On the Role of Heterogeneous Chemistry in Ozone Depletion and Recovery

Catherine Wilka; Kasturi Shah; Kane Stone; Susan Solomon; Douglas Kinnison; Michael Mills; Anja Schmidt; Ryan R. Neely

doi:10.1029/2018GL078596

On the Role of Heterogeneous Chemistry in Ozone Depletion and Recovery

Catherine Wilka, Kasturi Shah, Kane Stone, Susan Solomon, Douglas Kinnison, Michael Mills, Anja Schmidt, Ryan R. Neely

ACOM Modeling

Research output: Contribution to journal › Article › peer-review

13 Scopus citations

Abstract

We demonstrate that identification of stratospheric ozone changes attributable to ozone depleting substances and actions taken under the Montreal Protocol requires evaluation of confounding influences from volcanic eruptions. Using a state-of-the-art chemistry-climate model, we show that increased stratospheric aerosol loading from volcanic eruptions after 2004 impeded the rate of ozone recovery post-2000. In contrast, eruptions increased ozone loss rates over the depletion era from 1980 to 1998. We also present calculations without any aerosol chemistry to isolate contributions from gas-phase chemistry alone. This study reinforces the need for accurate information regarding stratospheric aerosol loading when modeling ozone changes, particularly for the challenging task of accurately identifying the early signs of ozone healing distinct from other sources of variability.

Original language	English
Pages (from-to)	7835-7842
Number of pages	8
Journal	Geophysical Research Letters
Volume	45
Issue number	15
DOIs	https://doi.org/10.1029/2018GL078596
State	Published - Aug 16 2018

Keywords

heterogeneous chemistry
ozone depletion
ozone recovery
stratosphere
volcanic aerosols

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10.1029/2018GL078596

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title = "On the Role of Heterogeneous Chemistry in Ozone Depletion and Recovery",

abstract = "We demonstrate that identification of stratospheric ozone changes attributable to ozone depleting substances and actions taken under the Montreal Protocol requires evaluation of confounding influences from volcanic eruptions. Using a state-of-the-art chemistry-climate model, we show that increased stratospheric aerosol loading from volcanic eruptions after 2004 impeded the rate of ozone recovery post-2000. In contrast, eruptions increased ozone loss rates over the depletion era from 1980 to 1998. We also present calculations without any aerosol chemistry to isolate contributions from gas-phase chemistry alone. This study reinforces the need for accurate information regarding stratospheric aerosol loading when modeling ozone changes, particularly for the challenging task of accurately identifying the early signs of ozone healing distinct from other sources of variability.",

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T1 - On the Role of Heterogeneous Chemistry in Ozone Depletion and Recovery

AU - Wilka, Catherine

AU - Shah, Kasturi

AU - Stone, Kane

AU - Solomon, Susan

AU - Kinnison, Douglas

AU - Mills, Michael

AU - Schmidt, Anja

AU - Neely, Ryan R.

PY - 2018/8/16

Y1 - 2018/8/16

N2 - We demonstrate that identification of stratospheric ozone changes attributable to ozone depleting substances and actions taken under the Montreal Protocol requires evaluation of confounding influences from volcanic eruptions. Using a state-of-the-art chemistry-climate model, we show that increased stratospheric aerosol loading from volcanic eruptions after 2004 impeded the rate of ozone recovery post-2000. In contrast, eruptions increased ozone loss rates over the depletion era from 1980 to 1998. We also present calculations without any aerosol chemistry to isolate contributions from gas-phase chemistry alone. This study reinforces the need for accurate information regarding stratospheric aerosol loading when modeling ozone changes, particularly for the challenging task of accurately identifying the early signs of ozone healing distinct from other sources of variability.

AB - We demonstrate that identification of stratospheric ozone changes attributable to ozone depleting substances and actions taken under the Montreal Protocol requires evaluation of confounding influences from volcanic eruptions. Using a state-of-the-art chemistry-climate model, we show that increased stratospheric aerosol loading from volcanic eruptions after 2004 impeded the rate of ozone recovery post-2000. In contrast, eruptions increased ozone loss rates over the depletion era from 1980 to 1998. We also present calculations without any aerosol chemistry to isolate contributions from gas-phase chemistry alone. This study reinforces the need for accurate information regarding stratospheric aerosol loading when modeling ozone changes, particularly for the challenging task of accurately identifying the early signs of ozone healing distinct from other sources of variability.

KW - heterogeneous chemistry

KW - ozone depletion

KW - ozone recovery

KW - stratosphere

KW - volcanic aerosols

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SP - 7835

EP - 7842

JO - Geophysical Research Letters

JF - Geophysical Research Letters

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ER -

On the Role of Heterogeneous Chemistry in Ozone Depletion and Recovery

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Keywords

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