Thermal and Kinematic Constraints in High-Energy Nuclear Transitions and Their Applications in Gamma Lasers
DOI:
https://doi.org/10.65405/nmd10w29Keywords:
Recoil energy, recoil velocity, isomeric nuclei, nuclear transition energy, resonance photon, Mössbauer effect, MATLABAbstract
Nuclear recoil plays a fundamental role in determining the feasibility of resonant gamma-ray processes and the potential realization of gamma-ray lasers. In this study, the recoil energy, recoil velocity, and associated thermal constraints of gamma transitions were quantitatively investigated for a set of selected isomeric nuclei with mass numbers ranging from Ba-133 to Os-189. Nuclear transition energies were obtained from internationally recognized nuclear data libraries, including the National Nuclear Data Center (NNDC) and the Evaluated Nuclear Structure Data File (ENSDF). Using theoretical relations derived from momentum conservation, recoil parameters were calculated and analyzed numerically using MATLAB. The results show that recoil energy increases quadratically with transition energy while decreasing with increasing nuclear mass. Consequently, nuclei with high-energy transitions exhibit significantly larger recoil energies and recoil velocities. The calculations also reveal an energy mismatch between emitted and absorbed photons caused by nuclear recoil, which disrupts the resonance condition required for efficient stimulated gamma emission. Order-of-magnitude analysis further indicates that recoil energy is typically several orders of magnitude larger than the natural linewidth of nuclear transitions, making resonant absorption in free nuclei extremely unlikely. These findings highlight the fundamental kinematic and thermal limitations imposed by nuclear recoil and emphasize the importance of recoil-suppression mechanisms, such as lattice confinement, for achieving precise nuclear resonance and advancing gamma-ray laser research.
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