Steam Stripping-Coupled Cycle for Thermodynamic Optimization and Carbon Cycle Intensification in CO/CO2 Mixed-Gas Hydrogenation Methanol Synthesis

Xin Yu; Yan Gao; Guangjie Zhou; Shidan Chi; Chongming Wang; Chaonan Tan; Arman Burkitbayev; Jun Yan; Xudong Zhao

doi:10.1021/acsomega.5c05883

Steam Stripping-Coupled Cycle for Thermodynamic Optimization and Carbon Cycle Intensification in CO/CO2 Mixed-Gas Hydrogenation Methanol Synthesis

Xin Yu
, Yan Gao
, Guangjie Zhou
, Shidan Chi
, Chongming Wang
, Chaonan Tan
, Arman Burkitbayev
, Jun Yan
, Xudong Zhao

Centre for E-Mobility and Clean Growth

Shandong Jianzhu University
Shandong Electric Power Engineering Consulting Institute Corp
German-Kazakh Institute of Sustainable Engineering
Zhejiang University
University College London

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

8 Citations (Scopus)

34 Downloads (Pure)

Abstract

Methanol synthesis, a crucial platform chemical and clean energy carrier, plays a significant role in the global energy transition. This study focuses on thermodynamic optimization and carbon cycle intensification of the CO/CO ₂hydrogenation process. A multidimensional reaction system model was developed to investigate the effects of the CO/CO ₂feed ratio, H ₂/CO _xmolar ratio, reaction temperature and pressure, catalyst efficiency, and gas–liquid mass transfer resistance on product distribution. To improve carbon utilization, an innovative steam stripping-coupled cycle process was proposed, enabling efficient recovery of dissolved CO ₂in the liquid phase through phase equilibrium regulation. This reduced the CO ₂content from 10.72 kmol·h ^–1before stripping to 1.69 × 10 ^–4kmol·h ^–1after stripping. Under optimized operating conditions, the methanol yield reached 82.0%, and the single-pass yields of CO and CO ₂were 90.7% and 72.6%, respectively. After the novel stripping cycle was adopted, the loss of liquid-phase CO ₂became negligible, with carbon and hydrogen losses mainly caused by gas-phase relaxation. When the relaxation rate was set to 1.0%, the utilization of CO _xand H ₂reached 93.2% and 82.8%, respectively. This strategy established a dynamic reaction-separation-recycle balance, improving both resource efficiency and economic performance, and offering theoretical and technical guidance for green methanol industrialization.

Original language	English
Pages (from-to)	40477-40491
Number of pages	15
Journal	ACS Omega
Volume	10
Issue number	35
Early online date	26 Aug 2025
DOIs	https://doi.org/10.1021/acsomega.5c05883
Publication status	E-pub ahead of print - 26 Aug 2025

Bibliographical note

Copyright © 2025 The Authors. Published by American Chemical Society
This publication is licensed under CC-BY-NC-ND 4.0 .

Funding

This project is funded by the following funds: the Shandong Province Innovation Capacity Enhancement Project for Science and Technology-based Small and Medium-sized Enterprises (2023TSGC0206); the “Chunhui Plan” cooperative scientific research project of the Ministry of Education of China (HZKY20220498); the China Postdoctoral Science Foundation (2020M671983); the Postdoctoral Innovation Project of Shandong Province (202103077); the Shandong Province technology innovation project plan (202360001105, 202350101441); the China Scholarship Council (202008370134); the Shandong Province Housing and Urban-Rural Construction Science and Technology Project (2022-K7-11, 2021-K8-10, 2020-K2-10); the Doctoral Fund of Shandong Jianzhu University (X18069Z).

Funders	Funder number
Shandong Province Housing and Urban-Rural Construction Science and Technology Project	2021-K8-10, 2020-K2-10, 2022-K7-11
Shandong Province technology innovation	202360001105, 202350101441
Shandong Province Innovation Capacity Enhancement Project for Science and Technology-based Small and Medium-sized Enterprises	2023TSGC0206
China Scholarship Council	202008370134
Ministry of Education China	HZKY20220498
Shandong Jianzhu University	X18069Z
Postdoctoral Innovation Project of Shandong Province	202103077
China Postdoctoral Science Foundation	2020M671983

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 7 Affordable and Clean Energy
SDG 8 Decent Work and Economic Growth
SDG 12 Responsible Consumption and Production

Access to Document

10.1021/acsomega.5c05883Licence: CC BY-NC-ND

Wang2025VoRFinal published version, 4.12 MBLicence: CC BY-NC-ND

Cite this

@article{dd8721ee5101476490eef02ca05bfaeb,

title = "Steam Stripping-Coupled Cycle for Thermodynamic Optimization and Carbon Cycle Intensification in CO/CO2 Mixed-Gas Hydrogenation Methanol Synthesis",

abstract = "Methanol synthesis, a crucial platform chemical and clean energy carrier, plays a significant role in the global energy transition. This study focuses on thermodynamic optimization and carbon cycle intensification of the CO/CO 2hydrogenation process. A multidimensional reaction system model was developed to investigate the effects of the CO/CO 2feed ratio, H 2/CO xmolar ratio, reaction temperature and pressure, catalyst efficiency, and gas–liquid mass transfer resistance on product distribution. To improve carbon utilization, an innovative steam stripping-coupled cycle process was proposed, enabling efficient recovery of dissolved CO 2in the liquid phase through phase equilibrium regulation. This reduced the CO 2content from 10.72 kmol·h –1before stripping to 1.69 × 10 –4kmol·h –1after stripping. Under optimized operating conditions, the methanol yield reached 82.0\%, and the single-pass yields of CO and CO 2were 90.7\% and 72.6\%, respectively. After the novel stripping cycle was adopted, the loss of liquid-phase CO 2became negligible, with carbon and hydrogen losses mainly caused by gas-phase relaxation. When the relaxation rate was set to 1.0\%, the utilization of CO xand H 2reached 93.2\% and 82.8\%, respectively. This strategy established a dynamic reaction-separation-recycle balance, improving both resource efficiency and economic performance, and offering theoretical and technical guidance for green methanol industrialization.",

author = "Xin Yu and Yan Gao and Guangjie Zhou and Shidan Chi and Chongming Wang and Chaonan Tan and Arman Burkitbayev and Jun Yan and Xudong Zhao",

note = "Copyright {\textcopyright} 2025 The Authors. Published by American Chemical Society This publication is licensed under CC-BY-NC-ND 4.0 .",

year = "2025",

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doi = "10.1021/acsomega.5c05883",

language = "English",

volume = "10",

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T1 - Steam Stripping-Coupled Cycle for Thermodynamic Optimization and Carbon Cycle Intensification in CO/CO2 Mixed-Gas Hydrogenation Methanol Synthesis

AU - Yu, Xin

AU - Gao, Yan

AU - Zhou, Guangjie

AU - Chi, Shidan

AU - Wang, Chongming

AU - Tan, Chaonan

AU - Burkitbayev, Arman

AU - Yan, Jun

AU - Zhao, Xudong

PY - 2025/8/26

Y1 - 2025/8/26

N2 - Methanol synthesis, a crucial platform chemical and clean energy carrier, plays a significant role in the global energy transition. This study focuses on thermodynamic optimization and carbon cycle intensification of the CO/CO 2hydrogenation process. A multidimensional reaction system model was developed to investigate the effects of the CO/CO 2feed ratio, H 2/CO xmolar ratio, reaction temperature and pressure, catalyst efficiency, and gas–liquid mass transfer resistance on product distribution. To improve carbon utilization, an innovative steam stripping-coupled cycle process was proposed, enabling efficient recovery of dissolved CO 2in the liquid phase through phase equilibrium regulation. This reduced the CO 2content from 10.72 kmol·h –1before stripping to 1.69 × 10 –4kmol·h –1after stripping. Under optimized operating conditions, the methanol yield reached 82.0%, and the single-pass yields of CO and CO 2were 90.7% and 72.6%, respectively. After the novel stripping cycle was adopted, the loss of liquid-phase CO 2became negligible, with carbon and hydrogen losses mainly caused by gas-phase relaxation. When the relaxation rate was set to 1.0%, the utilization of CO xand H 2reached 93.2% and 82.8%, respectively. This strategy established a dynamic reaction-separation-recycle balance, improving both resource efficiency and economic performance, and offering theoretical and technical guidance for green methanol industrialization.

AB - Methanol synthesis, a crucial platform chemical and clean energy carrier, plays a significant role in the global energy transition. This study focuses on thermodynamic optimization and carbon cycle intensification of the CO/CO 2hydrogenation process. A multidimensional reaction system model was developed to investigate the effects of the CO/CO 2feed ratio, H 2/CO xmolar ratio, reaction temperature and pressure, catalyst efficiency, and gas–liquid mass transfer resistance on product distribution. To improve carbon utilization, an innovative steam stripping-coupled cycle process was proposed, enabling efficient recovery of dissolved CO 2in the liquid phase through phase equilibrium regulation. This reduced the CO 2content from 10.72 kmol·h –1before stripping to 1.69 × 10 –4kmol·h –1after stripping. Under optimized operating conditions, the methanol yield reached 82.0%, and the single-pass yields of CO and CO 2were 90.7% and 72.6%, respectively. After the novel stripping cycle was adopted, the loss of liquid-phase CO 2became negligible, with carbon and hydrogen losses mainly caused by gas-phase relaxation. When the relaxation rate was set to 1.0%, the utilization of CO xand H 2reached 93.2% and 82.8%, respectively. This strategy established a dynamic reaction-separation-recycle balance, improving both resource efficiency and economic performance, and offering theoretical and technical guidance for green methanol industrialization.

UR - https://www.scopus.com/pages/publications/105016759955

U2 - 10.1021/acsomega.5c05883

DO - 10.1021/acsomega.5c05883

M3 - Article

SN - 2470-1343

VL - 10

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JO - ACS Omega

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IS - 35

ER -

Steam Stripping-Coupled Cycle for Thermodynamic Optimization and Carbon Cycle Intensification in CO/CO2 Mixed-Gas Hydrogenation Methanol Synthesis

Abstract

Bibliographical note

Funding

UN SDGs

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