.20.Cz Decays of pi mesons 
13.20.Eb Decays of <i>K</i> mesons 
13.20.Fc Decays of charmed mesons 
13.20.Gd Decays of <i>J</i>/psi, Upsilon, and other quarkonia 
13.20.He Decays of bottom mesons 
13.20.Jf Decays of other mesons 
13.25.-k Hadronic decays of mesons 
13.25.Cq Decays of pi mesons 
13.25.Es Decays of <i>K</i> mesons 
13.25.Ft Decays of charmed mesons 
13.25.Gv Decays of <i>J</i>/psi, Upsilon, and other quarkonia 
13.25.Hw Decays of bottom mesons 
13.25.Jx Decays of other mesons 
13.30.-a Decays of baryons 
13.30.Ce Leptonic, semileptonic, and radiative decays 
13.30.Eg Hadronic decays 
13.35.-r Decays of leptons 
13.35.Bv Decays of muons 
13.35.Dx Decays of taus 
13.35.Hb Decays of heavy neutrinos 
13.38.-b Decays of intermediate bosons 
13.38.Be Decays of <i>W</i> bosons 
13.38.Dg Decays of <i>Z</i> bosons 
13.40.-f Electromagnetic processes and properties 
13.40.Dk Electromagnetic mass differences 
13.40.Em Electric and magnetic moments 
13.40.Gp Electromagnetic form factors 
13.40.Hq Electromagnetic decays 
13.40.Ks Electromagnetic corrections to strong- and weak-interaction processes 
13.60.-r Photon and charged-lepton interactions with hadrons (for neutrino interactions, see 13.15.+g)
13.60.Fz Elastic and Compton scattering 
13.60.Hb Total and inclusive cross sections (including deep-inelastic processes) 
13.60.Le Meson production 
13.60.Rj Baryon production 
13.66.-a Lepton-lepton interactions 
13.66.Bc Hadron production in <i>e</i><sup>-</sup><i>e</i><sup>+</sup> interactions 
13.66.De Lepton production in <i>e</i><sup>-</sup><i>e</i><sup>+</sup> interactions 
13.66.Fg Gauge and Higgs boson production in <i>e</i><sup>-</sup><i>e</i><sup>+</sup> interactions 
13.66.Hk Production of non-standard model particles in <i>e</i><sup>-</sup><i>e</i><sup>+</sup> interactions 
13.66.Jn Precision measurements in <i>e</i><sup>-</sup><i>e</i><sup>+</sup> interactions 
13.66.Lm Processes in other lepton-lepton interactions 
13.75.-n Hadron-induced low- and intermediate-energy reactions and scattering (energy (less-than-or-equal-to) 10 GeV) (for higher energies, see 13.85.-t)
13.75.Cs Nucleon-nucleon interactions (including antinucleons, deuterons, etc.) (for <i>N</i>-<i>N</i> interactions in nuclei, see 21.30.-x)
13.75.Ev Hyperon-nucleon interactions 
13.75.Gx Pion-baryon interactions 
13.75.Jz Kaon-baryon interactions 
13.75.Lb Meson-meson interactions 
13.85.-t Hadron-induced high- and super-high-energy interactions (energy > 10 GeV) (for low energies, see 13.75.-n)
13.85.Dz Elastic scattering 
13.85.Fb Inelastic scattering: two-particle final states 
13.85.Hd Inelastic scattering: many-particle final states 
13.85.Lg Total cross sections 
13.85.Ni Inclusive production with identified hadrons 
13.85.Qk Inclusive production with identified leptons, photons, or other nonhadronic particles 
13.85.Rm Limits on production of particles 
13.85.Tp Cosmic-ray interactions (see also 96.50.S- Cosmic rays in interplanetary physics)
13.87.-a Jets in large-Q<sup>2</sup> scattering 
13.87.Ce Production 
13.87.Fh Fragmentation into hadrons 
13.88.+e Polarization in interactions and scattering 
13.90.+i Other topics in specific reactions and phenomenology of elementary particles (restricted to new topics in section 13) 
14.00.00 Properties of specific particles 
14.20.-c Baryons (including antiparticles) 
14.20.Dh Protons and neutrons 
14.20.Gk Baryon resonances with <i>S</i>=0 
14.20.Jn Hyperons 
14.20.Lq Charmed baryons 
14.20.Mr Bottom baryons 
14.20.Pt Dibaryons 
14.40.-n Mesons 
14.40.Aq pi, <i>K</i>, and eta mesons 
14.40.Cs Other mesons with <i>S</i>=<i>C</i>=0, mass < 2.5 GeV 
14.40.Ev Other strange mesons 
14.40.Gx Mesons with <i>S</i>=<i>C</i>=<i>B</i>=0, mass > 2.5 GeV (including quarkonia) 
14.40.Lb Charmed mesons 
14.40.Nd Bottom mesons 
14.60.-z Leptons 
14.60.Cd Electrons (including positrons) 
14.60.Ef Muons 
14.60.Fg Taus 
14.60.Hi Other charged heavy leptons 
14.60.Lm Ordinary neutrinos (nu<sub>e</sub>, nu<sub>mu</sub>, nu<sub>tau</sub>) 
14.60.Pq Neutrino mass and mixing (see also 12.15.Ff Quark and lepton masses and mixing)
14.60.St Non-standard-model neutrinos, right-handed neutrinos, etc. 
14.65.-q Quarks 
14.65.Bt Light quarks 
14.65.Dw Charmed quarks 
14.65.Fy Bottom quarks 
14.65.Ha Top quarks 
14.70.-e Gauge bosons 
14.70.Bh Photons 
14.70.Dj Gluons 
14.70.Fm <i>W</i> bosons 
14.70.Hp <i>Z</i> bosons 
14.70.Pw Other gauge bosons 
14.80.-j Other particles (including hypothetical) 
14.80.Bn Standard-model Higgs bosons 
14.80.Cp Non-standard-model Higgs bosons 
14.80.Hv Magnetic monopoles 
14.80.Ly Supersymmetric partners of known particles 
14.80.Mz Axions and other Nambu-Goldstone bosons (Majorons, familons, etc.) 
20.00.00 NUCLEAR PHYSICS 
21.00.00 Nuclear structure (for nucleon structure, see 14.20.Dh Properties of protons and neutrons; 13.40.-f for electromagnetic processes and properties; 13.60.Hb for deep-inelastic structure functions)
21.10.-k Properties of nuclei; nuclear energy levels (for properties of specific nuclei listed by mass ranges, see section 27)
21.10.Dr Binding energies and masses 
21.10.Ft Charge distribution 
21.10.Gv Nucleon distributions and halo features 
21.10.Hw Spin, parity, and isobaric spin 
21.10.Jx Spectroscopic factors and asymptotic normalization coefficients 
21.10.Ky Electromagnetic moments 
21.10.Ma Level density 
21.10.Pc Single-particle levels and strength functions 
21.10.Re Collective levels 
21.10.Sf Coulomb energies, analogue states 
21.10.Tg Lifetimes, widths 
21.30.-x Nuclear forces (see also 13.75.Cs Nucleon-nucleon interactions)
21.30.Cb Nuclear forces in vacuum 
21.30.Fe Forces in hadronic systems and effective interactions 
21.45.-v Few-body systems 
21.45.Bc Two-nucleon system 
21.45.Ff Three-nucleon forces 
21.60.-n Nuclear structure models and methods 
21.60.Cs Shell model 
21.60.De <i>Ab initio</i> methods 
21.60.Ev Collective models 
21.60.Fw Models based on group theory 
21.60.Gx Cluster models 
21.60.Jz Nuclear Density Functional Theory and extensions (includes Hartree-Fock and random-phase approximations) 
21.60.Ka Monte Carlo models 
21.65.-f Nuclear matter 
21.65.Cd Asymmetric matter, neutron matter 
21.65.Ef Symmetry energy 
21.65.Jk Mesons in nuclear matter 
21.65.Mn Equations of state of nuclear matter (see also 26.60.Kp Equations of state of neutron-star matter)
21.65.Qr Quark matter (see also 12.38.Mh Quark-gluon plasma in quantum chromodynamics; 25.75.Nq Quark deconfinement, quark-gluon plasma production and phase transitions in relativistic heavy-ion collisions)
 ... ... Exotic atoms and molecules, see 36.10.-k 
21.80.+a Hypernuclei 
21.85.+d Mesic nuclei 
21.90.+f Other topics in nuclear structure (restricted to new topics in section 21) 
23.00.00 Radioactive decay and in-beam spectroscopy 
23.20.-g Electromagnetic transitions 
23.20.En Angular distribution and correlation measurements 
23.20.Gq Multipole mixing ratios 
23.20.Js Multipole matrix elements 
23.20.Lv gamma transitions and level energies 
23.20.Nx Internal conversion and extranuclear effects (including Auger electrons and internal bremsstrahlung) 
23.20.Ra Internal pair production 
23.35.+g Isomer decay 
23.40.-s beta decay; double beta decay; electron and muon capture 
23.40.Bw Weak-interaction and lepton (including neutrino) aspects (see also 14.60.Pq Neutrino mass and mixing)
23.40.Hc Relation with nuclear matrix elements and nuclear structure 
23.50.+z Decay by proton emission 
23.60.+e alpha decay 
23.70.+j Heavy-particle decay 
23.90.+w Other topics in radioactive decay and in-beam spectroscopy (restricted to new topics in section 23) 
24.00.00 Nuclear reactions: general 
24.10.-i Nuclear reaction models and methods 
24.10.Cn Many-body theory 
24.10.Eq Coupled-channel and distorted-wave models 
24.10.Ht Optical and diffraction models 
24.10.Jv Relativistic models 
24.10.Lx Monte Carlo simulations (including hadron and parton cascades and string breaking models) 
24.10.Nz Hydrodynamic models 
24.10.Pa Thermal and statistical models 
24.30.-v Resonance reactions 
24.30.Cz Giant resonances 
24.30.Gd Other resonances 
24.50.+g Direct reactions 
24.60.-k Statistical theory and fluctuations 
24.60.Dr Statistical compound-nucleus reactions 
24.60.Gv Statistical multistep direct reactions 
24.60.Ky Fluctuation phenomena 
24.60.Lz Chaos in nuclear systems 
24.70.+s Polarization phenomena in reactions 
24.75.+i General properties of fission 
24.80.+y Nuclear tests of fundamental interactions and symmetries 
24.85.+p Quarks, gluons, and QCD in nuclear reactions 
24.87.+y Surrogate reactions 
24.90.+d Other topics in nuclear reactions: general (restricted to new topics in section 24) 
25.00.00 Nuclear reactions: specific reactions 
25.10.+s Nuclear reactions involving few-nucleon systems 
25.20.-x Photonuclear reactions 
25.20.Dc Photon absorption and scattering 
25.20.Lj Photoproduction reactions 
25.30.-c Lepton-induced reactions 
25.30.Bf Elastic electron scattering 
25.30.Dh Inelastic electron scattering to specific states 
25.30.Fj Inelastic electron scattering to continuum 
25.30.Hm Positron-induced reactions 
25.30.Mr Muon-induced reactions (including the EMC effect) 
25.30.Pt Neutrino-induced reactions 
25.30.Rw Electroproduction reactions 
25.40.-h Nucleon-induced reactions (see also 28.20.-v Neutron physics)
25.40.Cm Elastic proton scattering 
25.40.Dn Elastic neutron scattering 
25.40.Ep Inelastic proton scattering 
25.40.Fq Inelastic neutron scattering 
25.40.Hs Transfer reactions 
25.40.Kv Charge-exchange reactions 
25.40.Lw Radiative capture 
25.40.Ny Resonance reactions 
25.40.Qa (<i>p</i>, pi) reactions 
25.40.Sc Spallation reactions 
25.40.Ve Other reactions above meson production thresholds (energies > 400 MeV) 
25.43.+t Antiproton-induced reactions 
25.45.-z <sup>2</sup>H-induced reactions 
25.45.De Elastic and inelastic scattering 
25.45.Hi Transfer reactions 
25.45.Kk Charge-exchange reactions 
25.55.-e <sup>3</sup>H-, <sup>3</sup>He-, and <sup>4</sup>He-induced reactions 
25.55.Ci Elastic and inelastic scattering 
25.55.Hp Transfer reactions 
25.55.Kr Charge-exchange reactions 
25.60.-t Reactions induced by unstable nuclei 
25.60.Bx Elastic scattering 
25.60.Dz Interaction and reaction cross sections 
25.60.Gc Breakup and momentum distributions 
25.60.Je Transfer reactions 
25.60.Lg Charge-exchange reactions 
25.60.Pj Fusion reactions 
25.60.Tv Radiative capture 
25.70.-z Low and intermediate energy heavy-ion reactions 
25.70.Bc Elastic and quasielastic scattering 
25.70.De Coulomb excitation 
25.70.Ef Resonances 
25.70.Gh Compound nucleus 
25.70.Hi Transfer reactions 
25.70.Jj Fusion and fusion-fission reactions 
25.70.Kk Charge-exchange reactions 
25.70.Lm Strongly damped collisions 
25.70.Mn Projectile and target fragmentation 
25.70.Pq Multifragment emission and correlations 
25.75.-q Relativistic heavy-ion collisions (collisions induced by light ions studied to calibrate relativistic heavy-ion collisions should be classified under both 25.75.-q and sections 13 or 25 appropriate to the light ions)
25.75.Ag Global features in relativistic heavy ion collisions 
25.75.Bh Hard scattering in relativistic heavy ion collisions 
25.75.Cj Photon, lepton, and heavy quark production in relativistic heavy ion collisions 
25.75.Dw Particle and resonance production 
25.75.Gz Particle correlations and fluctuations 
25.75.Ld Collective flow 
25.75.Nq Quark deconfinement, quark-gluon plasma production, and phase transitions (see also 12.38.Mh Quark-gluon plasma in quantum chromodynamics; 21.65.Qr Quark matter in nuclear matter)
25.80.-e Meson- and hyperon-induced reactions 
25.80.Dj Pion elastic scattering 
25.80.Ek Pion inelastic scattering 
25.80.Gn Pion charge-exchange reactions 
25.80.Hp Pion-induced reactions 
25.80.Ls Pion inclusive scattering and absorption 
25.80.Nv Kaon-induced reactions 
25.80.Pw Hyperon-induced reactions 
25.85.-w Fission reactions 
25.85.Ca Spontaneous fission 
25.85.Ec Neutron-induced fission 
25.85.Ge Charged-particle-induced fission 
25.85.Jg Photofission 
25.90.+k Other topics in nuclear reactions: specific reactions (restricted to new topics in section 25) 
26.00.00 Nuclear astrophysics (see also 95.30.-k Fundamental aspects of astrophysics in astronomy)
26.20.-f Hydrostatic stellar nucleosynthesis (see also 97.10.Cv Stellar structure, interiors, evolution, nucleosynthesis, ages in astronomy)
26.20.Cd Stellar hydrogen burning 
26.20.Fj Stellar helium burning 
26.20.Kn s-process 
26.20.Np Nucleosynthesis in late stellar evolution 
26.20.Qr Quasistatistical processes 
26.30.-k Nucleosynthesis in novae, supernovae, and other explosive environments 
26.30.Ca Explosive burning in accreting binary systems (novae, x-ray bursts) 
26.30.Ef Explosive burning in supernovae shock fronts 
26.30.Hj r-process 
26.30.Jk Weak interaction and neutrino induced processes, galactic radioactivity 
26.35.+c Big Bang nucleosynthesis (see also 98.80.Ft Origin, formation, and abundances of the elements in astronomy)
26.40.+r Cosmic ray nucleosynthesis 
26.50.+x Nuclear physics aspects of novae, supernovae, and other explosive environments 
26.60.-c Nuclear matter aspects of neutron stars 
26.60.Dd Neutron star core 
26.60.Gj Neutron star crust 
26.60.Kp Equations of state of neutron-star matter 
26.65.+t Solar neutrinos (see also 96.60.Vg Particle emission, solar wind in solar physics)
26.90.+n Other topics in nuclear astrophysics (restricted to new topics in section 26) 
27.00.00 Properties of specific nuclei listed by mass ranges (an additional heading must be chosen with these entries, where the given mass number limits are, to some degree, arbitrary)
27.10.+h A (less-than-or-equal-to) 5 
27.20.+n 6 (less-than-or-equal-to) A (less-than-or-equal-to) 19 
27.30.+t 20 (less-than-or-equal-to) A (less-than-or-equal-to) 38 
27.40.+z 39 (less-than-or-equal-to) A (less-than-or-equal-to) 58 
27.50.+e 59 (less-than-or-equal-to) A (less-than-or-equal-to) 89 
27.60.+j 90 (less-than-or-equal-to) A (less-than-or-equal-to) 149 
27.70.+q 150 (less-than-or-equal-to) A (less-than-or-equal-to) 189 
27.80.+w 190 (less-than-or-equal-to) A (less-than-or-equal-to) 219 
27.90.+b A (greater-than-or-equal-to) 220 
28.00.00 Nuclear engineering and nuclear power studies 
28.20.-v Neutron physics (see also 25.40.-h Nucleon-induced reactions and 25.85.Ec Neutron-induced fission)
28.20.Cz Neutron scattering 
28.20.Fc Neutron absorption 
28.20.Gd Neutron transport: diffusion and moderation 
28.20.Ka Thermal neutron cross sections 
28.20.Np Neutron capture gamma-rays 
28.41.-i Fission reactors (see also 89.30.Gg nuclear fission power in energy resources)
28.41.Ak Theory, design, and computerized simulation 
28.41.Bm Fuel elements, preparation, reloading, and reprocessing 
28.41.Fr Reactor coolants, reactor cooling, and heat recovery 
28.41.Kw Radioactive wastes, waste disposal 
28.41.My Reactor control systems 
28.41.Pa Moderators 
28.41.Qb Structural and shielding materials 
28.41.Rc Instrumentation 
28.41.Te Protection systems, safety, radiation monitoring, accidents, and dismantling 
28.41.Vx Fuel cycles 
28.50.-k Fission reactor types 
28.50.Dr Research reactors 
28.50.Ft Fast and breeder reactors 
28.50.Hw Power and production reactors 
28.50.Ky Propulsion reactors 
28.50.Ma Auxiliary generators 
28.52.-s Fusion reactors (see also 52.55.-s Magnetic confinement and equilibrium, 52.57.-z Laser inertial confinement, and 52.58.-c Other confinement methods in physics of plasmas; 89.30.Jj Nuclear fusion power in energy resources)
28.52.Av Theory, design, and computerized simulation 
28.52.Cx Fueling, heating and ignition 
28.52.Fa Materials 
28.52.Lf Components and instrumentation 
28.52.Nh Safety (see also 87.55.N- Radiation monitoring, control, and safety in biological and medical physics)
28.60.+s Isotope separation and enrichment 
28.65.+a Accelerator-driven transmutation of nuclear waste 
28.70.+y Nuclear explosions (see also 47.40.-x Compressible flows; shock waves; for radiation protection from fallout, for dosimetry and exposure assessment, see 87.53.Bn; for nuclear explosion seismology, see 91.30.Rz)
28.90.+i Other topics in nuclear engineering and nuclear power studies (restricted to new topics in section 28) 
29.00.00 Experimental methods and instrumentation for elementary-particle and nuclear physics 
29.20.-c Accelerators (for accelerators used in medical applications, see 87.56.bd)
29.20.Ba Electrostatic accelerators 
29.20.D- Cyclic accelerators and storage rings 
29.20.db Storage rings and colliders 
29.20.df Betatrons 
29.20.dg Cyclotrons 
29.20.dk Synchrotrons 
29.20.Ej Linear accelerators 
29.25.-t Particle sources and targets (see also 52.59.-f Intense particle beams and radiation sources in physics of plasmas; 87.56.bg Radioactive sources in medical physics)
29.25.Bx Electron sources 
29.25.Dz Neutron sources 
29.25.Lg Ion sources: polarized 
29.25.Ni Ion sources: positive and negative 
29.25.Pj Polarized and other targets 
29.25.Rm Sources of radioactive nuclei 
29.27.-a Beams in particle accelerators (for low energy charged-particle beams, see 41.75.-i and 41.85.-p)
29.27.Ac Beam injection and extraction 
29.27.Bd Beam dynamics; collective effects and instabilities 
29.27.Eg Beam handling; beam transport 
29.27.Fh Beam characteristics 
29.27.Hj Polarized beams 
29.30.-h Spectrometers and spectroscopic techniques 
29.30.Aj Charged-particle spectrometers: electric and magnetic 
29.30.Dn Electron spectroscopy 
29.30.Ep Charged-particle spectroscopy 
29.30.Hs Neutron spectroscopy 
29.30.Kv X- and gamma-ray spectroscopy 
29.30.Lw Nuclear orientation devices 
 ... ... Energy loss and stopping power, see 34.50.Bw and 61.85.+p 
29.38.-c Radioactive beams 
29.38.Db Fast radioactive beam techniques 
29.38.Gj Reaccelerated radioactive beams 
29.40.-n Radiation detectors (for mass spectrometers, see 07.75.+h; see also 95.55.Vj Neutrino, muon, pion, and other particle detectors; cosmic ray detectors in astronomy)
29.40.Cs Gas-filled counters: ionization chambers, proportional, and avalanche counters 
29.40.Gx Tracking and position-sensitive detectors 
29.40.Ka Cherenkov detectors 
29.40.Mc Scintillation detectors 
29.40.Rg Nuclear emulsions 
29.40.Vj Calorimeters 
29.40.Wk Solid-state detectors 
29.50.+v Computer interfaces 
29.85.-c Computer data analysis 
29.85.Ca Data acquisition and sorting 
29.85.Fj Data analysis 
29.87.+g Nuclear data compilation 
29.90.+r Other topics in elementary-particle and nuclear physics experimental methods and instrumentation (restricted to new topics in section 29) 
30.00.00 ATOMIC AND MOLECULAR PHYSICS 
31.00.00 Electronic structure of atoms and molecules: theory 
31.10.+z Theory of electronic structure, electronic transitions, and chemical binding (for theory and mathematical methods applied to electronic structure of biomolecules, see 87.10.-e)
31.15.-p Calculations and mathematical techniques in atomic and molecular physics (see also 02.70.-c Computational techniques, in mathematical methods in physics)
31.15.A- <i>Ab initio</i> calculations 
31.15.ac High-precision calculations for few-electron (or few-body) atomic systems 
31.15.ae Electronic structure and bonding characteristics 
31.15.ag Excitation energies and lifetimes; oscillator strengths 
31.15.aj Relativistic corrections, spin-orbit effects, fine structure; hyperfine structure 
31.15.am Relativistic configuration interaction (CI) and many-body perturbation calculations 
31.15.ap Polarizabilities and other atomic and molecular properties 
31.15.aq Strongly correlated electron systems: generalized tight-binding method 
31.15.at Molecule transport characteristics; molecular dynamics; electronic structure of polymers 
31.15.B- Approximate calculations 
31.15.bt Statistical model calculations (including Thomas-Fermi and Thomas-Fermi-Dirac models) 
31.15.bu Semi-empirical and empirical calculations (differential overlap, Huckel, PPP methods, etc.) 
31.15.bw Coupled-cluster theory 
31.15.E- Density-functional theory 
31.15.ec Hohenberg-Kohn theorem and formal mathematical properties, completeness theorems 
31.15.ee Time-dependent density functional theory 
31.15.eg Exchange-correlation functionals (in current density functional theory) 
31.15.ej Spin-density functionals 
31.15.em Corrections for core-spin polarization, surface effects, etc. 
31.15.ep Variational particle-number approach 
31.15.es Applications of density-functional theory (e.g., to electronic structure and stability; defect formation; dielectric properties, susceptibilities; viscoelastic coefficients; Rydberg transition frequencies) 
31.15.V- Electron correlation calculations for atoms, ions and molecules 
31.15.ve Electron correlation calculations for atoms and ions: ground state 
31.15.vj Electron correlation calculations for atoms and ions: excited states 
31.15.vn Electron correlation calculations for diatomic molecules 
31.15.vq Electron correlation calculations for polyatomic molecules 
31.15.X- Alternative approaches 
31.15.xf Finite-difference schemes 
31.15.xg Semiclassical methods 
31.15.xh Group-theoretical methods (see also 02.20.-a Group theory in mathematical methods in physics)
31.15.xj Hyperspherical methods 
31.15.xk Path-integral methods 
31.15.xm Quasiparticle methods 
31.15.xp Perturbation theory 
31.15.xr Self-consistent-field methods 
31.15.xt Variational techniques 
31.15.xv Molecular dynamics and other numerical methods (for simulation techniques for biomolecules, see 87.15.ak, ap)
31.15.xw Valence bond calculations 
31.30.-i Corrections to electronic structure (see also 03.30.+p Special relativity; for exotic atoms and molecules, see 36.10.-k; for applications of density-functional theory, see 31.15.es)
31.30.Gs Hyperfine interactions and isotope effects (see also 32.10.Fn Fine and hyperfine structure)
31.30.J- Relativistic and quantum electrodynamic (QED) effects in atoms, molecules, and ions 
31.30.jc Relativistic corrections to atomic structure and properties 
31.30.jd Relativistic corrections due to negative-energy states or processes 
31.30.jf QED calculations of level energies, transition frequencies, fine structure intervals (radiative corrections, self-energy, vacuum polarization, etc.) 
31.30.jg QED corrections to parity nonconserving transition amplitudes and CP violations 
31.30.jh QED corrections to long-range and weak interactions 
31.30.jn QED corrections to electric dipole moments and other atomic properties 
31.30.jp Electron electric dipole moment 
31.30.jr QED corrections (Lamb shift) in muonic hydrogen and deuterium (see also 36.10.Ee Muonium, muonic atoms and molecules)
31.30.js Corrections to bound-electron g factor 
31.30.jx Nonrelativistic limits of Dirac-Fock calculations 
31.30.jy Higher-order effective Hamiltonians 
31.30.jz Decay rates of hydrogen-antihydrogen quasimolecules (for exotic atoms and molecules, see 36.10.-k)
31.50.-x Potential energy surfaces (for potential energy surfaces for chemical reactions, see 82.20.Kh; for collisions, see 34.20.-b)
31.50.Bc Potential energy surfaces for ground electronic states 
31.50.Df Potential energy surfaces for excited electronic states 
31.50.Gh Surface crossings, non-adiabatic couplings 
31.70.-f Effects of atomic and molecular interactions on electronic structure (see also section 34 Atomic and molecular collision processes and interactions)
31.70.Dk Environmental and solvent effects 
31.70.Hq Time-dependent phenomena: excitation and relaxation processes, and reaction rates (for chemical kinetics aspects, see 82.20.Rp)
31.70.Ks Molecular solids 
31.90.+s Other topics in the theory of the electronic structure of atoms and molecules (restricted to new topics in section 31) 
32.00.00 Atomic properties and interactions with photons (for quantum chaos, see 05.45.Mt; for standards of calibration, see 06.20.fb; for relativistic and quantum electrodynamic effects, see 31.30.J-)
32.10.-f Properties of atoms (for astrophysical applications, see 95.30.Ky)
32.10.Bi Atomic masses, mass spectra, abundances, and isotopes (for mass spectroscopy, see 07.75.+h in instruments, and 82.80.Ms, Nj, Rt in physical chemistry and chemical physics)
32.10.Dk Electric and magnetic moments, polarizabilities 
32.10.Ee Magnetic bound states, magnetic trapping of Rydberg states 
32.10.Fn Fine and hyperfine structure (see also 31.30.Gs Hyperfine interactions and isotope effects)
32.10.Hq Ionization potentials, electron affinities 
32.30.-r Atomic spectra (see also 78.47.J- Ultrafast pump/probe spectroscopy in condensed matter and 82.53.Kp Coherent spectroscopy of atoms and molecules in physical chemistry and chemical physics)
32.30.Bv Radio-frequency, microwave, and infrared spectra 
32.30.Dx Magnetic resonance spectra 
32.30.Jc Visible and ultraviolet spectra 
32.30.Rj X-ray spectra 
32.50.+d Fluorescence, phosphorescence (including quenching) 
32.60.+i Zeeman and Stark effects 
32.70.-n Intensities and shapes of atomic spectral lines (see also 31.15.-p Calculations and mathematical techniques)
32.70.Cs Oscillator strengths, lifetimes, transition moments 
32.70.Fw Absolute and relative intensities 
32.70.Jz Line shapes, widths, and shifts 
32.80.-t Photoionization and excitation 
32.80.Aa Inner-shell excitation and ionization 
 ... ... Atomic scattering cross sections, form factors, Compton scattering, see section 34 
32.80.Ee Rydberg states 
32.80.Fb Photoionization of atoms and ions (for fluorescence yield, see 32.50.+d)
32.80.Gc Photodetachment of atomic negative ions 
32.80.Hd Auger effect (including Coster-Kronig transitions) 
 ... ... Mechanical effects of light on atoms, molecules, and ions, see 37.10.Vz 
 ... ... Atom cooling methods, traps and guides, see 37.10.De and 37.10.Gh 
 ... ... Atoms in optical lattices, see 37.10.Jk 
32.80.Qk Coherent control of atomic interactions with photons
32.80.Rm Multiphoton ionization and excitation to highly excited states 
32.80.Wr Other multiphoton processes 
32.80.Xx Level crossing and optical pumping 
32.80.Zb Autoionization 
32.90.+a Other topics in atomic properties and interactions of atoms with photons (restricted to new topics in section 32) 
33.00.00 Molecular properties and interactions with photons 
33.15.-e Properties of molecules (see also section 31, Electronic structure of atoms and molecules: theory; for molecules of interest in astrophysics, see 95.30.Ky; for structure and properties of biomolecules, see 87.15.-v)
33.15.Bh General molecular conformation and symmetry; stereochemistry 
33.15.Dj Interatomic distances and angles 
33.15.Fm Bond strengths, dissociation energies 
33.15.Hp Barrier heights (internal rotation, inversion, rotational isomerism, conformational dynamics) 
33.15.Kr Electric and magnetic moments (and derivatives), polarizability, and magnetic susceptibility 
33.15.Mt Rotation, vibration, and vibration-rotation constants 
33.15.Pw Fine and hyperfine structure 
33.15.Ry Ionization potentials, electron affinities, molecular core binding energy 
33.15.Ta Mass spectra 
33.15.Vb Correlation times in molecular dynamics 
33.20.-t Molecular spectra (see also 78.47.J- Ultrafast pump/probe spectroscopy in condensed matter and 82.53.Kp Coherent spectroscopy of atoms and molecules; for chemical analytical methods using spectroscopy, see 82.80.Dx, Gk, Ha in physical chemistry; 87.64.-t Spectroscopic and microscopic techniques in biological physics; for spectra of macromolecules and polymer molecules, see 36.20.Kd)
33.20.Bx Radio-frequency and microwave spectra 
33.20.Ea Infrared spectra 
33.20.Fb Raman and Rayleigh spectra (including optical scattering) 
33.20.Kf Visible spectra 
33.20.Lg Ultraviolet spectra 
33.20.Ni Vacuum ultraviolet spectra 
33.20.Rm X-ray spectra 
33.20.Sn Rotational analysis 
33.20.Tp Vibrational analysis 
33.20.Vq Vibration-rotation analysis 
33.20.Wr Vibronic, rovibronic, and rotation-electron-spin interactions 
33.20.Xx Spectra induced by strong-field or attosecond laser irradiation (see also 33.60.+q Photoelectron spectra)
33.25.+k Nuclear resonance and relaxation (see also 76.60.-k Nuclear magnetic resonance and relaxation in condensed matter; 82.56.-b Nuclear magnetic resonance in physical chemistry and chemical physics; 87.80.Lg Magnetic and paramagnetic resonance in biological physics)
33.35.+r Electron resonance and relaxation (see also 76.30.-v Electron paramagnetic resonance and relaxation in condensed matter)
33.40.+f Multiple resonances (including double and higher-order resonance processes, such as double nuclear magnetic resonance, electron double resonance, and microwave optical double resonance) (see also 76.70.-r Magnetic double resonances and cross effects in condensed matter)
33.45.+x Mossbauer spectra (see also 76.80.+y Mossbauer effect; other gamma-ray spectroscopy in condensed matter; for biophysical applications, see 87.64.Kx; for chemical analysis applications, see 82.80.Ej)
33.50.-j Fluorescence and phosphorescence; radiationless transitions, quenching (intersystem crossing, internal conversion) (for energy transfer, see also section 34; for biophysical applications, see 87.64.kv)
33.50.Dq Fluorescence and phosphorescence spectra 
33.50.Hv Radiationless transitions, quenching 
33.55.+b Optical activity and dichroism 
33.57.+c Magnetooptical and electrooptical spectra and effects 
33.60.+q Photoelectron spectra (for biophysical applications, see 87.64.ks)
33.70.-w Intensities and shapes of molecular spectral lines and bands 
33.70.Ca Oscillator and band strengths, lifetimes, transition moments, and Franck-Condon factors 
33.70.Fd Absolute and relative line and band intensities 
33.70.Jg Line and band widths, shapes, and shifts 
33.80.-b Photon interactions with molecules (see also 42.50.-p Quantum optics)
33.80.Be Level crossing and optical pumping 
33.80.Eh Autoionization, photoionization, and photodetachment 
33.80.Gj Diffuse spectra; predissociation, photodissociation 
 ... ... Slowing, cooling, and trapping of molecules, see 37.10.Mn and 37.10.Pq 
33.80.Rv Multiphoton ionization and excitation to highly excited states (e.g., Rydberg states) 
33.80.Wz Other multiphoton processes 
33.90.+h Other topics in molecular properties and interactions with photons (restricted to new topics in section 33) 
34.00.00 Atomic and molecular collision processes and interactions (for atomic, molecular, and ionic collisions in plasma, see 52.20.Hv; for atoms and molecules of astrophysical interest, see 95.30.Dr, Ft; see also 98.38.Bn and 98.58.Bz in interstellar media in astronomy; 87.15.K- Molecular interactions, membrane-protein interactions in biological physics)
34.10.+x General theories and models of atomic and molecular collisions and interactions (including statistical theories, transition state, stochastic and trajectory models, etc.) 
34.20.-b Interatomic and intermolecular potentials and forces, potential energy surfaces for collisions (see also 82.20.Kh Potential energy surfaces for reactions; for potential energy surfaces in electronic structure calculations, see 31.50.-x)
34.20.Cf Interatomic potentials and forces 
34.20.Gj Intermolecular and atom-molecule potentials and forces 
34.35.+a Interactions of atoms and molecules with surfaces 
34.50.-s Scattering of atoms and molecules 
34.50.Bw Energy loss and stopping power 
34.50.Cx Elastic; ultracold collisions 
34.50.Ez Rotational and vibrational energy transfer 
34.50.Fa Electronic excitation and ionization of atoms (including beam-foil excitation and ionization) 
34.50.Gb Electronic excitation and ionization of molecules 
34.50.Lf Chemical reactions 
34.50.Rk Laser-modified scattering and reactions 
34.70.+e Charge transfer (for charge transfer in biological systems, see 82.39.Jn in physical chemistry)
34.80.-i Electron and positron scattering 
34.80.Bm Elastic scattering 
34.80.Dp Atomic excitation and ionization 
34.80.Gs Molecular excitation and ionization 
34.80.Ht Dissociation and dissociative attachment 
34.80.Lx Recombination, attachment, and positronium formation 
34.80.Nz Spin dependence of cross sections; polarized beam experiments 
34.80.Pa Coherence and correlation 
34.80.Qb Laser-modified scattering 
34.80.Uv Positron scattering 
34.90.+q Other topics in atomic and molecular collision processes and interactions (restricted to new topics in section 34) 
36.00.00 Exotic atoms and molecules; macromolecules; clusters 
36.10.-k Exotic atoms and molecules (containing mesons, antiprotons and other unusual particles) 
36.10.Dr Positronium (see also 82.30.Gg Positronium chemistry)
36.10.Ee Muonium, muonic atoms and molecules [see also 31.30.jr QED corrections (Lamb shift) in muonic hydrogen and deuterium]
36.10.Gv Mesonic, hyperonic and antiprotonic atoms and molecules 
36.20.-r Macromolecules and polymer molecules 
36.20.Cw Molecular weights, dispersity 
36.20.Ey Conformation (statistics and dynamics) 
36.20.Fz Constitution (chains and sequences) 
36.20.Hb Configuration (bonds, dimensions) 
36.20.Kd Electronic structure and spectra 
36.20.Ng Vibrational and rotational structure, infrared and Raman spectra 
36.40.-c Atomic and molecular clusters (see also 61.46.-w Nanoscale materials in condensed matter)
36.40.Cg Electronic and magnetic properties of clusters 
36.40.Ei Phase transitions in clusters 
36.40.Gk Plasma and collective effects in clusters 
36.40.Jn Reactivity of clusters 
36.40.Mr Spectroscopy and geometrical structure of clusters 
36.40.Qv Stability and fragmentation of clusters 
36.40.Sx Diffusion and dynamics of clusters 
36.40.Vz Optical properties of clusters 
36.40.Wa Charged clusters 
36.90.+f Other topics in exotic atoms and molecules; macromolecules; clusters (restricted to new topics in section 36) 
37.00.00 Mechanical control of atoms, molecules, and ions (see also 82.37.Gk STM and AFM manipulations of a single molecule in physical chemistry and chemical physics; for atom manipulation in nanofabrication and processing, see 81.16.Ta; see also 03.75.-b Matter waves)
37.10.-x Atom, molecule, and ion cooling methods (see also 87.80.Cc Optical trapping in biophysical techniques)
37.10.De Atom cooling methods 
37.10.Gh Atom traps and guides 
37.10.Jk Atoms in optical lattices 
37.10.Mn Slowing and cooling of molecules 
37.10.Pq Trapping of molecules 
37.10.Rs Ion cooling 
37.10.Ty Ion trapping 
37.10.Vz Mechanical effects of light on atoms, molecules, and ions 
37.20.+j Atomic and molecular beam sources and techniques 
37.25.+k Atom interferometry techniques (see also 03.75.Dg Atom and neutron interferometry in matter waves)
37.30.+i Atoms, molecules, and ions in cavities (see also 42.50.Pq Cavity quantum electrodynamics; micromasers)
37.90.+j Other topics in mechanical control of atoms, molecules, and ions (restricted to new topics in section 37) 
40.00.00 ELECTROMAGNETISM, OPTICS, ACOUSTICS, HEAT TRANSFER, CLASSICAL MECHANICS, AND FLUID DYNAMICS 
41.00.00 Electromagnetism; electron and ion optics 
41.20.-q Applied classical electromagnetism (for submillimeter wave, microwave, and radiowave instruments and equipment, see 07.57.-c)
41.20.Cv Electrostatics; Poisson and Laplace equations, boundary-value problems 
41.20.Gz Magnetostatics; magnetic shielding, magnetic induction, boundary-value problems 
41.20.Jb Electromagnetic wave propagation; radiowave propagation (for light propagation, see 42.25.Bs; for electromagnetic waves in plasma, see 52.35.Hr; for atmospheric, ionospheric, and magnetospheric propagation, see 92.60.Ta, 94.20.Bb, and 94.30.Tz, respectively; see also 94.05.Pt Wave/wave, wave/particle interactions, in space plasma physics)
41.50.+h X-ray beam source magnets and x-ray optics for control of particle beams (see also 07.85.Fv X- and gamma-ray sources, mirrors, gratings, and detectors in instruments)
41.60.-m Radiation by moving charges 
41.60.Ap Synchrotron radiation (for synchrotron radiation instrumentation, see 07.85.Qe)
41.60.Bq Cherenkov radiation 
41.60.Cr Free-electron lasers (see also 52.59.Rz Free-electron devices-in plasma physics)
41.60.Dk Transition radiation 
41.75.-i Charged-particle beams 
41.75.Ak Positive-ion beams 
41.75.Cn Negative-ion beams 
41.75.Fr Electron and positron beams 
41.75.Ht Relativistic electron and positron beams 
41.75.Jv Laser-driven acceleration (see also 52.38.-r Laser-plasma interactions in plasma physics)
41.75.Lx Other advanced accelerator concepts 
41.85.-p Beam optics (see also 07.77.Ka Charged-particle beam sources and detectors in instruments; 29.27.-a Beams in particle accelerators)
41.85.Ar Particle beam extraction, beam injection 
41.85.Ct Particle beam shaping, beam splitting 
41.85.Ew Particle beam profile, beam intensity 
41.85.Gy Chromatic and geometrical aberrations 
41.85.Ja Particle beam transport 
41.85.Lc Particle beam focusing and bending magnets, wiggler magnets, and quadrupoles (see also 07.55.Db Generation of magnetic fields; magnets in instruments; for superconducting magnets, see 84.71.Ba)
41.85.Ne Electrostatic lenses, septa 
41.85.Qg Particle beam analyzers, beam monitors, and Faraday cups 
41.85.Si Particle beam collimators, monochromators 
41.90.+e Other topics in electromagnetism; electron and ion optics (restricted to new topics in section 41) 
42.00.00 Optics (for optical properties of gases, see 51.70.+f; for optical properties of bulk materials and thin films, see 78.20.-e; for x-ray optics, see 41.50.+h)
42.15.-i Geometrical optics 
42.15.Dp Wave fronts and ray tracing 
42.15.Eq Optical system design 
42.15.Fr Aberrations 
42.25.-p Wave optics 
42.25.Bs Wave propagation, transmission and absorption [see also 41.20.Jb-in electromagnetism; for propagation in atmosphere, see 42.68.Ay; see also 52.40.Db Electromagnetic (nonlaser) radiation interactions with plasma and 52.38-r Laser-plasma interactions-in plasma physics]
42.25.Dd Wave propagation in random media 
42.25.Fx Diffraction and scattering 
42.25.Gy Edge and boundary effects; reflection and refraction 
42.25.Hz Interference 
42.25.Ja Polarization 
42.25.Kb Coherence 
42.25.Lc Birefringence 
42.30.-d Imaging and optical processing 
42.30.Kq Fourier optics 
42.30.Lr Modulation and optical transfer functions 
42.30.Ms Speckle and moire patterns 
42.30.Rx Phase retrieval 
42.30.Sy Pattern recognition 
42.30.Tz Computer vision; robotic vision 
42.30.Va Image forming and processing 
42.30.Wb Image reconstruction; tomography 
42.40.-i Holography 
42.40.Eq Holographic optical elements; holographic gratings 
42.40.Ht Hologram recording and readout methods (see also 42.70.Ln Holographic recording materials; optical storage media)
42.40.Jv Computer-generated holograms 
42.40.Kw Holographic interferometry; other holographic techniques (for interferometers, see 07.60.Ly in instruments)
42.40.Lx Diffraction efficiency, resolution, and other hologram characteristics 
42.40.My Applications 
42.40.Pa Volume holograms 
42.50.-p Quantum optics (for lasers, see 42.55.-f and 42.60.-v; see also 42.65.-k Nonlinear optics; 03.65.-w Quantum mechanics)
42.50.Ar Photon statistics and coherence theory 
42.50.Ct Quantum description of interaction of light and matter; related experiments 
42.50.Dv Quantum state engineering and measurements (see also 03.65.Ud Entanglement and quantum nonlocality, e.g., EPR paradox, Bells inequalities, GHZ states, etc.)
42.50.Ex Optical implementations of quantum information processing and transfer 
42.50.Gy Effects of atomic coherence on propagation, absorption, and amplification of light; electromagnetically induced transparency and absorption 
42.50.Hz Strong-field excitation of optical transitions in quantum systems; multiphoton processes; dynamic Stark shift (for multiphoton ionization and excitation of atoms and molecules, see 32.80.Rm, and 33.80.Rv, respectively)
42.50.Lc Quantum fluctuations, quantum noise, and quantum jumps 
42.50.Md Optical transient phenomena: quantum beats, photon echo, free-induction decay, dephasings and revivals, optical nutation, and self-induced transparency 
 ... ... Dynamics of nonlinear optical systems; optical instabilities, optical chaos, and optical spatio-temporal dynamics, see 42.65.Sf 
 ... ... Optical solitons; nonlinear guided waves, see 42.65.Tg 
42.50.Nn Quantum optical phenomena in absorbing, amplifying, dispersive and conducting media; cooperative phenomena in quantum optical systems 
42.50.Pq Cavity quantum electrodynamics; micromasers 
42.50.St Nonclassical interferometry, subwavelength lithography 
42.50.Tx Optical angular momentum and its quantum aspects (see also 42.25.Ja Polarization)
 ... ... Mechanical effects of light on atoms, molecules, and ions, see 37.10.Vz 
42.50.Wk Mechanical effects of light on material media, microstructures and particles (see also 87.80.Cc Optical trapping in biology and medicine)
 ... ... Experimental tests in quantum electrodynamics, see 12.20.Fv 
 ... ... Measurements theory in quantum mechanics, see 03.65.Ta 
42.50.Xa Optical tests of quantum theory 
42.55.-f Lasers 
42.55.Ah General laser theory 
42.55.Ks Chemical lasers (for chemiluminescence, see 78.60.Ps)
42.55.Lt Gas lasers including excimer and metal-vapor lasers 
42.55.Mv Dye lasers 
42.55.Px Semiconductor lasers; laser diodes 
42.55.Rz Doped-insulator lasers and other solid state lasers 
42.55.Sa Microcavity and microdisk lasers 
42.55.Tv Photonic crystal lasers and coherent effects 
42.55.Vc X- and gamma-ray lasers 
42.55.Wd Fiber lasers 
42.55.Xi Diode-pumped lasers 
42.55.Ye Raman lasers (see also 42.65.Dr Stimulated Raman scattering; CARS)
 ... ... Free-electron lasers, see 41.60.Cr and 52.59.Rz 
42.55.Zz Random lasers 
42.60.-v Laser optical systems: design and operation 
42.60.By Design of specific laser systems 
42.60.Da Resonators, cavities, amplifiers, arrays, and rings 
42.60.Fc Modulation, tuning, and mode locking 
42.60.Gd Q-switching 
42.60.Jf Beam characteristics: profile, intensity, and power; spatial pattern formation 
42.60.Lh Efficiency, stability, gain, and other operational parameters 
42.60.Mi Dynamical laser instabilities; noisy laser behavior 
42.60.Pk Continuous operation 
42.60.Rn Relaxation oscillations and long pulse operation 
 ... ... Ultrashort pulse generation, see 42.65.Re 
 ... ... Dynamics of nonlinear optical systems, see 42.65.Sf 
42.62.-b Laser applications 
42.62.Be Biological and medical applications (see also 87.50.W-, 87.63.L-, and 87.80.Cc in biological and medical physics)
42.62.Cf Industrial applications 
42.62.Eh Metrological applications; optical frequency synthesizers for precision spectroscopy (see also 06.20.-f Metrology in metrology, measurements, and laboratory procedures)
42.62.Fi Laser spectroscopy 
42.65.-k Nonlinear optics 
42.65.An Optical susceptibility, hyperpolarizability [see also 33.15.Kr Electric and magnetic moments (and derivatives), polarizability, and magnetic susceptibility]
42.65.Dr Stimulated Raman scattering; CARS (for Raman lasers, see 42.55.Ye)
42.65.Es Stimulated Brillouin and Rayleigh scattering 
42.65.Hw Phase conjugation; photorefractive and Kerr effects 
42.65.Jx Beam trapping, self-focusing and defocusing; self-phase modulation 
42.65.Ky Frequency conversion; harmonic generation, including higher-order harmonic generation (see also 42.79.Nv Optical frequency converters)
42.65.Lm Parametric down conversion and production of entangled photons (see also 42.50.Dv Quantum state engineering and measurements; for optical parametric oscillators and amplifiers, see 42.65.Yj)
42.65.Pc Optical bistability, multistability, and switching, including local field effects (see also 42.60.Gd Q-switching; 42.79.Ta Optical computers, logic elements, interconnects, switches; neural networks)
42.65.Re Ultrafast processes; optical pulse generation and pulse compression 
42.65.Sf Dynamics of nonlinear optical systems; optical instabilities, optical chaos and complexity, and optical spatio-temporal dynamics 
42.65.Tg Optical solitons; nonlinear guided waves (for solitons in fibers, see 42.81.Dp)
42.65.Wi Nonlinear waveguides 
42.65.Yj Optical parametric oscillators and amplifiers (see also 42.65.Lm Parametric down conversion and production of entangled photons)
42.66.-p Physiological optics (see also 87.19.lt Sensory systems: visual, auditory, tactile, taste, and olfaction)
42.66.Ct Anatomy and optics of eye 
42.66.Ew Physiology of eye; optic-nerve structure and function (see also 87.19.lt Sensory systems: visual, auditory, tactile, taste, and olfaction)
42.66.Lc Vision: light detection, adaptation, and discrimination 
42.66.Ne Color vision: color detection, adaptation, and discrimination 
42.66.Qg Scales for light and color detection 
42.66.Si Psychophysics of vision, visual perception; binocular vision 
42.68.-w Atmospheric and ocean optics 
42.68.Ay Propagation, transmission, attenuation, and radiative transfer (see also 92.60.Ta Electromagnetic wave propagation)
42.68.Bz Atmospheric turbulence effects (see also 92.60.hk Convection, turbulence, and diffusion in meteorology)
42.68.Ca Spectral absorption by atmospheric gases (see also 92.60.Vb Radiative processes, solar radiation in meteorology)
42.68.Ge Effects of clouds and water; ice crystal phenomena (see also 92.60.Jq Water in the atmosphere; 92.60.Nv Cloud physics and chemistry in meteorology)
42.68.Jg Effects of aerosols (see also 92.60.Mt Particles and aerosols in meteorology; 92.20.Bk Aerosols in chemical and biological oceanography; 91.40.Dr Atmospheric effects in volcanology)
42.68.Kh Effects of air pollution (see also 92.60.Sz Air quality and air pollution in meteorology; 92.10.Xc Ocean fog in oceanography)
42.68.Mj Scattering, polarization (see also 92.60.Ta Electromagnetic wave propagation and 92.60.Vb Radiative processes, solar radiation in meteorology)
42.68.Sq Image transmission and formation 
42.68.Wt Remote sensing; LIDAR and adaptive systems 
42.68.Xy Ocean optics (see also 92.05.Hj Physical and chemical properties of sea water in oceanography)
42.70.-a Optical materials (see also 81.05.-t Specific materials: fabrication, treatment, testing and analysis)
42.70.Ce Glasses, quartz 
42.70.Df Liquid crystals (for structure of liquid crystals, see 61.30.-v)
42.70.Gi Light-sensitive materials 
42.70.Hj Laser materials 
42.70.Jk Polymers and organics 
42.70.Km Infrared transmitting materials 
42.70.Ln Holographic recording materials; optical storage media 
42.70.Mp Nonlinear optical crystals (see also 77.84.-s Dielectric, piezoelectric, and ferroelectric materials)
42.70.Nq Other nonlinear optical materials; photorefractive and semiconductor materials 
42.70.Qs Photonic bandgap materials (for photonic crystal lasers, see 42.55.Tv)
42.72.-g Optical sources and standards (for lasers, see 42.55.-f)
42.72.Ai Infrared sources (see also 07.57.Hm Infrared, submillimeter wave, microwave, and radiowave sources)
42.72.Bj Visible and ultraviolet sources 
42.79.-e Optical elements, devices, and systems (for integrated optics, see 42.82.-m; for fiber optics, see 42.81.-i)
 ... ... Optical instruments, equipment and techniques, see 07.60.-j and 07.57.-c 
 ... ... Optical spectrometers, see 07.57.Ty and 07.60.Rd 
 ... ... Photography, photographic instruments and techniques, see 07.68.+m 
 ... ... Magnetooptical devices, see 85.70.Sq 
42.79.Ag Apertures, collimators 
42.79.Bh Lenses, prisms and mirrors 
42.79.Ci Filters, zone plates, and polarizers 
42.79.Dj Gratings (for holographic gratings, see 42.40.Eq)
42.79.Ek Solar collectors and concentrators (see also 84.60.Jt Photoelectric conversion: solar cells and arrays)
42.79.Fm Reflectors, beam splitters, and deflectors 
42.79.Gn Optical waveguides and couplers (for fiber waveguides and waveguides in integrated optics, see 42.81.Qb and 42.82.Et, respectively)
42.79.Hp Optical processors, correlators, and modulators 
42.79.Jq Acousto-optical devices (see also 43.38.Zp-in Acoustics Appendix)
42.79.Kr Display devices, liquid-crystal devices (see also 85.60.Pg Display systems)
42.79.Ls Scanners, image intensifiers, and image converters (see also 85.60.-q Optoelectronic devices)
42.79.Mt Schlieren devices 
42.79.Nv Optical frequency converters 
42.79.Pw Imaging detectors and sensors (see also 85.60.Gz Photodetectors)
42.79.Qx Range finders, remote sensing devices; laser Doppler velocimeters, SAR, and LIDAR (see also 42.68.Wt Remote sensing; LIDAR and adaptive systems)
42.79.Ry Gradient-index (GRIN) devices (for fiber GRIN devices, see 42.81.Ht)
42.79.Sz Optical communication systems, multiplexers, and demultiplexers (for fiber networks, see 42.81.Uv)
42.79.Ta Optical computers, logic elements, interconnects, switches; neural networks 
42.79.Vb Optical storage systems, optical disks (see also 42.40.Ht Hologram recording and readout methods)
42.79.Wc Optical coatings 
42.81.-i Fiber optics 
 ... ... Fiber-optic instruments, see 07.60.Vg 
42.81.Bm Fabrication, cladding, and splicing 
42.81.Cn Fiber testing and measurement of fiber parameters 
42.81.Dp Propagation, scattering, and losses; solitons 
42.81.Gs Birefringence, polarization 
42.81.Ht Gradient-index (GRIN) fiber devices 
42.81.Pa Sensors, gyros 
42.81.Qb Fiber waveguides, couplers, and arrays 
42.81.Uv Fiber networks (see also 42.79.Sz Optical communication systems, multiplexers, and demultiplexers)
42.81.Wg Other fiber-optical devices (for fiber lasers, see 42.55.Wd)
42.82.-m Integrated optics 
42.82.Bq Design and performance testing of integrated-optical systems 
42.82.Cr Fabrication techniques; lithography, pattern transfer (see also 85.40.-e Microelectronics: LSI, VLSI, ULSI; integrated circuit fabrication technology)
42.82.Ds Interconnects, including holographic interconnects (see also 42.79.Ta Optical computers, logic elements, interconnects, switches; neural networks)
42.82.Et Waveguides, couplers, and arrays (for fiber waveguides, see 42.81.Qb)
42.82.Fv Hybrid systems 
42.82.Gw Other integrated-optical elements and systems 
42.86.+b Optical workshop techniques 
42.87.-d Optical testing techniques 
42.87.Bg Phase shifting interferometry (for interferometers, see 07.60.Ly in instruments)
42.88.+h Environmental and radiation effects on optical elements, devices, and systems 
42.90.+m Other topics in optics (restricted to new topics in section 42) 
43.00.00 Acoustics (for more detailed headings, see Appendix to section 43)
43.20.+g General linear acoustics 
43.25.+y Nonlinear acoustics 
43.28.+h Aeroacoustics and atmospheric sound (see also 92.60.hh Acoustic gravity waves, tides, and compressional waves in meteorology)
43.30.+m Underwater sound (see also 92.10.Vz-in physical oceanography)
43.35.+d Ultrasonics, quantum acoustics, and physical effects of sound 
 ... ... Phonons in crystal lattices, see 63.20.-e 
 ... ... Acoustical properties of rocks and minerals, see 91.60.Lj 
 ... ... Sound waves in plasma, see 52.35.Dm 
 ... ... Low-temperature acoustics and sound in liquid helium, see section 67 
 ... ... Acoustical properties and ultrasonic relaxation of solids, see 62.65.+k and 62.80.+f 
 ... ... Acoustic properties of thin films, see 68.60.Bs 
 ... ... Acoustoelectric effects, see 72.50.+b and 73.50.Rb 
 ... ... Magnetoacoustic effects, oscillations, and resonance, see 72.55.+s, 73.50.Rb, and 75.80.+q 
 ... ... Acoustic holography, see 43.60.Sx in Acoustics Appendix; 
 ... ... Sound waves in fluid dynamics, see 47.35.Rs 
 ... ... Acoustooptical effects, see 78.20.Hp 
43.38.+n Transduction; acoustical devices for the generation and reproduction of sound 
43.40.+s Structural acoustics and vibration 
43.50.+y Noise: its effects and control 
43.55.+p Architectural acoustics 
43.58.+z Acoustical measurements and instrumentation 
43.60.+d Acoustic signal processing 
43.64.+r Physiological acoustics 
 ... ... Biological effects of sound and ultrasound, see 87.50.Y- 
43.66.+y Psychological acoustics 
43.70.+i Speech production 
43.71.+m Speech perception 
43.72.+q Speech processing and communication systems 
43.75.+a Music and musical instruments 
43.80.+p Bioacoustics 
43.90.+v Other topics in acoustics (restricted to new topics in section 43) 
44.00.00 Heat transfer 
44.05.+e Analytical and numerical techniques 
44.10.+i Heat conduction (see also 66.25.+g and 66.70.-f in nonelectronic transport properties of condensed matter)
44.15.+a Channel and internal heat flow 
44.20.+b Boundary layer heat flow 
44.25.+f Natural convection (see also 47.27.te Turbulent convective heat transfer in fluid dynamics)
44.27.+g Forced convection 
44.30.+v Heat flow in porous media 
44.35.+c Heat flow in multiphase systems 
44.40.+a Thermal radiation 
44.90.+c Other topics in heat transfer (restricted to new topics in section 44) 
45.00.00 Classical mechanics of discrete systems 
45.05.+x General theory of classical mechanics of discrete systems 
45.10.-b Computational methods in classical mechanics (see also 02.70.-c Computational techniques in mathematical methods in physics)
45.10.Db Variational and optimization methods 
45.10.Hj Perturbation and fractional calculus methods 
45.10.Na Geometrical and tensorial methods 
45.20.-d Formalisms in classical mechanics 
45.20.D- Newtonian mechanics 
45.20.da Forces and torques 
45.20.dc Rotational dynamics 
45.20.df Momentum conservation 
45.20.dg Mechanical energy, work, and power 
45.20.dh Energy conservation 
45.20.Jj Lagrangian and Hamiltonian mechanics 
45.30.+s General linear dynamical systems (for nonlinear dynamical systems, see 05.45.-a)
45.40.-f Dynamics and kinematics of rigid bodies 
45.40.Aa Translation kinematics 
45.40.Bb Rotational kinematics 
45.40.Cc Rigid body and gyroscope motion 
45.40.Gj Ballistics (projectiles; rockets) 
45.40.Ln Robotics 
45.50.-j Dynamics and kinematics of a particle and a system of particles 
45.50.Dd General motion 
45.50.Jf Few- and many-body systems 
45.50.Pk Celestial mechanics (see also 95.10.Ce in fundamental astronomy)
45.50.Tn Collisions 
45.70.-n Granular systems (see also 05.65.+b Self-organized systems)
45.70.Cc Static sandpiles; granular compaction 
45.70.Ht Avalanches 
45.70.Mg Granular flow: mixing, segregation and stratification 
45.70.Qj Pattern formation 
45.70.Vn Granular models of complex systems; traffic flow 
45.80.+r Control of mechanical systems (see also 46.80.+j Measurement methods and techniques in continuum mechanics of solids)
45.90.+t Other topics in classical mechanics of discrete systems (restricted to new topics in section 45) 
46.00.00 Continuum mechanics of solids (see also 83.10.Ff in rheology; 91.60.Ba Elasticity, fracture, and flow; 91.45.Ga Dynamics and mechanics of tectonics; 91.55.Ln Kinematics of crustal and mantle deformation in geophysics)
46.05.+b General theory of continuum mechanics of solids 
46.15.-x Computational methods in continuum mechanics (see also 02.70.-c Computational techniques; simulations, in mathematical methods in physics)
46.15.Cc Variational and optimizational methods 
46.15.Ff Perturbation and complex analysis methods 
46.25.-y Static elasticity 
46.25.Cc Theoretical studies 
46.25.Hf Thermoelasticity and electromagnetic elasticity (electroelasticity, magnetoelasticity) 
46.32.+x Static buckling and instability 
46.35.+z Viscoelasticity, plasticity, viscoplasticity (see also 83.60.Bc, Df, in rheology; 91.60.Dc Plasticity, diffusion, and creep in physical properties of rocks and minerals)
46.40.-f Vibrations and mechanical waves (see also 43.40.+s Structural acoustics and vibration; 62.30.+d Mechanical and elastic waves; vibrations in mechanical properties of solids)
46.40.Cd Mechanical wave propagation (including diffraction, scattering, and dispersion) 
46.40.Ff Resonance, damping, and dynamic stability 
46.40.Jj Aeroelasticity and hydroelasticity 
46.50.+a Fracture mechanics, fatigue and cracks (see also 62.20.M- Structural failure of materials in mechanical properties of condensed matter)
46.55.+d Tribology and mechanical contacts (see also 81.40.Pq Friction, lubrication and wear in materials science; 62.20.Qp Friction, tribology and hardness in mechanical properties of solids)
46.65.+g Random phenomena and media (see also 05.40.-a Fluctuation phenomena, random processes, noise, and Brownian motion)
46.70.-p Application of continuum mechanics to structures 
46.70.De Beams, plates, and shells 
46.70.Hg Membranes, rods, and strings 
46.70.Lk Other structures 
46.80.+j Measurement methods and techniques in continuum mechanics of solids (for mechanical instruments, equipment, and techniques, see 07.10.-h in instruments)
46.90.+s Other topics in continuum mechanics of solids (restricted to new topics in section 46) 
47.00.00 Fluid dynamics (for fluid dynamics of quantum fluids, see section 67; see also section 83 Rheology; for sound generation by fluid flow, see 43.28.Ra-in Acoustics Appendix)
47.10.-g General theory in fluid dynamics 
47.10.A- Mathematical formulations 
47.10.ab Conservation laws and constitutive relations 
47.10.ad Navier-Stokes equations 
47.10.Df Hamiltonian formulations 
47.10.Fg Dynamical systems methods 
47.11.-j Computational methods in fluid dynamics 
47.11.Bc Finite difference methods 
47.11.Df Finite volume methods 
47.11.Fg Finite element methods 
47.11.Hj Boundary element methods 
47.11.Kb Spectral methods 
47.11.Mn Molecular dynamics methods 
47.11.Qr Lattice gas 
47.11.St Multi-scale methods 
47.15.-x Laminar flows 
47.15.Cb Laminar boundary layers 
47.15.Fe Stability of laminar flows 
47.15.G- Low-Reynolds-number (creeping) flows 
47.15.gm Thin film flows 
47.15.gp Hele-Shaw flows 
47.15.K- Inviscid laminar flows 
47.15.ki Inviscid flows with vorticity 
47.15.km Potential flows 
47.15.Rq Laminar flows in cavities, channels, ducts, and conduits 
47.15.St Free shear layers 
47.15.Tr Laminar wakes 
47.15.Uv Laminar jets 
47.20.-k Flow instabilities (see also 47.15.Fe Stability of laminar flows)
47.20.Bp Buoyancy-driven instabilities (e.g., Rayleigh-Benard) 
47.20.Cq Inviscid instability 
47.20.Dr Surface-tension-driven instability 
47.20.Ft Instability of shear flows (e.g., Kelvin-Helmholtz) 
47.20.Gv Viscous and viscoelastic instabilities 
47.20.Hw Morphological instability; phase changes 
47.20.Ib Instability of boundary layers; separation 
47.20.Ky Nonlinearity, bifurcation, and symmetry breaking 
47.20.Lz Secondary instabilities 
47.20.Ma Interfacial instabilities (e.g., Rayleigh-Taylor) 
47.20.Pc Flow receptivity 
47.20.Qr Centrifugal instabilities (e.g., Taylor-Couette flow) 
47.27.-i Turbulent flows 
47.27.Ak Fundamentals 
47.27.Cn Transition to turbulence 
47.27.De Coherent structures 
47.27.E- Turbulence simulation and modeling 
47.27.eb Statistical theories and models 
47.27.ed Dynamical systems approaches 
47.27.ef Field-theoretic formulations and renormalization 
47.27.ek Direct numerical simulations 
47.27.em Eddy-viscosity closures; Reynolds stress modeling 
47.27.ep Large-eddy simulations 
47.27.er Spectral methods 
47.27.Gs Isotropic turbulence; homogeneous turbulence 
47.27.Jv High-Reynolds-number turbulence 
47.27.N- Wall-bounded shear flow turbulence 
47.27.nb Boundary layer turbulence 
47.27.nd Channel flow 
47.27.nf Flows in pipes and nozzles 
47.27.Rc Turbulence control 
47.27.Sd Turbulence generated noise 
47.27.T- Turbulent transport processes 
47.27.tb Turbulent diffusion 
47.27.te Turbulent convective heat transfer 
47.27.W- Boundary-free shear flow turbulence 
47.27.wb Turbulent wakes 
47.27.wg Turbulent jets 
47.27.wj Turbulent mixing layers 
47.32.-y Vortex dynamics; rotating fluids (for vortices in superfluid helium, see 67.25.dk and 67.30.he)
47.32.C- Vortex dynamics 
47.32.cb Vortex interactions 
47.32.cd Vortex stability and breakdown 
47.32.cf Vortex reconnection and rings 
47.32.ck Vortex streets 
47.32.Ef Rotating and swirling flows 
47.32.Ff Separated flows 
47.35.-i Hydrodynamic waves (see also 47.65.-d Magnetohydrodynamics and electrohydrodynamics; 52.35.Bj Magnetohydrodynamic waves; 52.35.Dm Sound waves in Physics of plasmas and electric discharges)
47.35.Bb Gravity waves 
47.35.De Shear waves 
47.35.Fg Solitary waves 
47.35.Jk Wave breaking 
47.35.Lf Wave-structure interactions 
47.35.Pq Capillary waves 
47.35.Rs Sound waves 
47.35.Tv Magnetohydrodynamic waves 
47.37.+q Hydrodynamic aspects of superfluidity; quantum fluids (for transport and hydrodynamics of normal and superfluid phase of <sup>4</sup>He, see 67.25.bf, and 67.25.dg respectively; for transport and hydrodynamics of normal and superfluid phase of <sup>3</sup>He, see 67.30.eh, and 67.30.hb respectively)
47.40.-x Compressible flows; shock waves (see also 43.25.Cb Macrosonic propagation, finite amplitude sound; shock waves in Acoustics Appendix; 52.35.Tc Shock waves and discontinuities in Physics of plasmas and electric discharges; 82.40.Fp Shock wave initiated reactions, high-pressure chemistry in Physical chemistry and chemical physics)
47.40.Dc General subsonic flows 
47.40.Hg Transonic flows 
47.40.Ki Supersonic and hypersonic flows 
47.40.Nm Shock wave interactions and shock effects (for shock wave initiated chemical reactions, see 82.40.Fp)
47.40.Rs Detonation waves 
47.45.-n Rarefied gas dynamics 
47.45.Ab Kinetic theory of gases 
47.45.Dt Free molecular flows 
47.45.Gx Slip flows and accommodation 
47.50.-d Non-Newtonian fluid flows 
47.50.Cd Modeling 
47.50.Ef Measurements 
47.50.Gj Instabilities 
47.51.+a Mixing (see also 64.75.Ef Mixing in Equations of state, phase equilibria, and phase transitions; 82.60.Lf Thermodynamics of solutions in Physical chemistry and chemical physics; 83.50.Xa Mixing and blending in Rheology)
47.52.+j Chaos in fluid dynamics (see also 05.45.-a Nonlinear dynamics and chaos in Statistical physics, thermodynamics, and nonlinear dynamical systems)
47.53.+n Fractals in fluid dynamics (see also 05.45.Df Fractals in Statistical physics, thermodynamics, and nonlinear dynamical systems)
47.54.-r Pattern selection; pattern formation (see also 82.40.Ck Pattern formation in reactions with diffusion, flow and heat transfer in Physical chemistry and chemical physics; 87.18.Hf Spatiotemporal pattern formation in cellular populations in Biological and medical physics)
47.54.Bd Theoretical aspects 
47.54.De Experimental aspects 
47.54.Fj Chemical and biological applications 
47.54.Jk Materials science applications 
47.55.-t Multiphase and stratified flows 
47.55.Ca Gas/liquid flows 
47.55.D- Drops and bubbles 
47.55.db Drop and bubble formation 
47.55.dd Bubble dynamics 
47.55.df Breakup and coalescence 
47.55.dk Surfactant effects 
47.55.dm Thermocapillary effects 
47.55.dp Cavitation and boiling 
47.55.dr Interactions with surfaces 
47.55.Hd Stratified flows 
 ... ... Rotational flows, see 47.32.-y 
47.55.Iv Core-annular flows 
47.55.Kf Particle-laden flows 
47.55.Lm Fluidized beds 
47.55.N- Interfacial flows 
47.55.nb Capillary and thermocapillary flows 
47.55.nd Spreading films 
47.55.nk Liquid bridges 
47.55.nm Curtains/sheets 
47.55.np Contact lines 
47.55.P- Buoyancy-driven flows; convection 
47.55.pb Thermal convection 
47.55.pd Multidiffusive convection 
47.55.pf Marangoni convection 
47.56.+r Flows through porous media 
47.57.-s Complex fluids and colloidal systems (see also 82.70.-y Disperse systems; complex fluids in Physical chemistry and chemical physics; 83.80.Hj Suspensions, dispersions, pastes, slurries, colloids; 83.80.Iz Emulsions and foams in Rheology)
47.57.Bc Foams and emulsions 
47.57.E- Suspensions 
47.57.eb Diffusion and aggregation 
47.57.ef Sedimentation and migration 
47.57.Gc Granular flow 
47.57.J- Colloidal systems 
47.57.jb Microemulsions 
47.57.jd Electrokinetic effects 
47.57.Lj Flows of liquid crystals 
47.57.Ng Polymers and polymer solutions 
47.57.Qk Rheological aspects 
47.60.-i Flow phenomena in quasi-one-dimensional systems (see also 43.28.Py Interaction of fluid motion and sound, Doppler effect and sound in flow ducts in Acoustics Appendix; 47.15.Rq Laminar flows in cavities, channels, ducts and conduits; 47.27.nd Channel flows; 47.27.nf Flows in pipes and nozzles)	
47.60.Dx Flows in ducts and channels 
47.60.Kz Flows and jets through nozzles 
47.61.-k Micro- and nano- scale flow phenomena 
47.61.Cb Non-continuum effects 
47.61.Fg Flows in micro-electromechanical systems (MEMS) and nano-electromechanical systems (NEMS) 
47.61.Jd Multiphase flows 
47.61.Ne Micromixing 
47.63.-b Biological fluid dynamics (see also 87.19.U- Hemodynamics, 87.19.rh Fluid transport and rheology, 87.19.Wx Pneumodynamics, 87.85.gf Fluid mechanics and rheology in biological and medical physics)
47.63.Cb Blood flow in cardiovascular system 
47.63.Ec Pulmonary fluid mechanics 
47.63.Gd Swimming microorganisms 
47.63.Jd Microcirculation and flow through tissues 
47.63.M- Biopropulsion in water and air 
47.63.mc High-Reynolds-number motions 
47.63.mf Low-Reynolds-number motions 
47.63.mh Transport processes and drug delivery 
47.65.-d Magnetohydrodynamics and electrohydrodynamics (see also 47.35.Tv Magnetohydrodynamic waves; 52.30.Cv Magnetohydrodynamics, and 52.65.Kj Magnetohydrodynamics and fluid equation in Physics of plasmas and electric discharges; 83.80.Gv Electro- and magnetorheological fluids in Rheology)
47.65.Cb Magnetic fluids and ferrofluids 
47.65.Gx Electrorheological fluids 
47.65.Md Plasma dynamos 
47.70.-n Reactive and radiative flows (see also 82.33.Vx Reactions in flames, combustion and explosion; 82.33.Xj Plasma reactions (including flowing afterglow and electric discharges); 82.33.Ya Chemistry of MOCVD and other vapor deposition methods in Physical chemistry and chemical physics; 92.60.Vb Radiative processes, solar radiation in Hydrospheric and atmospheric geophysics)
47.70.Fw Chemically reactive flows (see also 83.80.Jx-in rheology)
47.70.Mc Radiation gas dynamics 
47.70.Nd Nonequilibrium gas dynamics 
47.70.Pq Flames; combustion 
47.75.+f Relativistic fluid dynamics (see also 52.27.Ny Relativistic plasmas in Physics of plasmas and electric discharges; 98.80.Jk Mathematical and relativistic aspects of cosmology in Stellar systems; interstellar medium; galactic and extragalactic objects and systems; the Universe)
47.80.-v Instrumentation and measurement methods in fluid dynamics 
47.80.Cb Velocity measurements 
47.80.Fg Pressure and temperature measurements 
47.80.Jk Flow visualization and imaging 
47.85.-g Applied fluid mechanics 
47.85.Dh Hydrodynamics, hydraulics, hydrostatics 
47.85.Gj Aerodynamics 
47.85.Kn Hydraulic and pneumatic machinery 
47.85.L- Flow control 
47.85.lb Drag reduction 
47.85.ld Boundary layer control 
47.85.lf Flow noise reduction 
47.85.lk Mixing enhancement 
47.85.M- Material processing flows; industrial applications 
47.85.mb Coating flows 
47.85.md Polymer processing flows 
47.85.mf Lubrication flows 
47.85.Np Fluidics 
 ... ... Atmospheric circulation, see 92.60.Bh 
 ... ... Atmospheric boundary layer processes, see 92.60.Fm 
 ... ... Atmospheric turbulence, see 92.60.hk 
 ... ... Storms, see 92.60.Qx 
 ... ... Hydrodynamics of the oceans, see 92.10.-c 
 ... ... Mantle convection, see 91.45.Fj 
 ... ... Lava and magma rheology, see 83.80.Nb, 91.40.Hw, and 91.40.Jk 
 ... ... Groundwater flow, see 92.40.Kf 
 ... ... Role of fluids in structural geology, see 91.55.Tt 
 ... ... Flows in streams and rivers, see 92.40.Qk; 
 ... ... Geothermal fluids, see 91.40.Ge 
47.90.+a Other topics in fluid dynamics (restricted to new topics in section 47) 
50.00.00 PHYSICS OF GASES, PLASMAS, AND ELECTRIC DISCHARGES 
51.00.00 Physics of gases 
51.10.+y Kinetic and transport theory of gases (see also 05.20.Dd Kinetic theory in classical statistical mechanics; see also 47.70.Mc Radiation gas dynamics)
51.20.+d Viscosity, diffusion, and thermal conductivity 
51.30.+i Thermodynamic properties, equations of state (see also 05.70.Ce Thermodynamic functions and equations of state in thermodynamics)
51.35.+a Mechanical properties; compressibility 
51.40.+p Acoustical properties (see also 43.28.-g Aeroacoustics and atmospheric sound in Acoustics Appendix; for ultrasonic relaxation in gases, see 43.35.Fj-
in Acoustics Appendix)
51.50.+v Electrical properties (ionization, breakdown, electron and ion mobility, etc.) (see also 52.80.-s Electric discharges in physics of plasmas)
51.60.+a Magnetic properties 
51.70.+f Optical and dielectric properties 
 ... ... Sorption, see 68.43.-h 
 ... ... Gas sensors and detectors, see 07.07.Df 
51.90.+r Other topics in the physics of gases (restricted to new topics in section 51) 
52.00.00 Physics of plasmas and electric discharges (for space plasma physics, see 94.05.-a; for astrophysical plasmas, see 95.30.Qd; for physics of the ionosphere and magnetosphere, see 94.20.-y and 94.30.-d respectively)
52.20.-j Elementary processes in plasmas 
52.20.Dq Particle orbits 
52.20.Fs Electron collisions 
52.20.Hv Atomic, molecular, ion, and heavy-particle collisions 
52.25.-b Plasma properties (for chemical reactions in plasma, see 82.33.Xj)
52.25.Dg Plasma kinetic equations 
52.25.Fi Transport properties 
52.25.Gj Fluctuation and chaos phenomena (for plasma turbulence, see 52.35.Ra; see also 05.45.-a Nonlinear dynamics and chaos)
52.25.Jm Ionization of plasmas 
52.25.Kn Thermodynamics of plasmas 
52.25.Mq Dielectric properties 
52.25.Os Emission, absorption, and scattering of electromagnetic radiation 
52.25.Tx Emission, absorption, and scattering of particles 
52.25.Vy Impurities in plasmas 
52.25.Xz Magnetized plasmas 
52.25.Ya Neutrals in plasmas 
52.27.-h Basic studies of specific kinds of plasmas 
52.27.Aj Single-component, electron-positive-ion plasmas 
52.27.Cm Multicomponent and negative-ion plasmas 
52.27.Ep Electron-positron plasmas 
52.27.Gr Strongly-coupled plasmas 
52.27.Jt Nonneutral plasmas 
52.27.Lw Dusty or complex plasmas; plasma crystals 
52.27.Ny Relativistic plasmas 
52.30.-q Plasma dynamics and flow 
52.30.Cv Magnetohydrodynamics (including electron magnetohydrodynamics) (see also 47.65.-d Magnetohydrodynamics and electrohydrodynamics in fluid dynamics; for MHD generators, see 52.75.Fk; see also 95.30.Qd Magnetohydrodynamics and plasmas in astrophysics)
52.30.Ex Two-fluid and multi-fluid plasmas 
52.30.Gz Gyrokinetics 
52.35.-g Waves, oscillations, and instabilities in plasmas and intense beams (see also 94.20.wf Plasma waves and instabilities in physics of the ionosphere; 94.30.cq MHD waves, plasma waves, and instabilities in physics of the magnetosphere; 96.50.Tf MHD waves, plasma waves, turbulence in interplanetary physics)
52.35.Bj Magnetohydrodynamic waves (e.g., Alfven waves) 
52.35.Dm Sound waves 
52.35.Fp Electrostatic waves and oscillations (e.g., ion-acoustic waves) 
52.35.Hr Electromagnetic waves (e.g., electron-cyclotron, Whistler, Bernstein, upper hybrid, lower hybrid) 
52.35.Kt Drift waves 
52.35.Lv Other linear waves 
52.35.Mw Nonlinear phenomena: waves, wave propagation, and other interactions (including parametric effects, mode coupling, ponderomotive effects, etc.) 
52.35.Py Macroinstabilities (hydromagnetic, e.g., kink, fire-hose, mirror, ballooning, tearing, trapped-particle, flute, Rayleigh-Taylor, etc.) 
52.35.Qz Microinstabilities (ion-acoustic, two-stream, loss-cone, beam-plasma, drift, ion- or electron-cyclotron, etc.) 
52.35.Ra Plasma turbulence 
52.35.Sb Solitons; BGK modes 
52.35.Tc Shock waves and discontinuities 
52.35.Vd Magnetic reconnection (see also 94.30.cp in physics of the magnetosphere)
52.35.We Plasma vorticity 
52.38.-r Laser-plasma interactions (for plasma production and heating by laser beams, see 52.50.Jm)
52.38.Bv Rayleigh scattering; stimulated Brillouin and Raman scattering 
52.38.Dx Laser light absorption in plasmas (collisional, parametric, etc.) 
52.38.Fz Laser-induced magnetic fields in plasmas 
52.38.Hb Self-focussing, channeling, and filamentation in plasmas 
52.38.Kd Laser-plasma acceleration of electrons and ions (see also 41.75.Jv Laser-driven acceleration in electromagnetism; electron and ion optics)
52.38.Mf Laser ablation (see also 79.20.Ds, Laser-beam impact phenomena)
52.38.Ph X-ray, gamma-ray, and particle generation 
52.40.-w Plasma interactions (nonlaser) 
52.40.Db Electromagnetic (nonlaser) radiation interactions with plasma (for electromagnetic wave propagation in the ionosphere and magnetosphere, see 94.20.Bb and 94.30.Tz respectively)
52.40.Fd Plasma interactions with antennas; plasma-filled waveguides 
52.40.Hf Plasma-material interactions; boundary layer effects 
52.40.Kh Plasma sheaths (see also 94.30.cj Magnetosheath)
52.40.Mj Particle beam interactions in plasmas 
52.50.-b Plasma production and heating (see also 52.80.-s Electric discharges)
52.50.Dg Plasma sources 
52.50.Gj Plasma heating by particle beams 
52.50.Jm Plasma production and heating by laser beams (laser-foil, laser-cluster, etc.) 
52.50.Lp Plasma production and heating by shock waves and compression 
52.50.Nr Plasma heating by DC fields; ohmic heating, arcs 
52.50.Qt Plasma heating by radio-frequency fields; ICR, ICP, helicons 
52.50.Sw Plasma heating by microwaves; ECR, LH, collisional heating 
52.55.-s Magnetic confinement and equilibrium (see also 28.52.-s Fusion reactors)
52.55.Dy General theory and basic studies of plasma lifetime, particle and heat loss, energy balance, field structure, etc. 
52.55.Ez Theta pinch 
52.55.Fa Tokamaks, spherical tokamaks 
52.55.Hc Stellarators, torsatrons, heliacs, bumpy tori, and other toroidal confinement devices 
52.55.Ip Spheromaks 
52.55.Jd Magnetic mirrors, gas dynamic traps 
52.55.Lf Field-reversed configurations, rotamaks, astrons, ion rings, magnetized target fusion, and cusps 
52.55.Pi Fusion products effects (e.g., alpha-particles, etc.), fast particle effects 
52.55.Rk Power exhaust; divertors 
52.55.Tn Ideal and resistive MHD modes; kinetic modes 
52.55.Wq Current drive; helicity injection 
52.57.-z Laser inertial confinement 
52.57.Bc Target design and fabrication 
52.57.Fg Implosion symmetry and hydrodynamic instability (Rayleigh-Taylor, Richtmyer-Meshkov, imprint, etc.) 
52.57.Kk Fast ignition of compressed fusion fuels 
52.58.-c Other confinement methods 
52.58.Ei Light-ion inertial confinement 
52.58.Hm Heavy-ion inertial confinement 
52.58.Lq Z-pinches, plasma focus, and other pinch devices 
52.58.Qv Electrostatic and high-frequency confinement 
52.59.-f Intense particle beams and radiation sources (see also 29.25.-t Particle sources and targets, and 29.27.-a Beams in particle accelerators, in instrumentation for elementary-particle and nuclear physics)
52.59.Bi Grid- and ion-diode-accelerated beams 
52.59.Dk Magneto-plasma accelerated plasmas 
52.59.Fn Multistage accelerated heavy-ion beams 
52.59.Hq Dense plasma focus 
52.59.Mv High-voltage diodes (for high-current and high-voltage technology, see 84.70.+p)
52.59.Px Hard X-ray sources 
52.59.Qy Wire array Z-pinches 
52.59.Rz Free-electron devices (for free-electron lasers, see 41.60.Cr)
52.59.Sa Space-charge-dominated beams 
52.59.Tb Moderate-intensity beams 
52.59.Wd Emittance-dominated beams 
52.59.Ye Plasma devices for generation of coherent radiation 
52.65.-y Plasma simulation 
52.65.Cc Particle orbit and trajectory 
52.65.Ff Fokker-Planck and Vlasov equation 
52.65.Kj Magnetohydrodynamic and fluid equation 
52.65.Pp Monte Carlo methods 
52.65.Rr Particle-in-cell method 
52.65.Tt Gyrofluid and gyrokinetic simulations 
52.65.Vv Perturbative methods 
52.65.Ww Hybrid methods 
52.65.Yy Molecular dynamics methods 
52.70.-m Plasma diagnostic techniques and instrumentation 
52.70.Ds Electric and magnetic measurements 
52.70.Gw Radio-frequency and microwave measurements 
52.70.Kz Optical (ultraviolet, visible, infrared) measurements 
52.70.La X-ray and gamma-ray measurements 
52.70.Nc Particle measurements 
52.72.+v Laboratory studies of space- and astrophysical-plasma processes (see also 94.05.Rx in space plasma physics)
52.75.-d Plasma devices (for ion sources, see 29.25.Lg, Ni; for plasma sources, see 52.50.Dg)
52.75.Di Ion and plasma propulsion 
52.75.Fk Magnetohydrodynamic generators and thermionic convertors; plasma diodes (see also 84.60.Lw, Ny in direct-energy conversion and storage)
52.75.Hn Plasma torches 
52.75.Kq Plasma switches (e.g., spark gaps) 
52.75.Xx Thermionic and filament-based sources (e.g., Q machines, double- and triple-plasma devices, etc.) 
52.77.-j Plasma applications 
52.77.Bn Etching and cleaning (see also 81.65.Cf Surface cleaning, etching, patterning in surface treatments)
52.77.Dq Plasma-based ion implantation and deposition (see also 81.15.Jj Ion and electron beam-assisted deposition)
52.77.Fv High-pressure, high-current plasmas (plasma spray, arc welding, etc.) (see also 81.15.Rs Spray coating techniques)
 ... ... Chemical synthesis; combustion synthesis, see 81.20.Ka 
52.80.-s Electric discharges (see also 51.50.+v Electrical properties of gases; for plasma reactions including flowing afterglow and electric discharges, see 82.33.Xj in physical chemistry and chemical physics)
52.80.Dy Low-field and Townsend discharges 
52.80.Hc Glow; corona 
52.80.Mg Arcs; sparks; lightning; atmospheric electricity (see also 92.60.Pw Atmospheric electricity, lightning in meteorology)
52.80.Pi High-frequency and RF discharges 
52.80.Qj Explosions; exploding wires 
52.80.Sm Magnetoactive discharges (e.g., Penning discharges) 
52.80.Tn Other gas discharges 
52.80.Vp Discharge in vacuum 
52.80.Wq Discharge in liquids and solids (for electric breakdown in liquids, see 77.22.Jp)
52.80.Yr Discharges for spectral sources (including inductively coupled plasma) 
52.90.+z Other topics in physics of plasmas and electric discharges (restricted to new topics in section 52) 
60.00.00 CONDENSED MATTER: STRUCTURAL, MECHANICAL, AND THERMAL PROPERTIES 
61.00.00 Structure of solids and liquids; crystallography (for surface, interface, and thin film structure, see section 68)
61.05.-a Techniques for structure determination 
 ... ... Microscopy of surfaces, interfaces, and thin films, see 68.37.-d 
61.05.C- X-ray diffraction and scattering (for x-ray diffractometers, see 07.85.Jy; for x-ray studies of crystal defects, see 61.72.Dd, Ff)
61.05.cc Theories of x-ray diffraction and scattering 
61.05.cf X-ray scattering (including small-angle scattering) 
61.05.cj X-ray absorption spectroscopy: EXAFS, NEXAFS, XANES, etc. (for x-ray and EXAFS applications in biological physics, see 87.64.kd)
61.05.cm X-ray reflectometry (surfaces, interfaces, films) 
61.05.cp X-ray diffraction 
61.05.F- Neutron diffraction and scattering 
61.05.fd Theories of neutron diffraction and scattering 
61.05.fg Neutron scattering (including small-angle scattering) 
61.05.fj Neutron reflectometry 
61.05.fm Neutron diffraction 
 ... ... Microscopy of surfaces, interfaces, and thin films, see 68.37.-d 
61.05.J- Electron diffraction and scattering (for electron diffractometers, see 07.78.+s)
61.05.jd Theories of electron diffraction and scattering 
61.05.jh Low-energy electron diffraction (LEED) and reflection high-energy electron diffraction (RHEED) 
61.05.jm Convergent-beam electron diffraction, selected-area electron diffraction, nanodiffraction 
61.05.jp Electron holography 
61.05.js X-ray photoelectron diffraction 
61.05.Np Atom, molecule, and ion scattering (for structure determination only) 
61.05.Qr Magnetic resonance techniques; Mossbauer spectroscopy (for structure determination only) 
61.20.-p Structure of liquids 
61.20.Gy Theory and models of liquid structure 
61.20.Ja Computer simulation of liquid structure 
61.20.Lc Time-dependent properties; relaxation (for glass transitions, see 64.70.P-)
61.20.Ne Structure of simple liquids 
61.20.Qg Structure of associated liquids: electrolytes, molten salts, etc. 
61.25.-f Studies of specific liquid structures 
61.25.Bi Liquid noble gases 
61.25.Em Molecular liquids 
61.25.H- Macromolecular and polymers solutions; polymer melts 
61.25.he Polymer solutions 
61.25.hk Polymer melts and blends 
61.25.hp Polymer swelling, cross linking 
61.25.Mv Liquid metals and alloys 
61.30.-v Liquid crystals (for phase transitions in liquid crystals, see 64.70.M-; for liquid crystals as dielectric materials, see 77.84.Nh; for liquid crystals as optical materials, see 42.70.Df; for liquid crystal devices, see 42.79.Kr)
61.30.Cz Molecular and microscopic models and theories of liquid crystal structure 
61.30.Dk Continuum models and theories of liquid crystal structure 
61.30.Eb Experimental determinations of smectic, nematic, cholesteric, and other structures 
61.30.Gd Orientational order of liquid crystals; electric and magnetic field effects on order 
61.30.Hn Surface phenomena: alignment, anchoring, anchoring transitions, surface-induced layering, surface-induced ordering, wetting, prewetting transitions, and wetting transitions 
61.30.Jf Defects in liquid crystals 
61.30.Mp Blue phases and other defect-phases 
61.30.Pq Microconfined liquid crystals: droplets, cylinders, randomly confined liquid crystals, polymer dispersed liquid crystals, and porous systems 
61.30.St Lyotropic phases 
61.30.Vx Polymer liquid crystals 
61.41.+e Polymers, elastomers, and plastics (see also 81.05.Lg in materials science; for rheology of polymers, see section 83; for polymer reactions and polymerization, see 82.35.-x in physical chemistry and chemical physics)
61.43.-j Disordered solids (see also 81.05.Gc Amorphous semiconductors, 81.05.Kf Glasses, and 81.05.Rm Porous materials; granular materials in materials science; for photoluminescence of disordered solids, see 78.55.Mb and 78.55.Qr)
61.43.Bn Structural modeling: serial-addition models, computer simulation 
61.43.Dq Amorphous semiconductors, metals, and alloys 
61.43.Er Other amorphous solids 
61.43.Fs Glasses 
61.43.Gt Powders, porous materials 
61.43.Hv Fractals; macroscopic aggregates (including diffusion-limited aggregates) 
61.44.-n Semi-periodic solids 
61.44.Br Quasicrystals 
61.44.Fw Incommensurate crystals 
61.46.-w Structure of nanoscale materials (for thermal properties of nanocrystals and nanotubes, see 65.80.+n; for mechanical properties of nanoscale systems, see 62.25.-g; for electronic transport in nanoscale materials, see 73.63.-b; see also 62.23.-c Structural classes of nanoscale systems; 64.70.Nd Structural transitions in nanoscale materials)
61.46.Bc Structure of clusters (e.g., metcars; not fragments of crystals; free or loosely aggregated or loosely attached to a substrate) (see also 61.48.-c for structure of fullerenes)
61.46.Df Structure of nanocrystals and nanoparticles ("colloidal" quantum dots but not gate-isolated embedded quantum dots) 
61.46.Fg Nanotubes 
61.46.Hk Nanocrystals 
61.46.Km Structure of nanowires and nanorods (long, free or loosely attached, quantum wires and quantum rods, but not gate-isolated embedded quantum wires) 
61.46.Np Structure of nanotubes (hollow nanowires) (see 61.48.De for carbon nanotubes, boron nanotubes, and closely related graphitelike systems)
61.48.-c Structure of fullerenes and related hollow molecular clusters (see also 81.05.Tp Fullerenes and related materials in materials science)
61.48.De Structure of carbon nanotubes, boron nanotubes, and closely related graphitelike systems (for structure of hollow nanowires, see 61.46.Np)
61.50.-f Structure of bulk crystals 
61.50.Ah Theory of crystal structure, crystal symmetry; calculations and modeling 
 ... ... Crystal growth, see 81.10.-h 
61.50.Ks Crystallographic aspects of phase transformations; pressure effects (see also 81.30.Hd in materials science)
61.50.Lt Crystal binding; cohesive energy 
61.50.Nw Crystal stoichiometry 
61.66.-f Structure of specific crystalline solids (for surface structure, see 68.35.B-)
61.66.Bi Elemental solids 
61.66.Dk Alloys 
61.66.Fn Inorganic compounds 
61.66.Hq Organic compounds 
 ... ... Quantum crystals, see 67.80.-s 
61.68.+n Crystallographic databases 
61.72.-y Defects and impurities in crystals; microstructure (for radiation induced defects, see 61.80.-x; for defects in surfaces, interfaces, and thin films, see 68.35.Dv and 68.55.Ln; see also 85.40.Ry Impurity doping, diffusion, and ion implantation technology)
61.72.Bb Theories and models of crystal defects 
61.72.Cc Kinetics of defect formation and annealing 
61.72.Dd Experimental determination of defects by diffraction and scattering 
61.72.Ff Direct observation of dislocations and other defects (etch pits, decoration, electron microscopy, x-ray topography, etc.) 
61.72.Hh Indirect evidence of dislocations and other defects (resistivity, slip, creep, strains, internal friction, EPR, NMR, etc.) 
61.72.J- Point defects and defect clusters 
61.72.jd Vacancies 
61.72.jj Interstitials 
61.72.jn Color centers 
61.72.Lk Linear defects: dislocations, disclinations 
61.72.Mm Grain and twin boundaries 
61.72.Nn Stacking faults and other planar or extended defects 
61.72.Qq Microscopic defects (voids, inclusions, etc.) 
61.72.S- Impurities in crystals 
61.72.sd Impurity concentration 
61.72.sh Impurity distribution 
61.72.sm Impurity gradients 
61.72.U- Doping and impurity implantation 
61.72.uf Ge and Si 
61.72.uj III-V and II-VI semiconductors 
61.72.up Other materials 
61.72.Yx Interaction between different crystal defects; gettering effect 
61.80.-x Physical radiation effects, radiation damage (for photochemical reactions, see 82.50.-m; for effects of ionizing radiation on biological systems, see 87.53.-j)
 ... ... Radiation treatments, see 81.40.Wx 
61.80.Az Theory and models of radiation effects 
61.80.Ba Ultraviolet, visible, and infrared radiation effects (including laser radiation) 
61.80.Cb X-ray effects 
61.80.Ed gamma-ray effects 
61.80.Fe Electron and positron radiation effects 
61.80.Hg Neutron radiation effects 
61.80.Jh Ion radiation effects (for ion implantation, see 61.72.U-)
61.80.Lj Atom and molecule irradiation effects 
 ... ... Channeling, blocking, and energy loss of particles, see 61.85.+p 
61.82.-d Radiation effects on specific materials 
61.82.Bg Metals and alloys 
61.82.Fk Semiconductors 
61.82.Ms Insulators 
61.82.Pv Polymers, organic compounds 
61.82.Rx Nanocrystalline materials 
61.85.+p Channeling phenomena (blocking, energy loss, etc.) 
61.90.+d Other topics in structure of solids and liquids; crystallography (restricted to new topics in section 61) 
62.00.00 Mechanical and acoustical properties of condensed matter (for mechanical properties of tissues and organs, see 87.19.R-; for mechanical properties of nanoscale systems, see 62.25.-g; for nonlinear acoustics of solids, see 43.25.Dc-in Acoustics Appendix; for mechanical and acoustical properties of interfaces and thin films, see 68.35.Gy, 68.35.Iv, and 68.60.Bs; for mechanical properties related to treatment conditions, see 81.40.Jj, Lm, Np-in material science; for mechanical and acoustical properties of superconductors, see 74.25.Ld; for mechanical and acoustical properties of rocks and minerals, see 91.60.Ba, Dc, and Lj)
62.10.+s Mechanical properties of liquids (for viscosity of liquids, see 66.20.-d)
62.20.-x Mechanical properties of solids 
62.20.D- Elasticity (for materials treatment effects on elastic properties, see 81.40.Jj)
62.20.de Elastic moduli 
62.20.dj Poisson's ratio 
62.20.dq Other elastic constants 
62.20.F- Deformation and plasticity (see also 83.50.-v Deformation and flow in rheology; for materials treatment effects on deformation, see 81.40.Lm)
62.20.fg Shape-memory effect; yield stress; superelasticity 
62.20.fk Ductility, malleability 
62.20.fq Plasticity and superplasticity 
62.20.Hg Creep 
62.20.M- Structural failure of materials (for materials treatment effects on microstructure, see 81.40.Np)
62.20.me Fatigue 
62.20.mj Brittleness 
62.20.mm Fracture 
62.20.mq Buckling 
62.20.mt Cracks 
62.20.Qp Friction, tribology, and hardness (see also 46.55.+d Tribology and mechanical contacts in continuum mechanics of solids; for materials treatment effects on friction related properties, see 81.40.Pq)
62.23.-c Structural classes of nanoscale systems (see also 81.07.-b Nanoscale materials and structures: fabrication and characterization in materials science)
62.23.Eg Nanodots 
62.23.Hj Nanowires 
62.23.Kn Nanosheets 
62.23.Pq Composites (nanosystems embedded in a larger structure) 
62.23.St Complex nanostructures, including patterned or assembled structures 
62.25.-g Mechanical properties of nanoscale systems (for structure of nanoscale systems, see 61.46.-w; for structural transitions in nanoscale materials, see 64.70.Nd; for electronic transport in nanoscale systems, see 73.63.-b)
62.25.De Low-frequency properties: response coefficients 
62.25.Fg High-frequency properties, responses to resonant or transient (time-dependent) fields 
62.25.Jk Mechanical modes of vibration 
62.25.Mn Fracture/brittleness 
62.30.+d Mechanical and elastic waves; vibrations (see also 43.40.+s Structural acoustics and vibration; 46.40.-f Vibrations and mechanical waves in continuum mechanics of solids)
62.40.+i Anelasticity, internal friction, stress relaxation, and mechanical resonances (for materials treatment effects on anelasticity, see 81.40.Jj in materials science)
 ... ... Thermomechanical effects, see 65.40.De 
 ... ... Magnetomechanical effects, see 75.80.+q 
 ... ... Piezoelectric effects, see 77.65.-j 
 ... ... Elastooptical effects, see 78.20.Hp 
62.50.-p High-pressure effects in solids and liquids (for high pressure apparatus and techniques, see 07.35.+k; for high-pressure behavior of rocks and minerals, see 91.60.Gf; for pressure treatments, see 81.40.Vw in materials science)
62.50.Ef Shock wave effects in solids and liquids (for shock wave initiated high-pressure chemistry, see 82.40.Fp; see also 47.40.Nm Shock wave interactions and shock effects in fluid dynamics)
62.60.+v Acoustical properties of liquids (see also 43.35.+d in acoustics; 87.50.Y- Biological effects of acoustic and ultrasonic energy in biological and medical physics)
 ... ... Lattice dynamics, phonons, see section 63 
 ... ... Sound waves in fluid dynamics, see 47.35.Rs 
 ... ... Second sound in quantum fluids, see 67.25.dt 
62.65.+k Acoustical properties of solids 
 ... ... Magnetoacoustic effects, see 72.55.+s and 73.50.Rb 
 ... ... Acoustoelectric effects, see 72.50.+b, 73.50.Rb, and 77.65.Dq 
 ... ... Acoustooptical effects, see 78.20.Hp 
62.80.+f Ultrasonic relaxation (see also 43.35.Fj Ultrasonic relaxation processes in liquids and solids-in Acoustics Appendix; for ultrasonic attenuation in superconductors, see 74.25.Ld)
62.90.+k Other topics in mechanical and acoustical properties of condensed matter (restricted to new topics in section 62) 
63.00.00 Lattice dynamics (see also 78.30.-j Infrared and Raman spectra; for surface and interface vibrations, see 68.35.Ja; for adsorbate vibrations, see 68.43.Pq; for lattice dynamics of quantum solids, see 67.80.de)
63.10.+a General theory 
63.20.-e Phonons in crystal lattices (for phonons in superconductors, see 74.25.Kc; see also 43.35.Gk Phonons in crystal lattice, quantum acoustics-in Acoustics Appendix)
63.20.D- Phonon states and bands, normal modes, and phonon dispersion 
63.20.dd Measurements 
63.20.dh Fitted theory 
63.20.dk First-principles theory 
63.20.K- Phonon interactions 
63.20.kd Phonon-electron interactions 
63.20.kg Phonon-phonon interactions 
63.20.kk Phonon interactions with other quasiparticles 
63.20.kp Phonon-defect interactions 
63.20.Pw Localized modes 
63.20.Ry Anharmonic lattice modes 
63.22.-m Phonons or vibrational states in low-dimensional structures and nanoscale materials 
63.22.Dc Free films 
63.22.Gh Nanotubes and nanowires 
63.22.Kn Clusters and nanocrystals 
63.22.Np Layered systems 
63.50.-x Vibrational states in disordered systems 
63.50.Gh Disordered crystalline alloys 
63.50.Lm Glasses and amorphous solids 
63.70.+h Statistical mechanics of lattice vibrations and displacive phase transitions 
63.90.+t Other topics in lattice dynamics (restricted to new topics in section 63) 
64.00.00 Equations of state, phase equilibria, and phase transitions (see also 82.60.-s Chemical thermodynamics)
64.10.+h General theory of equations of state and phase equilibria (see also 05.70.Ce Thermodynamic functions and equations of state)
64.30.-t Equations of state of specific substances 
64.30.Ef Equations of state of pure metals and alloys 
64.30.Jk Equations of state of nonmetals 
64.60.-i General studies of phase transitions (see also 63.70.+h Statistical mechanics of lattice vibrations and displacive phase transitions; for critical phenomena in solid surfaces and interfaces, and in magnetism, see 68.35.Rh, and 75.40.-s, respectively)
64.60.A- Specific approaches applied to studies of phase transitions 
64.60.ae Renormalization-group theory 
64.60.ah Percolation 
64.60.al Fractal and multifractal systems (see also 61.43.Hv Fractals; macroscopic aggregates)
64.60.an Finite-size systems 
64.60.aq Networks 
64.60.at Convolution 
64.60.av Cracks, sandpiles, avalanches, and earthquakes (for general studies of sandpiles and avalanches, see 45.70.Cc, Ht in classical mechanics of discrete systems; see also 91.30.Px Earthquakes in geophysics)
64.60.Bd General theory of phase transitions 
64.60.Cn Order-disorder transformations (see also 81.30.Hd Constant-composition solid-solid phase transformations: polymorphic, massive, and order-disorder in materials science)
64.60.De Statistical mechanics of model systems (Ising model, Potts model, field-theory models, Monte Carlo techniques, etc) 
64.60.Ej Studies/theory of phase transitions of specific substances 
64.60.F- Equilibrium properties near critical points, critical exponents 
64.60.fd General theory of critical region behavior 
64.60.fh Studies of specific substances in the critical region 
 ... ... Properties of quantum fluids, see section 67 
64.60.Ht Dynamic critical phenomena 
64.60.Kw Multicritical points 
64.60.My Metastable phases 
64.60.Q- Nucleation (see also 82.60.Nh Thermodynamics of nucleation in physical chemistry and chemical physics)
64.60.qe General theory and computer simulations of nucleation 
64.60.qj Studies of nucleation in specific substances 
64.70.-p Specific phase transitions 
64.70.D- Solid-liquid transitions 
64.70.dg Crystallization of specific substances 
64.70.dj Melting of specific substances 
64.70.dm General theory of the solid-liquid transition 
64.70.F- Liquid-vapor transitions 
64.70.fh Boiling and bubble dynamics (for bubble formation, bubble dynamics, boiling and cavitation, see section 47.55.D-; for acoustic cavitation, see 43.35.Ei in Acoustics Appendix)
64.70.fm Thermodynamics studies of evaporation and condensation (for evaporation and condensation on surfaces, see 68.03.Fg)
64.70.Hz Solid-vapor transitions 
64.70.Ja Liquid-liquid transitions 
64.70.K- Solid-solid transitions (see also 61.50.Ks Crystallographic aspects of phase transformations; pressure effects; 75.30.Kz and 77.80.Bh for magnetic and ferroelectric transitions, respectively; for material science aspects, see 81.30.-t)
64.70.kd Metals and alloys 
64.70.kg Semiconductors 
64.70.kj Glasses 
64.70.km Polymers 
64.70.kp Ionic crystals 
64.70.kt Molecular crystals 
64.70.M- Transitions in liquid crystals 
64.70.mf Theory and modeling of specific liquid crystal transitions, including computer simulation 
64.70.mj Experimental studies of liquid crystal transitions 
64.70.Nd Structural transitions in nanoscale materials 
64.70.P- Glass transitions of specific systems 
64.70.pe Metallic glasses 
64.70.ph Nonmetallic glasses (silicates, oxides, selenides, etc) 
64.70.pj Polymers 
64.70.pm Liquids 
64.70.pp Liquid crystals (see also 64.70.M- Transitions in liquid crystals)
64.70.ps Granules 
64.70.pv Colloids 
64.70.Q- Theory and modeling of the glass transition 
64.70.qd Thermodynamics and statistical mechanics 
64.70.qj Dynamics and criticality 
64.70.Rh Commensurate-incommensurate transitions 
64.70.Tg Quantum phase transitions (for quantum Hall effects aspects, see 73.43.Nq in electronic structure of surfaces, interfaces, thin films, and low dimensional structures)
64.75.-g Phase equilibria (see also 82.60.Lf Thermodynamics of solutions; 47.51.+a Mixing in fluid dynamics; for properties of solutions of biomolecules, see 87.15.N- in biological physics)
64.75.Bc Solubility 
64.75.Cd Phase equilibria of fluid mixtures, including gases, hydrates, etc. 
64.75.Ef Mixing 
64.75.Gh Phase separation and segregation in model systems (hard spheres, Lennard-Jones, etc.) 
64.75.Jk Phase separation and segregation in nanoscale systems (for general nanoscale materials studies, see 81.07.-b in materials science)
64.75.Lm Phase separation and segregation in oxidation (for general surface oxidation studies in surface treatments, see 81.65.Mq)
64.75.Nx Phase separation and segregation in solid solutions 
64.75.Op Phase separation and segregation in alloying 
64.75.Qr Phase separation and segregation in semiconductors 
64.75.St Phase separation and segregation in thin films 
64.75.Va Phase separation and segregation in polymer blends/polymeric solutions 
64.75.Xc Phase separation and segregation in colloidal systems 
64.75.Yz Self-assembly 
64.90.+b Other topics in equations of state, phase equilibria, and phase transitions (restricted to new topics in section 64) 
65.00.00 Thermal properties of condensed matter (see also section 44 Heat transfer; for thermodynamic properties of quantum fluids and solids, see section 67; for thermal properties of thin films, see 68.60.Dv; for nonelectronic thermal conduction, see 66.25.+g and 66.70.-f; for thermal properties of rocks and minerals, see 91.60.Ki; for thermodynamic properties of superconductors, see 74.25.Bt; see also 87.19.Pp Biothermics and thermal processes in biological physics)
65.20.-w Thermal properties of liquids 
65.20.De General theory of thermodynamic properties of liquids, including computer simulation 
65.20.Jk Studies of thermodynamic properties of specific liquids 
65.40.-b Thermal properties of crystalline solids (for specific heat of superconductors, see 74.25.Bt; for specific heat of magnetic systems, see 75.40.Cx)
65.40.Ba Heat capacity 
65.40.De Thermal expansion; thermomechanical effects 
65.40.G- Other thermodynamical quantities (for magnetocaloric effect, see 75.30.Sg; for properties of dielectrics, ferroelectrics, and piezoelectrics, see section 77)
65.40.gd Entropy 
65.40.gh Work functions 
65.40.gk Electrochemical properties (for general electrochemistry, see 82.45.-h)
65.40.gp Surface energy (see also