- Home
- Search Results
- Page 1 of 1
Search for: All records
-
Total Resources3
- Resource Type
-
00030
- Availability
-
30
- Author / Contributor
- Filter by Author / Creator
-
-
Lee, Taehyoung (3)
-
DeMott, Paul J. (2)
-
Jimenez, Jose L. (2)
-
Nault, Benjamin A. (2)
-
Park, Taehyun (2)
-
Abbatt, Jonathan (1)
-
Anderson, Bruce E. (1)
-
Ault, Andrew P. (1)
-
Axson, Jessica L. (1)
-
Bertram, Allan K. (1)
-
Bertram, Timothy H. (1)
-
Beyersdorf, Andreas J. (1)
-
Bourgeois, Ilann (1)
-
Campuzano-Jost, Pedro (1)
-
Campuzano‐Jost, Pedro (1)
-
Canagaratna, Manjula R. (1)
-
Collins, Douglas B. (1)
-
Croteau, Philip (1)
-
Day, Douglas A. (1)
-
Deane, Grant B. (1)
-
- Filter by Editor
-
-
& Spizer, S. M. (0)
-
& . Spizer, S. (0)
-
& Ahn, J. (0)
-
& Bateiha, S. (0)
-
& Bosch, N. (0)
-
& Brennan K. (0)
-
& Brennan, K. (0)
-
& Chen, B. (0)
-
& Chen, Bodong (0)
-
& Drown, S. (0)
-
& Ferretti, F. (0)
-
& Higgins, A. (0)
-
& J. Peters (0)
-
& Kali, Y. (0)
-
& Ruiz-Arias, P.M. (0)
-
& S. Spitzer (0)
-
& Spitzer, S. (0)
-
& Spitzer, S.M. (0)
-
(submitted - in Review for IEEE ICASSP-2024) (0)
-
- (0)
-
-
Have feedback or suggestions for a way to improve these results?
!
Note: When clicking on a Digital Object Identifier (DOI) number, you will be taken to an external site maintained by the publisher.
Some full text articles may not yet be available without a charge during the embargo (administrative interval).
What is a DOI Number?
Some links on this page may take you to non-federal websites. Their policies may differ from this site.
-
DeMott, Paul J. ; Hill, Thomas C. ; McCluskey, Christina S. ; Prather, Kimberly A. ; Collins, Douglas B. ; Sullivan, Ryan C. ; Ruppel, Matthew J. ; Mason, Ryan H. ; Irish, Victoria E. ; Lee, Taehyoung ; et al ( , Proceedings of the National Academy of Sciences)
-
Nair, Arshad Arjunan ; Yu, Fangqun ; Campuzano‐Jost, Pedro ; DeMott, Paul J. ; Levin, Ezra J. T. ; Jimenez, Jose L. ; Peischl, Jeff ; Pollack, Ilana B. ; Fredrickson, Carley D. ; Beyersdorf, Andreas J. ; et al ( , Geophysical Research Letters)more » « less
Abstract Cloud condensation nuclei (CCN) are mediators of aerosol‐cloud interactions, which contribute to the largest uncertainty in climate change prediction. Here, we present a machine learning (ML)/artificial intelligence (AI) model that quantifies CCN from model‐simulated aerosol composition, atmospheric trace gas, and meteorological variables. Comprehensive multi‐campaign airborne measurements, covering varied physicochemical regimes in the troposphere, confirm the validity of and help probe the inner workings of this ML model: revealing for the first time that different ranges of atmospheric aerosol composition and mass correspond to distinct aerosol number size distributions. ML extracts this information, important for accurate quantification of CCN, additionally from both chemistry and meteorology. This can provide a physicochemically explainable, computationally efficient, robust ML pathway in global climate models that only resolve aerosol composition; potentially mitigating the uncertainty of effective radiative forcing due to aerosol‐cloud interactions (ERFaci) and improving confidence in assessment of anthropogenic contributions and climate change projections.
