Study of molecular interfaces in polymer thin-film composite membranes for the efficient gas separations

• Project/Area Number: 22K04806
• Research Category: Grant-in-Aid for Scientific Research (C)
• Allocation Type: Multi-year Fund
• Section: 一般
• Review Section: Basic Section 27010:Transport phenomena and unit operations-related
• Research Institution: Kyushu University
• Principal Investigator: Selyanchyn Roman 九州大学, エネルギー研究教育機構, 准教授 (90729790)
• Project Period (FY): 2022-04-01 – 2025-03-31
• Project Status: Granted (Fiscal Year 2022)
• Budget Amount: ¥4,030,000 (Direct Cost: ¥3,100,000、Indirect Cost: ¥930,000); Fiscal Year 2024: ¥780,000 (Direct Cost: ¥600,000、Indirect Cost: ¥180,000); Fiscal Year 2023: ¥780,000 (Direct Cost: ¥600,000、Indirect Cost: ¥180,000); Fiscal Year 2022: ¥2,470,000 (Direct Cost: ¥1,900,000、Indirect Cost: ¥570,000)
• Keywords: gas separation / thin-film composite / carbon dioxide / molecular interface / interface selectivity / selective interface / CO2/N2 separation / polymer interface / CO2 philicity

Outline of Research at the Start

This study is devoted to the development of thin-film composite membranes with selective molecularly-thin interfaces between polymers to achieve efficient carbon dioxide separation from complex mixtures with other gases. Specifically, separation from nitrogen, oxygen and hydrogen will be studied.

Outline of Annual Research Achievements

This work is devoted to developing and investigating thin-film composite (TFC) membranes with selective molecularly-thin interfaces between polymers to achieve efficient carbon dioxide (CO2) separation from complex mixtures with other gases. During the first year, the research is progressing according to the original plan. The focus was to investigate how the surface modification of the hydrophobic polymer layer by water vapor-generated plasma influences the formation of the selective interface with the hydrophilic selective layer. It was found that some minimum critical amount of surface modification is essential to form the proper laminate structure. Furthermore, the influence of surface modification by the plasma treatment alone was found insufficient to increase the membrane's selectivity towards CO2.

The gas transport of CO2, O2, and N2 was thoroughly studied. The existence of the molecular interface was found to be the essential factor in the highly selective CO2/N2 and CO2/O2 separation. With the inclusion of the selective interface in the structure of the TFC, the selectivity increased to about 35 and 13 for CO2/N2 and CO2/O2 separation, respectively (~10 and ~5 in the membranes without the selective layer and interface). Finally, this work focuses on their membrane application for the direct air capture of CO2. Direct air capture is an important technology to mitigate the effects of climate change. By capturing carbon dioxide directly from the air, we can reduce the amount of greenhouse gases in the atmosphere and slow down the rate of global warming.

Current Status of Research Progress

2: Research has progressed on the whole more than it was originally planned.

Reason

The research is progressing smoothly according to the initial plan investigating both surface modification impact on gas separation and thinning of the layer in the thin-film composites.

Strategy for Future Research Activity

The conditions of the selective interface formation between the hydrophobic and hydrophilic polymers were understood, and the influence of the surface modification by water plasma was systematically studied. In the next research stage, we need to understand the influence of the thicknesses of polymeric layers in the structure of the thin-film composite membrane. The following work will use the optimal conditions for surface modification. Now we will systematically investigate the thickness's impact to elucidate the interface formation mechanism and its contribution to the attained CO2 selectivity and, consequently, gas separation performance.

Research Products

• [Journal Article] Carbon molecular sieve membranes fabricated at low carbonization temperatures with novel polymeric acid porogen for light gas separation (2023)
  • Author(s): Hongfang Guo, Jing Wei, Yulei Ma, Zikang Qin, Xiaohua Ma, Roman Selyanchyn, Bangda Wang, Xuezhong He, Bo Tang, Lin Yang, Lu Yao, Wenju Jiang, Yuanfa Zhuang, Dengguo Yin, Xue Li, Zhongde Dai
  • Journal Title: Separation and Purification Technology Volume: 317 Pages: 1-11
  • DOI: 10.1016/j.seppur.2023.123883
  • Peer Reviewed
• [Journal Article] Direct air capture by membranes (2022)
  • Author(s): Shigenori Fujikawa, Roman Selyanchyn
  • Journal Title: MRS Bulletin Volume: 47 Issue: 4 Pages: 416-423
  • DOI: 10.1557/s43577-022-00313-6
  • Peer Reviewed / Open Access
• [Journal Article] Cellulose Nanocrystals Crosslinked with Sulfosuccinic Acid as Sustainable Proton Exchange Membranes for Electrochemical Energy Applications (2022)
  • Author(s): Olena Selyanchyn, Thomas Bayer, Dino Klotz, Roman Selyanchyn, Kazunari Sasaki, Stephen Matthew Lyth
  • Journal Title: Membranes Volume: 12 (7) Issue: 7 Pages: 658-658
  • DOI: 10.3390/membranes12070658
  • Peer Reviewed / Open Access
• [Presentation] CO2 preconcentration from air with the aid of membranes and its potential for distributed CO2 utilization systems (2022)
  • Author(s): Roman Selyanchyn
  • Organizer: MIRAI 2.0 Research and Innovation Week, Kyushu University