Weizmann Institute accelerators have been long used to explore the properties of atomic nuclei, but now they also contribute to the solution of a variety of medical, ecological, and other problems. Many of these projects are directed by investigators from other research institutions.
Prof. Michael Paul of the Hebrew University, for example, utilizes the Koffler Accelerator of the Canada Centre of Nuclear Physics as an extremely sensitive mass spectrometer in order to follow the movement of man-made isotope calcium - 41 in the body. His investigations promote an understanding of the bone-weakening disease, osteoporosis. Paul and colleagues are also tracing the environmental impact of nuclear energy exploitation by determining variations in radioisotope iodine-129 (a by-product of modern nuclear fission reactors) in ice cores from Greenland. Another group, including Dr. Yeshayahu Lifshitz of Israel's Nahal Soreq Nuclear Research Center and Prof. Michael Hass of the Institute's Nuclear Physics Department, uses the Pelletron to simulate the radiation of outer space. This enables study of the reliability of electronic chips used in satellites.
Prof. Jacob Klein and his group of the Institute's Department of Materials and Interfaces are working on the 3 MV Van de Graaff accelerator. Their investigation of nuclear reactions in polymers sheds light on how the chemical structure and size of individual polymer molecules provide information on the physics of polymeric materials, including their stability, thin-film structure, and transport properties.
The Institute's third accelerator, the EN Tandem, is used by a Tel Aviv University group to develop Israel's first free-electron laser (FEL), the most powerful type of laser known to science. FELs may eventually be a key component in the production of environmentally clean energy via magnetic confinement nuclear fusion.
Fundamental research continues at the Pelletron Accelerator. Profs. Cyril Broude and Michael Hass of the Nuclear Physics Department are probing the shapes, magnetism, and other properties of nuclei. These determinations help provide a better understanding of the forces operating between their component protons and neutrons. Another group, headed by Professors Zeev Vager (Nuclear Physics Department) and Ron Naaman (Chemical Physics Department), is applying its own novel method, involving both lasers and Coulomb explosion imaging, to determine the structure of molecular species, work important for verifying theoretical models of molecular structure.
Prof. Klein holds the Herman F. Mark Chair of Polymer Physics; Prof. Naaman, the Aryeh and Mintzi Katzman Chair; and Prof. Vager, the Isidor I. Rabi Chair of Physics.
New Method for 'Improving' Light Signals
Light signals used in optical communications and computing carry minute bits of information, detected by measuring the number of photons (elementary packets of light energy) they contain. Such measurements, however, are imprecise because light signals originating even from the best lasers are inevitably distorted by "noise" due to random fluctuations in the number of photons produced. The Weizmann Institute and Imperial College researchers have suggested new strategies to reduce such "noise."
They propose the coupling of laser light output to a special storage cavity exposed to a beam of atomic particles that interacts with the light. The idea is to select those atoms that are unchanged by the cavity, which implies that the light trapped inside has a fixed number of photons, and is therefore free of "noise."
One technique involves passage of the atoms in close proximity to tiny plastic or glass spheres on which surface photons are trapped. Another possibility is the passage of atoms through a regularly spaced array of such spheres, which enables atoms to emit light in a single direction only. The new schemes are expected to be tested experimentally in the near future.