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Kyung-Eun Min

Kyung-Eun Min

Gwangju Institute of Science and Technology
Republic of Korea

Overview

What is he best known for?

The fields of study he is best known for:

Organic chemistry
Catalysis
Ozone

NOx, Environmental chemistry, Nitrate, Isoprene and Flux are his primary areas of study. His NOx research includes elements of Nitrogen oxides, Organic nitrates, Particulates and Ozone. His studies in Ozone integrate themes in fields like Smoke and Extratropical cyclone.

His Environmental chemistry research is multidisciplinary, incorporating perspectives in Atmosphere, Mineralogy, Methyl glyoxal and Organic molecules. His Nitrate study integrates concerns from other disciplines, such as Reactive nitrogen, Chemical transport model, Aerosol and Deposition. His work deals with themes such as Moisture, Peroxyacetyl nitrate and Deposition, which intersect with Flux.

His most cited work include:

Evidence for NOx Control over Nighttime SOA Formation (159 citations)
Nitrogen oxides and PAN in plumes from boreal fires during ARCTAS-B and their impact on ozone: an integrated analysis of aircraft and satellite observations (154 citations)
Closing the peroxy acetyl nitrate budget: observations of acyl peroxy nitrates (PAN, PPN, and MPAN) during BEARPEX 2007 (73 citations)

What are the main themes of his work throughout his whole career to date?

Kyung-Eun Min mainly investigates Environmental chemistry, NOx, Ozone, Isoprene and Atmosphere. Kyung-Eun Min interconnects Trace gas, Formaldehyde, Nitrogen oxides, Radical and Nitrate in the investigation of issues within Environmental chemistry. His NOx study also includes

Monoterpene which connect with Mixing ratio,
Nitrogen, which have a strong connection to Flux.

His Ozone study incorporates themes from Reactivity and Troposphere. The various areas that Kyung-Eun Min examines in his Atmosphere study include Daytime and Air quality index. While the research belongs to areas of Glyoxal, he spends his time largely on the problem of Nitrous acid, intersecting his research to questions surrounding Nitrogen dioxide.

He most often published in these fields:

Environmental chemistry (78.02%)
NOx (48.35%)
Ozone (41.76%)

What were the highlights of his more recent work (between 2016-2021)?

Environmental chemistry (78.02%)
Formaldehyde (31.87%)
Biomass burning (7.69%)

In recent papers he was focusing on the following fields of study:

Kyung-Eun Min mostly deals with Environmental chemistry, Formaldehyde, Biomass burning, Aerosol and Box model. His studies deal with areas such as Troposphere and Ozone as well as Environmental chemistry. His work on Chemical transport model as part of general Troposphere study is frequently linked to Planetary boundary layer and Isoprene, bridging the gap between disciplines.

His biological study spans a wide range of topics, including Nitrogen dioxide and Hydroxyl radical. His Formaldehyde research is multidisciplinary, incorporating elements of Natural gas, Glyoxal, Petrochemical, Carbon monoxide and Methane. His work deals with themes such as Atmosphere and Trace gas, which intersect with Aerosol.

Between 2016 and 2021, his most popular works were:

A Comprehensive Model Test of the HONO Sources Constrained to Field Measurements at Rural North China Plain. (18 citations)
Nighttime Chemical Transformation in Biomass Burning Plumes: A Box Model Analysis Initialized with Aircraft Observations. (14 citations)
Nighttime Chemical Transformation in Biomass Burning Plumes: A Box Model Analysis Initialized with Aircraft Observations. (14 citations)

In his most recent research, the most cited papers focused on:

Organic chemistry
Catalysis
Ozone

His primary areas of study are Aerosol, Atmosphere, Box model, Daytime and Chemical transformation. His studies in Aerosol integrate themes in fields like Trace gas, Ozone, Environmental chemistry, Radical and Troposphere. His Atmosphere research is multidisciplinary, incorporating perspectives in Nitrogen dioxide and Hydroxyl radical.

Box model is integrated with Box modeling and Biomass burning in his study.

This overview was generated by a machine learning system which analysed the scientist’s body of work. If you have any feedback, you can contact us here.

Best Publications

Evidence for NO(x) control over nighttime SOA formation.

A. W. Rollins;E. C. Browne;K.-E. Min;S. E. Pusede.
Science (2012)

246 Citations

Nitrogen oxides and PAN in plumes from boreal fires during ARCTAS-B and their impact on ozone: an integrated analysis of aircraft and satellite observations

M. J. Alvarado;J. A. Logan;J. Mao;E. Apel.
Atmospheric Chemistry and Physics (2010)

192 Citations

Closing the peroxy acetyl nitrate budget: observations of acyl peroxy nitrates (PAN, PPN, and MPAN) during BEARPEX 2007

B. W. LaFranchi;G. M. Wolfe;J. A. Thornton;S. A. Harrold.
Atmospheric Chemistry and Physics (2009)

115 Citations

Importance of biogenic precursors to the budget of organic nitrates: observations of multifunctional organic nitrates by CIMS and TD-LIF during BEARPEX 2009

M. R. Beaver;M. R. Beaver;J. M. St. Clair;F. Paulot;K. M. Spencer.
Atmospheric Chemistry and Physics (2012)

97 Citations

On the temperature dependence of organic reactivity, nitrogen oxides, ozone production, and the impact of emission controls in San Joaquin Valley, California

S. E. Pusede;D. R. Gentner;P. J. Wooldridge;E. C. Browne;E. C. Browne.
Atmospheric Chemistry and Physics (2014)

83 Citations

A broadband cavity enhanced absorption spectrometer for aircraft measurements of glyoxal, methylglyoxal, nitrous acid, nitrogen dioxide, and water vapor

K.-E. Min;K.-E. Min;K.-E. Min;R. A. Washenfelder;R. A. Washenfelder;W. P. Dubé;W. P. Dubé;A. O. Langford.
Atmospheric Measurement Techniques (2016)

72 Citations

Eddy covariance fluxes of acyl peroxy nitrates (PAN, PPN and MPAN) above a Ponderosa pine forest

G. M. Wolfe;J. A. Thornton;R. L. N. Yatavelli;M. McKay.
Atmospheric Chemistry and Physics (2009)

71 Citations

Instrumentation and measurement strategy for the NOAA SENEX aircraft campaign as part of the Southeast Atmosphere Study 2013

Carsten Warneke;Carsten Warneke;Michael Trainer;Joost A. de Gouw;Joost A. de Gouw;David D. Parrish;David D. Parrish.
Atmospheric Measurement Techniques (2016)

68 Citations

The Chemistry of Atmosphere-Forest Exchange (CAFE) Model – Part 2: Application to BEARPEX-2007 observations

G. M. Wolfe;J. A. Thornton;N. C. Bouvier-Brown;N. C. Bouvier-Brown;A. H. Goldstein.
Atmospheric Chemistry and Physics (2011)

65 Citations

A relaxed eddy accumulation system for measuring vertical fluxes of nitrous acid

X. Ren;X. Ren;J. E. Sanders;A. Rajendran;R. J. Weber.
Atmospheric Measurement Techniques (2011)

61 Citations

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