Abstract
This article reviews conceptual devices designed to generate coherent high-quantum-energy radiation by stimulating nuclear transitions in solids; and delineates some of the promising areas of research. Solid state γ-ray lasers can benefit from (1) Mossbauer effect or recoilless emission, which suppresses first-order Doppler broadening, and brings the emitting nuclei close to a common resonant frequency; and (2) Borrmann effect, which suppresses non-resonant scattering and absorption, and may allow a crystal lattice to act as a distributed resonator. I discuss some of the basic physics that governs the performance of conceptual γ-ray lasers, and some of the classic approaches to design. Many of these early schemes were shown to be unworkable decades ago, but re-emerge in different forms generally without attention to the fallacies already revealed. Other schemes have languished for lack of a champion. I also describe some exciting new approaches, particularly those utilizing techniques for suppressing resonant absorption, which can realize gain without a true inversion. Finally, I submit some recommendations for future research.
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