American Institute of Physics
SEARCH AIP
home contact us sitemap
Physics News Update
Number 666, December 18, 2003 by Phillip F. Schewe, Ben Stein, and James Riordon

Bringing the Nucleon into Sharper Focus

Working at the Thomas Jefferson National Accelerator Facility in Virginia, a multinational research team has determined how quarks in a proton orient their "spins," which, roughly speaking, can be visualized as tiny bar magnets that point in a certain direction and have a certain strength. Information about a quark's spin can provide new details of how the tiny particles arrange themselves inside a nucleon (proton or neutron).

In high-school physics classes, students are taught that a proton or neutron simply consists of three quarks, which specialists call "valence quarks." A more complete picture includes these three valence quarks, plus a sea of quark-antiquark pairs that pop in and out of empty space (the vacuum), as well as particles called gluons which hold the quarks together.

Now, for the first time, researchers have precisely measured the distribution of spin for a neutron's valence quarks. Strikingly, their results reveal the importance of once-neglected orbital motions of quarks inside the nucleon.

Aiming an electron beam at a helium-3 target in JLab's Hall A, researchers (led by Jian-Ping Chen, jpchen@jlab.org and Zein-Eddine Meziani, meziani@temple.edu) selected a 5.7 GeV beam energy so that the electrons interacted mainly with the neutron's valence quarks and not its sea quarks and gluons.

Interestingly, the researchers applied their new neutron data, along with existing proton data, to find out more about the proton. Their conclusions: the spins of the proton's two valence up quarks are aligned parallel to the overall proton spin, but the same is not true for the proton's valence down quark (see image).

This result disagrees with predictions from an approximation of perturbative quantum chromodynamics (pQCD), a widely accepted theory of the strong force (which holds the nucleon together). This approximation does not account for the quarks' orbital angular momenta, which describes the orbital paths of quarks inside the nucleon.

However, the results agree well with predictions from a relativistic valence quark model, which does consider quarks' orbital angular momenta as they move inside the nucleon. (Zheng et al., Physical Review Letters, upcoming article; for more information, contact Xiaochao Zheng, Argonne, 630-252-3431, xiaochao@jlab.org)

Once omitted in simpler pictures of the nucleon, quark orbital angular momentum is also proving important for exploring questions about the shape of the proton (see for example New Scientist, May 3, 2003.)

A True One-Dimensional Atomic System

A true one-dimensional atomic system, consisting of a Bose Einstein condensate (BEC) of rubidium atoms pulled out into a thin tubelike shape, has been experimentally demonstrated for the first time, in the ETH lab in Zurich.

The ETH researchers begin by loading their condensate into an optical lattice, an artificial configuration in which atoms are held and moved about in 3D space by criss-crossing beams of laser light. In contrast to previous efforts to make one-dimensional BECs, this experiment succeeded in extruding a condensate into 1000 small needle-like condensates---one dimensional strings of 100 atoms or so and not merely cigar shaped lozenges---because they used a far more intense laser trapping field and higher quality laser beams (more truly Gaussian in their profile), the better to keep atoms from tunneling from one needle into a neighboring needle (see figure).

Once the ETH physicists had established their one-dimensional atomic gas what did they do with it? They set their lean stack of atoms into motion by slightly moving the magnetic center of their apparatus. This caused the atoms to move up and down in a "breathing mode"at a characteristic frequency. Studying this oscillation was analogous to listening a one dimensional bell ringing.

How unusual is the ETH 1D condensate? Well, even two dimensional atomic systems are rare in physics: helium films and hydrogen atoms sitting atop helium are the prominent examples. The only other 1D gas studied in physics consists of electrons moving in "quantum wires."

One-dimensional systems are interesting because they are more intrinsically dominated by quantum effects than 2- or
3-dimensional systems. According to Tilman Esslinger (tilman.esslinger@iqe.phys.ethz.ch, http://www.quantumoptics.ethz.ch/) 1D ensembles of atoms should play an important role wherever precision handling of atoms is needed: in atom optics, atom interferometry, or sending signals from atom lasers down an atom waveguide. (Moritz et al., Physical Review Letters, 19 December 2003.)