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Literature DB >> 28488398

Poly(Ionic Liquid)-Derived Carbon with Site-Specific N-Doping and Biphasic Heterojunction for Enhanced CO₂ Capture and Sensing.

Jiang Gong¹, Markus Antonietti¹, Jiayin Yuan^1,2.

Abstract

CO2 capture is a pressing global environmental issue that drives scientists to develop creative strategies for tackling this challenge. The concept in this contribution is to produce site-specific nitrogen doping in microporous carbon fibers. Following this approach a carbon/carbon heterojunction is created by using a poly(ionic liquid) (PIL) as a "soft" activation agent that deposits nitrogen species exclusively on the surface of commercial microporous carbon fibers. This type of carbon-based biphasic heterojunction amplifies the interaction between carbon fiber and CO2 molecule for unusually high CO2 uptake and resistive sensing.

Entities: Chemical

Keywords: CO2 capture; CO2 sensors; biphasic heterojunctions; carbon fibers; ionic liquids

Year: 2017 PMID： 28488398 DOI： 10.1002/anie.201702453

Source DB: PubMed Journal: Angew Chem Int Ed Engl ISSN： 1433-7851 Impact factor: 15.336

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Cited

4 in total

Review 4. N-Doped Mesoporous Carbons: From Synthesis to Applications as Metal-Free Reduction Catalysts and Energy Storage Materials.

Authors: Ying Yang; Lin Gu; Shangwei Guo; Shuai Shao; Zelin Li; Yuhang Sun; Shijie Hao
Journal: Front Chem Date: 2019-11-12 Impact factor: 5.221

4 in total

Poly(Ionic Liquid)-Derived Carbon with Site-Specific N-Doping and Biphasic Heterojunction for Enhanced CO₂ Capture and Sensing.

1. Biowaste-derived 3D honeycomb-like N and S dual-doped hierarchically porous carbons for high-efficient CO₂ capture.

2. Networked Cages for Enhanced CO₂ Capture and Sensing.

3. Cross-linked poly(ionic liquid) as precursors for nitrogen-doped porous carbons.

Review 4. N-Doped Mesoporous Carbons: From Synthesis to Applications as Metal-Free Reduction Catalysts and Energy Storage Materials.

Poly(Ionic Liquid)-Derived Carbon with Site-Specific N-Doping and Biphasic Heterojunction for Enhanced CO2 Capture and Sensing.

1. Biowaste-derived 3D honeycomb-like N and S dual-doped hierarchically porous carbons for high-efficient CO2 capture.

2. Networked Cages for Enhanced CO2 Capture and Sensing.

3. Cross-linked poly(ionic liquid) as precursors for nitrogen-doped porous carbons.

Review 4. N-Doped Mesoporous Carbons: From Synthesis to Applications as Metal-Free Reduction Catalysts and Energy Storage Materials.

Poly(Ionic Liquid)-Derived Carbon with Site-Specific N-Doping and Biphasic Heterojunction for Enhanced CO₂ Capture and Sensing.

1. Biowaste-derived 3D honeycomb-like N and S dual-doped hierarchically porous carbons for high-efficient CO₂ capture.

2. Networked Cages for Enhanced CO₂ Capture and Sensing.