A once dark region of the electromagnetic spectrum is now becoming very bright. The soft‐x‐ray spectral region, nominally extending from wavelengths of several angstroms to several hundred angstroms and including photon energies from tens of electron volts to several thousand electron volts, is providing many new research and development opportunities in the physical and life sciences and in industry. The move toward shorter wavelengths is driven in part by the desire to see and write smaller features. But the numerous and distinct atomic resonances in this region of the spectrum also provide for elemental identification and, in some cases, chemical sensitivity. (See the article by Bernd Crasemann and Francois Wuilleumier in PHYSICS TODAY, June 1984, page 34.) Developments in x‐ray optics and new sources of highbrightness, partially coherent radiation make it possible to study materials and biological samples with feature sizes of several hundred angstroms.
Skip Nav Destination
Article navigation
August 1992
August 01 1992
New Opportunities at Soft‐X‐Ray Wavelengths
Advances in synchrotron radiation, x‐ray lasers and x‐ray optics permit new studies in the life and physical sciences at spatial resolutions of hundreds of angstroms.
David Attwood
David Attwood
College of Engineering, University of California, Berkeley
Search for other works by this author on:
Physics Today 45 (8), 24–31 (1992);
Citation
David Attwood; New Opportunities at Soft‐X‐Ray Wavelengths. Physics Today 1 August 1992; 45 (8): 24–31. https://doi.org/10.1063/1.881314
Download citation file:
PERSONAL SUBSCRIPTION
Purchase an annual subscription for $25. A subscription grants you access to all of Physics Today's current and backfile content.
Sign In
You could not be signed in. Please check your credentials and make sure you have an active account and try again.
Citing articles via
Going with the flow in unstable surroundings
Savannah D. Gowen; Thomas E. Videbæk; Sidney R. Nagel
Measuring violin resonances
Elizabeth M. Wood
Focus on cryogenics, vacuum equipment, materials, and semiconductors
Andreas Mandelis