Charles Payne
- Name
- Mr. Charles Payne
- Institution
- Idaho National Laboratory
- Position
- Nuclear Instrumentation Engineer
- h-Index
- ORCID
- 0009-0007-6146-1395
- Biography
Charles Payne is a member of the Measurement Sciences laboratory at Idaho National Lab. At MSL Charles supports optical fiber based instrumentation development for nuclear energy related applications. His primary area of research is in optical and laser-based measurement development for extreme environments and fundamental optical physics research. Charles has build and developed optical instruments/experiments for a variety of different applications varying from laser pulse compressors for nonlinear optical physics research to multiplexed optical fiber-based velocimetry systems for shock physics tests and experiments. His research interests are,
- Optical instrumentation
- Optical physics/engineering
- Metrology
- Experiment/Test design
- Data science
- Extreme environments- Expertise
- Extreme Environments, Fiber Optics, Instrumentation, Metrology
| "Electric field-assisted embedding of fiber optic sensors in structural materials for structural health monitoring" Joshua Daw, Charles Payne, Bibo Zhong, Austin Fleming, Zilong Hua, Jorgen Rufner, Xinchang Zhang, [2025] Journal of Materials Research and Technology · DOI: 10.1016/j.jmrt.2024.12.050 | |
| "Development of Accelerated High Temperature Mechanical Testing Techniques" Charles Payne, Michael McMurtrey, Ninad Mohale, [2024] · DOI: 10.2172/2448228 | |
| "Small Windowed PDV Slab Shot Verification" Steve Gilbertson, Kimberly Schultz, Charles Payne, [2022] Los Alamos National Laboratory · DOI: 10.2172/1888177 | |
| "Fourth Generation MPDV and MBR at DARHT" Charles Payne, Daniel Kalb, Kimberly Schultz, Steve Gilbertson, [2022] Los Alamos National Laboratory · DOI: 10.2172/1874137 | |
| "Optical communication in maritime environments using orbital angular momentum" [2020] Ocean Sensing and Monitoring XII · DOI: 10.1117/12.2560262 | |
|
"Stellar Midlife Crises: Challenges and Advances in Simulating Convection and Differential Rotation in Sun-like Stars"
Charles Payne, Cameron Michael Sorensen, Nicholas J. Nelson,
[2016]
Proceedings of the International Astronomical Union
· DOI: 10.1017/s1743921317004422
· ISSN: 1743-9213
Low mass, main sequence stars like our Sun exhibit a wide variety of rotational and magnetic states. Observational and theoretical advances have led to a renewed emphasis on understanding the rotational and magnetic evolution of sun-like stars has become a pressing problem in stellar physics. We use global 3D convection and convective dynamo simulations in rotating spherical shells and with realistic stellar stratification to explore the behavior of “middle-aged” stars. We show that for stars with slightly less rotational influence than our Sun a transition occurs from solar-like (fast equator, slow poles) to anti-solar (slow equator, fast poles) differential rotation. We investigate this transition using two different treatments for the upper boundary of our simulations and we hypothesize that this transition from solar-like to anti-solar differential rotation may be responsible for observations of anomalously rapid rotation for stars older than our Sun. |
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| Source: ORCID/CrossRef using DOI | |
About Us
The Nuclear Science User Facilities (NSUF) is the U.S. Department of Energy Office of Nuclear Energy's only designated nuclear energy user facility. Through peer-reviewed proposal processes, the NSUF provides researchers access to neutron, ion, and gamma irradiations, post-irradiation examination and beamline capabilities at Idaho National Laboratory and a diverse mix of university, national laboratory and industry partner institutions.
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