Simulating the Geological Fate of Terrestrial Organic Matter: Lignin vs Cellulose

Lea Atmani; Pierre Louis Valdenaire; Roland J.M. Pellenq; Christophe Bichara; Henri Van Damme; Adri C.T. Van Duin; Franz J. Ulm; Jean Marc Leyssale

doi:10.1021/acs.energyfuels.9b03681

Simulating the Geological Fate of Terrestrial Organic Matter: Lignin vs Cellulose

Lea Atmani
, Pierre Louis Valdenaire
, Roland J.M. Pellenq
, Christophe Bichara
, Henri Van Damme
, Adri C.T. Van Duin
, Franz J. Ulm
, Jean Marc Leyssale

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

20 Scopus citations

Abstract

While shale gas has become a major source of energy, a more sustainable recovery requires a better understanding of the gas/kerogen matrix interactions. Here, we use replica exchange molecular dynamics to investigate the geological conversion of two important classes of gas-forming constituents of the terrestrial organic matter: lignin and cellulose. In agreement with results from pyrolysis experiments, we show that lignin produces twice as much kerogen and 5 times more methane than cellulose. In addition, while ex-cellulose kerogen is relatively stiff and almost nonporous, ex-lignin kerogen, despite having a very similar composition and bonding, is an order of magnitude more compliant due to the presence of large micropores. The obtained results can potentially improve the nanoscale brick of bottom-up models of shale gas recovery.

Original language	English (US)
Pages (from-to)	1537-1547
Number of pages	11
Journal	Energy and Fuels
Volume	34
Issue number	2
DOIs	https://doi.org/10.1021/acs.energyfuels.9b03681
State	Published - Feb 20 2020

All Science Journal Classification (ASJC) codes

General Chemical Engineering
Fuel Technology
Energy Engineering and Power Technology

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10.1021/acs.energyfuels.9b03681

Cite this

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title = "Simulating the Geological Fate of Terrestrial Organic Matter: Lignin vs Cellulose",

abstract = "While shale gas has become a major source of energy, a more sustainable recovery requires a better understanding of the gas/kerogen matrix interactions. Here, we use replica exchange molecular dynamics to investigate the geological conversion of two important classes of gas-forming constituents of the terrestrial organic matter: lignin and cellulose. In agreement with results from pyrolysis experiments, we show that lignin produces twice as much kerogen and 5 times more methane than cellulose. In addition, while ex-cellulose kerogen is relatively stiff and almost nonporous, ex-lignin kerogen, despite having a very similar composition and bonding, is an order of magnitude more compliant due to the presence of large micropores. The obtained results can potentially improve the nanoscale brick of bottom-up models of shale gas recovery.",

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T2 - Lignin vs Cellulose

AU - Atmani, Lea

AU - Valdenaire, Pierre Louis

AU - Pellenq, Roland J.M.

AU - Bichara, Christophe

AU - Van Damme, Henri

AU - Van Duin, Adri C.T.

AU - Ulm, Franz J.

AU - Leyssale, Jean Marc

PY - 2020/2/20

Y1 - 2020/2/20

N2 - While shale gas has become a major source of energy, a more sustainable recovery requires a better understanding of the gas/kerogen matrix interactions. Here, we use replica exchange molecular dynamics to investigate the geological conversion of two important classes of gas-forming constituents of the terrestrial organic matter: lignin and cellulose. In agreement with results from pyrolysis experiments, we show that lignin produces twice as much kerogen and 5 times more methane than cellulose. In addition, while ex-cellulose kerogen is relatively stiff and almost nonporous, ex-lignin kerogen, despite having a very similar composition and bonding, is an order of magnitude more compliant due to the presence of large micropores. The obtained results can potentially improve the nanoscale brick of bottom-up models of shale gas recovery.

AB - While shale gas has become a major source of energy, a more sustainable recovery requires a better understanding of the gas/kerogen matrix interactions. Here, we use replica exchange molecular dynamics to investigate the geological conversion of two important classes of gas-forming constituents of the terrestrial organic matter: lignin and cellulose. In agreement with results from pyrolysis experiments, we show that lignin produces twice as much kerogen and 5 times more methane than cellulose. In addition, while ex-cellulose kerogen is relatively stiff and almost nonporous, ex-lignin kerogen, despite having a very similar composition and bonding, is an order of magnitude more compliant due to the presence of large micropores. The obtained results can potentially improve the nanoscale brick of bottom-up models of shale gas recovery.

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JO - Energy and Fuels

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IS - 2

ER -

Simulating the Geological Fate of Terrestrial Organic Matter: Lignin vs Cellulose

Abstract

All Science Journal Classification (ASJC) codes

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