HelioWebArthur J. Sedlacek
flowchart
A[Arthur J. Sedlacek]
AC["Associated Concepts (23)"]
AW["Authored Works (11)"]
CA["Linked Co-Authors (32)"]
CI["Linked Collaborating Institutions (28)"]
A== dcterms:relation ==>AC
AW== author ==>A
AW== author ==>CA
AW== affil ==>CI
click AC "#associated-concepts"
click AW "#authored-works"
click CA "#co-authors"
click CI "#collaborating-institutions"
NI["add incoming edge"]
NO["add outgoing edge"]
NI-- ? -->A
A-- ? -->NO
click NI "#add-incoming-edge"
click NO "#add-outgoing-edge"
style NI stroke-width:2px,stroke-dasharray: 5 5
style NO stroke-width:2px,stroke-dasharray: 5 5
- ORCiD
- https://orcid.org/0000-0001-9595-3653
- OpenAlex ID
- https://openalex.org/A5016971763 (API record)
Associated Concepts [?]
- Physics
- Geography
- Chemistry
- Organic chemistry
- Geology
- Environmental science
- Meteorology
- Aerosol
- Biology
- Ecology
- Materials science
- Optics
- Oceanography
- Atmospheric sciences
- Quantum mechanics
- Engineering
- Computer science
- Composite material
- Thermodynamics
- Remote sensing
- Particle (ecology)
- Mathematics
- Environmental chemistry
Authored Works
sorted by decreasing year, and then by display-name
- The Activation Properties of Fresh and Aged Black Carbon Particles from Biomass Burning
- Near Infrared-absorbing, Non-Black Carbon Particulate Material from Biomass Burning
- Measurements of Non-refractory Submicron Aerosol Composition and Other Aerosol Properties at a High-Altitude Site in Colorado River Basin
- Light absorption by brown carbon over the South-East Atlantic Ocean
- Fine ash-bearing particles as a major aerosol component in biomass burning smoke
- Chemistry of nonrefractory submicron aerosol in urban industrialized Texas: first results from TRACER
- Annual Variability of Particle Size, Cloud Condensation Nuclei, and Particle Hygroscopicity in the Central Arctic
- Trends in the CCN Activation of Coated Black Carbon Particles
- Multi-campaign analysis of smoke properties and cloud interactions in the Southeast Atlantic using ORACLES, LASIC, and CLARIFY data with WRF-CAM5
- Condensational Growth Model of Black Carbon Particles to Infer Black Carbon Particle Mixing State
- Black Carbon Particle Mixing State Analysis Allows Characterization of Biomass Burn Aerosol Lifecycle
Linked Co-Authors
- A. J. Soja
- Athanasios Nenes
- Calvin Howes
- Ernie R. Lewis
- Haochi Che
- Hugh Coe
- J. H. Crawford
- J. P. Schwarz
- Jack E. Dibb
- Jeffrey R. Pierce
- Jens Redemann
- Jessie M. Creamean
- Johnathan Hair
- Kenneth L Thornhill
- Kouji Adachi
- L. Ruby Leung
- Lawrence I. Kleinman
- Lu Zhang
- M. A. Fenn
- M. M. Frey
- Maria A. Zawadowicz
- Matthew D. Shupe
- Michael P. Jensen
- Mizuo Kajino
- O. L. Mayol-Bracero
- Ogochukwu Enekwizu
- Paquita Zuidema
- R. A. Ferrare
- Robert Wood
- S. P. Burton
- T. B. Onasch
- X. Gong
Linked Collaborating Institutions
- Aerodyne Research Inc., Massachusetts
- Arizona State University
- British Antarctic Survey
- Brookhaven National Laboratory, New York
- Colgate University, New York
- Colorado State University
- Dalhousie University, Canada
- Ecole Polytechnique Federale de Lausanne
- JMA, Meteorological Research Institute, Tsukuba
- Japan Marine Science and Technology Center
- Mount Allison University, Canada
- NASA Langley Research Center
- Northeastern University, Massachusetts
- Pacific Northwest National Laboratory
- Science Systems and Applications Inc., Maryland
- Tel Aviv University, Israel
- University of California, Los Angeles
- University of California, Riverside
- University of Colorado, Boulder
- University of Hawaii, Manoa
- University of Illinois, Urbana-Champaign
- University of Manchester, UK
- University of Miami, Florida
- University of Montana
- University of New Hampshire
- University of Oklahoma, Norman
- University of Washington, Seattle
- Washington University in Saint Louis, Missouri
Add Incoming Edge
Login via ORCiD to contribute.
Add Outgoing Edge
Login via ORCiD to contribute.