Impacts of wind power on air quality, premature mortality, and exposure disparities in the United States

Impacts of wind power on air quality, premature mortality, and exposure disparities in the United States

M. Qiu, C. M. Zigler, and N. E. Selin. 2022. Science Advances 8, eabn8762. [html] [MIT News]

From Stockholm to Minamata and beyond: Governing mercury pollution for a more sustainable future

From Stockholm to Minamata and beyond: Governing mercury pollution for a more sustainable future

H. Selin and N. E. Selin. 2022. One Earth, 5(10):1109-1125. [html]

A tool for air pollution scenarios (TAPS v1.0) to enable global, long-term, and flexible study of climate and air quality policies

A tool for air pollution scenarios (TAPS v1.0) to enable global, long-term, and flexible study of climate and air quality policies

W. Atkinson, S. D. Eastham, Y. H. H. Chen, J. Morris, S. Paltsev, C. A. Schlosser, and N. E. Selin. 2022. Geosci. Model Dev., 15, 7767–7789, https://doi.org/10.5194/gmd-15-7767-2022. [html]

Statistical and machine learning methods for evaluating trends in air quality under changing meteorological conditions

Statistical and machine learning methods for evaluating trends in air quality under changing meteorological conditions

M. Qiu, C. Zigler, and N. E. Selin. 2022. Atmos. Chem. Phys., 22, 10551–10566, https://doi.org/10.5194/acp-22-10551-2022. [html]

The Human-Technical-Environmental Systems Framework for Sustainability Analysis

The Human-Technical-Environmental Systems Framework for Sustainability Analysis

H. Selin and N. E. Selin. 2022. “The Human-Technical-Environmental Systems Framework for Sustainability Analysis.” Sustainability Science. [html]

Evaluating atmospheric mercury (Hg) uptake by vegetation in a chemistry-transport model

Evaluating atmospheric mercury (Hg) uptake by vegetation in a chemistry-transport model

A. Feinberg, T. Dlamini, M. Jiskra, V. Shah and N. E. Selin. 2022. Environmental Science: Processes & Impacts [html]

What are the likely changes in mercury concentration in the Arctic atmosphere and ocean under future emissions scenarios?

What are the likely changes in mercury concentration in the Arctic atmosphere and ocean under future emissions scenarios?

A.T. Schartup, A. L. Soerensen, H. Angot, K. Bowman, and N. E. Selin. 2022. Science of the Total Environment [html]

Meeting U.S. greenhouse gas emissions goals with the international air pollution provision of the clean air act

Meeting U.S. greenhouse gas emissions goals with the international air pollution provision of the clean air act

M. Yuan, A. R. Barron, N. E. Selin, P. D. Picciano, L. E. Metz, J. M. Reilly, and H. D. Jacoby. 2022. Environmental Research Letters [html]

The Parallel Transformations of Polycyclic Aromatic Hydrocarbons in the Body and in the Atmosphere

The Parallel Transformations of Polycyclic Aromatic Hydrocarbons in the Body and in the Atmosphere

A.I.H Hrdina, I. N. Kohale, S. Kaushal, J. Kelly, N. E. Selin, B. P. Engelward, J. H. Kroll. 2022. Environmental Health Perspectives 130(2) [html]

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Impacts of wind power on air quality, premature mortality, and exposure disparities in the United States
From Stockholm to Minamata and beyond: Governing mercury pollution for a more sustainable future
A tool for air pollution scenarios (TAPS v1.0) to enable global, long-term, and flexible study of climate and air quality policies
Statistical and machine learning methods for evaluating trends in air quality under changing meteorological conditions
The Human-Technical-Environmental Systems Framework for Sustainability Analysis
Evaluating atmospheric mercury (Hg) uptake by vegetation in a chemistry-transport model
What are the likely changes in mercury concentration in the Arctic atmosphere and ocean under future emissions scenarios?
Meeting U.S. greenhouse gas emissions goals with the international air pollution provision of the clean air act
The Parallel Transformations of Polycyclic Aromatic Hydrocarbons in the Body and in the Atmosphere