Raymond A. Shaw
Affiliations: | Physics | Michigan Technological University, USA |
Area:
atmospheric physics, turbulence, cloud physics, nucleation, holographyWebsite:
https://www.mtu.edu/physics/department/faculty/shaw/Google:
"Raymond Arthur Shaw" OR "Raymond A. Shaw"Bio:
https://www.proquest.com/openview/724e7dde8069943f41d27fc8f1878b2a/1
Cross-listing: Physics Tree
Parents
Sign in to add mentor| Dennis Lamb | grad student | 1998 | Penn State (Physics Tree) | |
| (Laboratory and theoretical studies of ice production in clouds) | ||||
Children
Sign in to add trainee| Michael C. Adler | research assistant | 2014 | Michigan Technological University (E-Tree) |
| Jacob P. Fugal | grad student | 2007 | Michigan Technological University (Physics Tree) |
| Ewe W. Saw | grad student | 2008 | Michigan Technological University (Physics Tree) |
| Matthew J. Beals | grad student | 2013 | Michigan Technological University |
| Colin Gurganus | grad student | 2014 | Michigan Technological University (Physics Tree) |
| Fan Yang | grad student | 2012-2017 | Michigan Technological University |
| Neel Uday Desai | grad student | 2013-2018 | Michigan Technological University |
| Corey Packard | grad student | 2013-2019 | Michigan Technological University |
| Kamal Kant Chandrakar | grad student | 2014-2019 | Michigan Technological University |
| Subin Thomas | grad student | 2016-2021 | Michigan Technological University (Physics Tree) |
BETA: Related publications
See more...
Publications
|
You can help our author matching system! If you notice any publications incorrectly attributed to this author, please sign in and mark matches as correct or incorrect. |
| Allwayin N, Larsen ML, Glienke S, et al. (2024) Locally narrow droplet size distributions are ubiquitous in stratocumulus clouds. Science (New York, N.Y.). 384: 528-532 |
| Feingold G, Ghate VP, Russell LM, et al. (2024) Physical science research needed to evaluate the viability and risks of marine cloud brightening. Science Advances. 10: eadi8594 |
| Yeom JM, Helman I, Prabhakaran P, et al. (2023) Cloud microphysical response to entrainment and mixing is locally inhomogeneous and globally homogeneous: Evidence from the lab. Proceedings of the National Academy of Sciences of the United States of America. 120: e2307354120 |
| Prabhakaran P, Shawon ASM, Kinney G, et al. (2020) The role of turbulent fluctuations in aerosol activation and cloud formation. Proceedings of the National Academy of Sciences of the United States of America |
| Niedermeier D, Voigtländer J, Schmalfuß S, et al. (2020) Characterization and first results from LACIS-T: a moist-air wind tunnel to study aerosol–cloud–turbulence interactions Atmospheric Measurement Techniques. 13: 2015-2033 |
| Packard CD, Larsen ML, Thomas S, et al. (2020) Light Scattering in a Turbulent Cloud: Simulations to Explore Cloud-Chamber Experiments Atmosphere. 11: 837 |
| Glienke S, Kostinski AB, Shaw RA, et al. (2020) Holographic Observations of Centimeter-Scale Nonuniformities within Marine Stratocumulus Clouds Journal of the Atmospheric Sciences. 77: 499-512 |
| Siebert H, Szodry K, Egerer U, et al. (2020) Observations of aerosol, cloud, turbulence, and radiation properties at the top of the marine boundary layer over the Eastern North Atlantic Ocean: The ACORES campaign Bulletin of the American Meteorological Society. 1-59 |
| Prabhakaran P, Kinney G, Cantrell W, et al. (2020) High Supersaturation in the Wake of Falling Hydrometeors: Implications for Cloud Invigoration and Ice Nucleation Geophysical Research Letters. 47 |
| Albrecht B, Ghate V, Mohrmann J, et al. (2019) Cloud System Evolution in the Trades-CSET: Following the Evolution of Boundary Layer Cloud Systems with the NSF/NCAR GV. Bulletin of the American Meteorological Society. 100: 93-121 |