Chakrabarty’s research group addresses grand challenges associated with complex environmental systems while working at the forefront of fundamental aerosol science and engineering.
Some of those challenges include those associated with radiative forcing by carbonaceous aerosols as well as researching the environmental determinants of infectious disease transmission and the effectiveness of non-pharmaceutical containment strategies.
Chakrabarty joined the faculty at Washington University in St. Louis in 2014. His research contributions have been recognized with several prestigious honors, most notably the 2019 Kenneth T. Whitby award (AAAR); 2019 Schmauss award (GAeF); 2018 American Geophysical Union (AGU) Global Environmental Change Early Career award; the 2017 Richard M. Goody award by the electromagnetic light scattering and remote sensing community; and a 2015 NSF CAREER award.
The Environmental Molecular Sciences Laboratory, a Department of Energy facility, has awarded $577,685 to Rajan Chakrabarty at the McKelvey School of Engineering to chemically image atmospheric particles.
Research from the lab of Rajan Chakrabarty at the McKelvey School of Engineering connects environmental injustice to the spread of COVID-19 in communities with high minority populations.
Research from the lab of Rajan Chakrabarty in the McKelvey School of Engineering at Washington University in St. Louis has found a close relationship between certain pollutants and the spread of COVID-19 through the United States.
Modeling from the McKelvey School of Engineering at Washington University in St. Louis shows how social distancing could have better been implemented. The key? Longer periods of distancing would have helped — but only to a point. More needed to be done.
Aerosol research at the McKelvey School of Engineering at Washington University in St. Louis is working at breakneck speed to understand the novel coronavirus and its effects at scales ranging from ecosystems to virus particles suspended in droplets.
Researchers at the McKelvey School of Engineering spent two weeks in India cooking with local residents. They found that soot wasn’t the only worrisome byproduct of traditional cookstoves; organic carbons are causing problems, too.
Using aerosols as ground truth, researchers at the McKelvey School of Engineering at Washington University in St. Louis have developed a deep learning method that accurately simulates chaotic trajectories — from the spread of poisonous gas to the path of foraging animals.
A new, joint master’s degree program and shared aerosol science research facility is the latest collaboration in a long history of partnerships between the McKelvey School of Engineering and the Indian Institute of Technology, Bombay.
Researchers in the School of Engineering & Applied Science have discovered a new, natural law that sheds light on the fundamental relationship between coated black carbon and light absorption.
Engineers at Washington University in St. Louis have developed tools that mathematically describe the kinetics in a system right before it dissolves into randomness.
Millions of Asian families use cookstoves and often fuel them with cheap biofuels to prepare food. But the smoke emitted from these cookstoves has a definite, detrimental environmental impact, particularly in India. New research from Washington University in St. Louis offers a clearer picture of the topic’s true scope.
As devastating wildfires rage in California wine country, a team of environmental engineers at Washington University in St. Louis have made a new discovery about wildfire smoke, and its effect on the atmosphere.
A pair of engineers at Washington University in St. Louis say proposed federal budget cuts to science programs and agencies could signal sweeping changes in the way our nation regulates and researches the environment.
