|
|
Thirty years ago the determination of a protein structure required years of effort and typically was sufficient for a Ph.D. thesis. Today, due to advances in synchrotron X-ray sources and detectors, protein crystal structures can be calculated in just hours.
This has enabled "many types of studies that were previously inconceivable," says Sol Gruner, a Cornell physics professor and an expert in designing and building fast, large-area X-ray imaging detectors. He says that high-powered synchrotron X-ray sources
and advanced detectors have been largely responsible for the progress in calculating protein structures. "The biotechnological revolution of the last two decades is built upon the twin pillars of protein structure determination and genetic engineering," Gruner says. Indeed, he says, "Synchrotron X-radiation has become an enormously powerful tool throughout science and technology."
Gruner, who is director of the Cornell High Energy Synchrotron Source (CHESS), presented an overview of these advances Feb. 16, in a talk, "Future X-ray Sources and Detector Technologies," at the AAAS meeting in Seattle. His talk was part of a symposium, "Synchrotron Radiation as a Frontier Multidisciplinary Scientific Tool," organized by Ernest Fontes, assistant director of CHESS, Doon Gibbs of Brookhaven National Laboratory and Keith Hodgson of Stanford University/Stanford Linear Accelerator Center. Synchrotron radiation is emitted when highly energetic electrons are deflected by magnetic fields. All existing synchrotron X-ray facilities are based on a technology called the storage ring. In such a ring, bunches of electrons are kept in a roughly circular orbit by magnetic deflecting and focusing structures. At Cornell, the National Science Foundation (NSF)-supported Cornell Electron Storage Ring (CESR) is the X-ray source for CHESS.
Usage of synchrotron radiation has grown steadily over the past three decades as synchrotron sources, X-ray optics and detector technology have steadily advanced. Gruner explained how novel technologies now being developed will couple with developing semiconductor X-ray detectors to open new avenues of scientific exploration.
One such new technology, which promises to remove many of the present limitations of existing storage ring X-ray sources, is based on the use of a superconducting linear accelerator (or linac) to continuously accelerate and recover the energy from an electron beam. This device, called an Energy Recovery Linac (ERL), will be able to produce X-ray beams of unprecedented brilliance and small size. Gruner is the principal investigator on a proposal to the NSF to build an ERL prototype, based on collaborative designs between Cornell and the Thomas Jefferson National Accelerator Facility in Newport News, Va.
| Cornell Chronicle Front Page | | Table of Contents | | Cornell News Service Home Page |