Measurement of Atmospheric Mercury: Current Limitations and Suggestions for Paths Forward

Authors

Mae Sexauer Gustin, University of Nevada, Reno
Sarrah M. Dunham-Cheatham, University of Nevada, Reno
Seth Lyman, Utah State University
Milena Horvat, Institut "Jožef Stefan"
David A. Gay, University of Wisconsin-Madison
Jan Gačnik, University of Nevada, Reno
Lynne Gratz, Reed College
Geyan Kempkes, University of Pretoria
Alexei Khalizov, New Jersey Institute of Technology
Che Jen Lin, Lamar University
Steven E. Lindberg, Oak Ridge National Laboratory
Livia Lown, University of Nevada, Reno
Lynwill Martin, South Africa Weather Service
Robert Peter Mason, University of Connecticut Avery Point Campus
Katrina MacSween, Environment and Climate Change Canada
Sreekanth Vijayakumaran Nair, Institut "Jožef Stefan"
Ly Sy Phu Nguyen, University of Science, Viet Nam National University Ho Chi Minh City
Trevor O’Neil, Utah State University
Jonas Sommar, Institute of Geochemistry Chinese Academy of Sciences
Peter Weiss-Penzias, University of California, Santa Cruz

Document Type

Article

Publication Date

7-23-2024

Abstract

Mercury (Hg) researchers have made progress in understanding atmospheric Hg, especially with respect to oxidized Hg (HgII) that can represent 2 to 20% of Hg in the atmosphere. Knowledge developed over the past ∼10 years has pointed to existing challenges with current methods for measuring atmospheric Hg concentrations and the chemical composition of HgII compounds. Because of these challenges, atmospheric Hg experts met to discuss limitations of current methods and paths to overcome them considering ongoing research. Major conclusions included that current methods to measure gaseous oxidized and particulate-bound Hg have limitations, and new methods need to be developed to make these measurements more accurate. Developing analytical methods for measurement of HgII chemistry is challenging. While the ultimate goal is the development of ultrasensitive methods for online detection of HgII directly from ambient air, in the meantime, new surfaces are needed on which HgII can be quantitatively collected and from which it can be reversibly desorbed to determine HgII chemistry. Discussion and identification of current limitations, described here, provide a basis for paths forward. Since the atmosphere is the means by which Hg is globally distributed, accurately calibrated measurements are critical to understanding the Hg biogeochemical cycle.

Identifier

85198348363 (Scopus)

Publication Title

Environmental Science and Technology

External Full Text Location

https://doi.org/10.1021/acs.est.4c06011

e-ISSN

15205851

ISSN

0013936X

PubMed ID

38982755

First Page

12853

Last Page

12864

Issue

29

Volume

58

Grant

2303105

Fund Ref

National Science Foundation

Recommended Citation

Gustin, Mae Sexauer; Dunham-Cheatham, Sarrah M.; Lyman, Seth; Horvat, Milena; Gay, David A.; Gačnik, Jan; Gratz, Lynne; Kempkes, Geyan; Khalizov, Alexei; Lin, Che Jen; Lindberg, Steven E.; Lown, Livia; Martin, Lynwill; Mason, Robert Peter; MacSween, Katrina; Vijayakumaran Nair, Sreekanth; Nguyen, Ly Sy Phu; O’Neil, Trevor; Sommar, Jonas; and Weiss-Penzias, Peter, "Measurement of Atmospheric Mercury: Current Limitations and Suggestions for Paths Forward" (2024). Faculty Publications. 279.
https://digitalcommons.njit.edu/fac_pubs/279