E. Spiller, COHERENCE EFFECTS FROM VISIBLE-LIGHT TO X-RAYS, Nuclear instruments & methods in physics research. Section A, Accelerators, spectrometers, detectors and associated equipment, 347(1-3), 1994, pp. 161-169
The development of the concept of coherence of light and its applicati
on for experiments in the XUV range are reviewed. Coherence was origin
ally defined by the visibility of interference fringes, and the main e
ffort of early work was to produce coherency from non-coherent, chaoti
c or thermal sources. With the invention of the laser, fully coherent
light became available, leading to further clarification of the cohere
nce concept. The laser offered the first possibility to observe easily
interference effects between different, independent light sources. By
providing many photons in a single mode, non-linear effects, such as
the generation of higher harmonics or sum and difference frequencies b
ecame possible. The generation of non-classical fields, i.e. fields wh
ich are only allowed by quantum theory but have no analogue in classic
al physics, is a more recent development. Synchrotron sources in the X
UV region are now reaching the brightness which visible light had at t
he beginning of the sixties and the first soft X-ray lasers are availa
ble. Brightness is now sufficient to prepare spatially coherent X-ray
beam with sufficient intensity for holography or the observation of co
herency effects in the fluctuations of the light intensity. Non-linear
effects might become observable by mixing synchrotron radiation with
laser light.