On the encounter desorption of hydrogen atoms on an ice mantle

Qiang Chang; Xu Li Zheng; Xia Zhang; Dong Hui Quan; Yang Lu; Qing Kuan Meng; Xiao Hu Li; Long Fei Chen

doi:10.1088/1674-4527/21/2/39

On the encounter desorption of hydrogen atoms on an ice mantle

Qiang Chang
, Xu Li Zheng
, Xia Zhang
, Dong Hui Quan
, Yang Lu
, Qing Kuan Meng
, Xiao Hu Li
, Long Fei Chen

Department of Chemistry and Materials Science

Shandong University of Technology
CAS - National Astronomical Observatories
Eastern Kentucky University
Sun Yat-Sen University

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

7 Citations (Scopus)

Abstract

At low temperatures (∼10 K), hydrogen atoms can diffuse quickly on grain ice mantles and frequently encounter hydrogen molecules, which cover a notable fraction of grain surface. The desorption energy of H atoms on H2 substrates is much less than that on water ice. The H atom encounter desorption mechanism is adopted to study the enhanced desorption of H atoms on H2 substrates. Using a small reaction network, we show that the steady-state surface H abundances predicted by the rate equation model that includes H atom encounter desorption agree reasonably well with the results from the more rigorous microscopic Monte Carlo method. For a full gas-grain model, H atom encounter desorption can reduce surface H abundances. Therefore, if a model adopts the encounter desorption of H atoms, it becomes more difficult for hydrogenation products such as methanol to form, but it is easier for C, O and N atoms to bond with each other on grain surfaces.

Original language	English
Article number	039
Journal	Research in Astronomy and Astrophysics
Volume	21
Issue number	2
DOIs	https://doi.org/10.1088/1674-4527/21/2/39
Publication status	Published - Mar 2021

Keywords

astrochemistry
ISM: abundances
ISM: molecules

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10.1088/1674-4527/21/2/39

Cite this

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title = "On the encounter desorption of hydrogen atoms on an ice mantle",

abstract = "At low temperatures (∼10 K), hydrogen atoms can diffuse quickly on grain ice mantles and frequently encounter hydrogen molecules, which cover a notable fraction of grain surface. The desorption energy of H atoms on H2 substrates is much less than that on water ice. The H atom encounter desorption mechanism is adopted to study the enhanced desorption of H atoms on H2 substrates. Using a small reaction network, we show that the steady-state surface H abundances predicted by the rate equation model that includes H atom encounter desorption agree reasonably well with the results from the more rigorous microscopic Monte Carlo method. For a full gas-grain model, H atom encounter desorption can reduce surface H abundances. Therefore, if a model adopts the encounter desorption of H atoms, it becomes more difficult for hydrogenation products such as methanol to form, but it is easier for C, O and N atoms to bond with each other on grain surfaces.",

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author = "Qiang Chang and Zheng, \{Xu Li\} and Xia Zhang and Quan, \{Dong Hui\} and Yang Lu and Meng, \{Qing Kuan\} and Li, \{Xiao Hu\} and Chen, \{Long Fei\}",

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doi = "10.1088/1674-4527/21/2/39",

language = "English",

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TY - JOUR

T1 - On the encounter desorption of hydrogen atoms on an ice mantle

AU - Chang, Qiang

AU - Zheng, Xu Li

AU - Zhang, Xia

AU - Quan, Dong Hui

AU - Lu, Yang

AU - Meng, Qing Kuan

AU - Li, Xiao Hu

AU - Chen, Long Fei

PY - 2021/3

Y1 - 2021/3

N2 - At low temperatures (∼10 K), hydrogen atoms can diffuse quickly on grain ice mantles and frequently encounter hydrogen molecules, which cover a notable fraction of grain surface. The desorption energy of H atoms on H2 substrates is much less than that on water ice. The H atom encounter desorption mechanism is adopted to study the enhanced desorption of H atoms on H2 substrates. Using a small reaction network, we show that the steady-state surface H abundances predicted by the rate equation model that includes H atom encounter desorption agree reasonably well with the results from the more rigorous microscopic Monte Carlo method. For a full gas-grain model, H atom encounter desorption can reduce surface H abundances. Therefore, if a model adopts the encounter desorption of H atoms, it becomes more difficult for hydrogenation products such as methanol to form, but it is easier for C, O and N atoms to bond with each other on grain surfaces.

AB - At low temperatures (∼10 K), hydrogen atoms can diffuse quickly on grain ice mantles and frequently encounter hydrogen molecules, which cover a notable fraction of grain surface. The desorption energy of H atoms on H2 substrates is much less than that on water ice. The H atom encounter desorption mechanism is adopted to study the enhanced desorption of H atoms on H2 substrates. Using a small reaction network, we show that the steady-state surface H abundances predicted by the rate equation model that includes H atom encounter desorption agree reasonably well with the results from the more rigorous microscopic Monte Carlo method. For a full gas-grain model, H atom encounter desorption can reduce surface H abundances. Therefore, if a model adopts the encounter desorption of H atoms, it becomes more difficult for hydrogenation products such as methanol to form, but it is easier for C, O and N atoms to bond with each other on grain surfaces.

KW - astrochemistry

KW - ISM: abundances

KW - ISM: molecules

UR - https://www.scopus.com/pages/publications/85104669605

U2 - 10.1088/1674-4527/21/2/39

DO - 10.1088/1674-4527/21/2/39

M3 - Article

AN - SCOPUS:85104669605

SN - 1674-4527

VL - 21

JO - Research in Astronomy and Astrophysics

JF - Research in Astronomy and Astrophysics

IS - 2

M1 - 039

ER -

On the encounter desorption of hydrogen atoms on an ice mantle

Abstract

Keywords

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