New Formulation of Nuclear Recoil and Mass Polarization in Collisional Line Broadening of Magnetized and Non-Magnetized Plasmas
Abstract
1. Introduction
2. Mass Polarization
3. Mass Polarization in Scattering
4. An Alternate Coordinate System: The Relative-Motion Representation
4.1. Exchange
4.2. Exchange Matrix Elements
4.3. Numerical Example
5. Impact on Spectral Line Broadening
5.1. How Unitary Transformations Affect Spectral Line Broadening
5.2. How Atomic Deflection Changes Line Broadening
5.3. The -Ion Model for Line-Shape Simulations
6. Atomic Motion in Collisions with Particles in High Magnetic Field
6.1. Neutral Radiator
6.2. Charged Radiator
7. Conclusions
Author Contributions
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
Appendix A. Evaluation of Shifted Coulomb Interactions
Appendix B. Different Methods for Capturing Doppler Shifts from Collisions
Appendix B.1. Direct Evaluation of the Momentum Operator
Appendix B.2. Modifying the Green Function
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Gomez, T.A.; Zammit, M.C.; White, J. New Formulation of Nuclear Recoil and Mass Polarization in Collisional Line Broadening of Magnetized and Non-Magnetized Plasmas. Atoms 2026, 14, 53. https://doi.org/10.3390/atoms14070053
Gomez TA, Zammit MC, White J. New Formulation of Nuclear Recoil and Mass Polarization in Collisional Line Broadening of Magnetized and Non-Magnetized Plasmas. Atoms. 2026; 14(7):53. https://doi.org/10.3390/atoms14070053
Chicago/Turabian StyleGomez, Thomas A., Mark C. Zammit, and Jackson White. 2026. "New Formulation of Nuclear Recoil and Mass Polarization in Collisional Line Broadening of Magnetized and Non-Magnetized Plasmas" Atoms 14, no. 7: 53. https://doi.org/10.3390/atoms14070053
APA StyleGomez, T. A., Zammit, M. C., & White, J. (2026). New Formulation of Nuclear Recoil and Mass Polarization in Collisional Line Broadening of Magnetized and Non-Magnetized Plasmas. Atoms, 14(7), 53. https://doi.org/10.3390/atoms14070053

