Porous Carbon Nanofibers with Heteroatoms Doped by Electrospinning Exhibit Excellent Acetone and Carbon Dioxide Adsorption Performance: The Contributions of Pore Structure and Functional Groups

Shi, Rui; Liu, Baogen; Jiang, Yu-Wei; Xu, Xiang; Wang, Huijun; Zeng, Zheng; Li, Liqing

doi:10.1021/acsomega.1c04618

Cited by 9 publications

(4 citation statements)

References 56 publications

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“…Because of the highly feasible dipole–quadruple interaction between CO 2 and other adsorption sites (host–guest interaction), the interaction between CO 2 molecules becomes very negligible, which correlates with the Langmuir isotherm used for the fitting of the adsorption curve. Notably, all the Tt-POPs were rich in heteroatom content; here, micropores and the narrow PSD play a crucial role in enhancing the CO 2 uptake capacity. , From the PSD analysis (Figure S14, Supporting Information), it is obvious that among all the POPs, Tt-POP-2 showed a narrow PSD accompanied by 0.40 cm 3 /g of pore volume compared to the other Tt-POPs consisting of broader ones. This reflected the CO 2 uptake efficiency, and eventually Tt-POP-2 exhibited the best CO 2 uptake capacity in comparison to its other counterparts.…”

Section: Resultsmentioning

confidence: 95%

“…Notably, all the Tt-POPs were rich in heteroatom content; here, micropores and the narrow PSD play a crucial role in enhancing the CO 2 uptake capacity. 59,60 From the PSD analysis (Figure S14, Supporting Information), it is obvious that among all the POPs, Tt-POP-2 showed a narrow PSD accompanied by 0.40 cm 3 /g of pore volume compared to the other Tt-POPs consisting of broader ones. This reflected the CO 2 uptake efficiency, and eventually Tt-POP-2 exhibited the best CO 2 uptake capacity in comparison to its other counterparts.…”

Section: ■ Introductionmentioning

confidence: 99%

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Nanospace Engineering of Triazine−Thiophene-Intertwined Porous-Organic-Polymers via Molecular Expansion in Tweaking CO₂ Capture

Das

Paul

Dao

et al. 2022

ACS Appl. Nano Mater.

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Post-combustion CO2 capture, storage, and separation have garnered colossal research interest in the energy industry, although realistic implementation of the available porous adsorbents is restricted owing to their cost competitiveness, stability, and scalability issues. The integration of heteroatom functionalities (N, O, or S) at the molecular level into the organic skeleton of porous framework materials endowed them with superior CO2 adsorbents to mitigate greenhouse gases. In this work, we have successfully introduced triazine–thiophene (Tt) groups to the nanoporous organic polymer (POP) skeleton by Friedel–Craft alkylation of Tt (as a monomer) with a series of cross-linking agents including formaldehyde dimethyl acetal, 1,4-bis(bromomethyl)benzene (BMB), and 4,4′-bis(bromomethyl)biphenyl, which contained methylene, bis-methylene benzene, and bis-methylene biphenyl moieties in each linker unit, respectively. The precise skeleton engineering with the variation of organic cross-linking agents at the molecular level leads to the development of Tt-POP-1, Tt-POP-2, and Tt-POP-3, having nanorod-, nanocoral-, and nanocloud-like morphologies, respectively. In particular, at 273 K, Tt-POP- 1, Tt-POP- 2, and Tt-POP-3 exhibited CO2 uptake capacities of about 33.04, 40.06, and 34.12 cm3/g, respectively, up to 1 bar pressure. Interestingly, Tt-POP-2 bearing a BMB linker exhibited enhanced CO2 uptake capacity both at 298 and 273 K in comparison with the other Tt-POP-1 and Tt-POP-3, respectively. An in-depth study of the CO2 adsorption mechanism by density functional theory calculations showed that the benzyl rings of linker units in Tt-POP-2 and Tt-POP-3 play a pivotal role in CO2 uptake. The more polarized interaction of CO2 with the thiophenyl and benzyl rings compared to the N and S atoms in Tt-POP-2 results in enhanced CO2 uptake capacity with respect to the others.

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Section: Resultsmentioning

confidence: 95%

Section: ■ Introductionmentioning

confidence: 99%

Nanospace Engineering of Triazine−Thiophene-Intertwined Porous-Organic-Polymers via Molecular Expansion in Tweaking CO₂ Capture

Das

Paul

Dao

et al. 2022

ACS Appl. Nano Mater.

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“…Generally, a suitable pore structure and surface functional groups of adsorbents can promote the adsorption performance of CO 2 . For instance, researchers 99 have reported that narrow micropore size (0.8 nm) is the key factor for CO 2 adsorption. In addition, pore volume are the key factors for CO 2 adsorption.…”

Section: Polymeric Membranesmentioning

confidence: 99%

The use of electrospun nanofibers for absorption and separation of carbon dioxide: A review

Shaki

2023

Journal of Industrial Textiles

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Air pollution as a result of industrialization is a serious problem in many developed and developing countries. Gaseous nitrogen oxides (NOx) and sulfur oxides (SOx) produced primarily due to the coal combustion process and automobiles, cause severe environmental problems such as acid rain, smog, ground level ozone etc. These have far reaching consequences on the ecosystem and in many cases direct toxicology effects on humans. Greenhouse gases such as carbon dioxide (CO2), methane (CH4) are another important class of air pollutants, which are widely regarded to be responsible for the global warming effect. Nanofibers could play an important role as gas sensors for the detection of acceptable emission limits for a variety of gases. Various methods have been proposed for carbon dioxide separation and eventual storage. Ideal materials for carbon dioxide capture and separation must have a porous structure, good strength and stability, and an environmentally friendly manufacturing process. In this regard, electrospun polymer nanofibers are among the ideal materials for carbon dioxide separation. Today, due to the appropriate physical structure and easy and cost-effective manufacturing method, electrospun polymer nanofibers have received more attention from scientists. In recent years, the use of polymer nanofibers has been identified as a high-efficiency method for the separation of gaseous pollutants, including carbon dioxide, from gaseous streams. In this review article, an attempt has been made to investigate the separation of CO2 gas from air using various methods, including the membrane separation method. The recent progress in the design and fabrication of electrospun nanofibers for chemical separation reviews. Also, the different CO2 capture mechanisms including electrostatic, affinity, covalent bonding, chelation, and magnetic adsorption by adsorbents, solvents, and membranes are explained

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“…Similar way, CO 2 adsorption by activated carbon nanofibers prepared from PAN, PVDF, and melamine was reported by a number of authors with adsorption in the range 0.55-3.47 mmol g À1 at 25 °C. Shi et al [95][96][97][98][99][100] studied acetone and CO 2 adsorption properties of porous carbon nanofibers prepared from PAN and reported acetone adsorption capacity of 955.74 mg g À1 and CO 2 adsorption of 3.34 mmol g À1 at 25 °C. Storage of hydrogen gas by electrospun nanofibers, being the main focus of this paper, is presented below in separate sections.…”

Section: Adsorption Of Methane Carbon Dioxide Acetone and Other Gases...mentioning

confidence: 99%

Hydrogen Production, Purification, Storage, Transportation, and Their Applications: A Review

2023

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The world is looking for clean and green energy as substitution for fossil fuels to minimize the greenhouse effect and climate changes threatening our existence. Solar energy, wind energy, and hydrogen gas‐based energy are few examples of promising sources of energy alternatives to fossil fuels. Hydrogen gas‐based energy is in focus today due to its availability in plenty of combined forms such as water, hydrocarbons, natural gases, etc. However, its storage and transportation are major challenges due to the low volumetric density and explosive nature of hydrogen. The scientific community is in search of suitable, economically viable, and energy‐efficient storage systems and transportation of hydrogen gas. Based on numerous studies, surface adsorption of hydrogen by high surface area nanoporous solids such as carbon and metal–organic framework (MOF)‐based nanofiber materials are most suitable for storage applications. Electrospinning process provides a gateway for the preparation of lightweight, highly porous nanofibers for efficient hydrogen adsorption. Herein, the production and use of electrospun polymer nanofibers and MOFs for the storage and transportation of hydrogen are presented.

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Porous Carbon Nanofibers with Heteroatoms Doped by Electrospinning Exhibit Excellent Acetone and Carbon Dioxide Adsorption Performance: The Contributions of Pore Structure and Functional Groups

Cited by 9 publications

References 56 publications

Nanospace Engineering of Triazine−Thiophene-Intertwined Porous-Organic-Polymers via Molecular Expansion in Tweaking CO₂ Capture

Nanospace Engineering of Triazine−Thiophene-Intertwined Porous-Organic-Polymers via Molecular Expansion in Tweaking CO₂ Capture

The use of electrospun nanofibers for absorption and separation of carbon dioxide: A review

Hydrogen Production, Purification, Storage, Transportation, and Their Applications: A Review

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Porous Carbon Nanofibers with Heteroatoms Doped by Electrospinning Exhibit Excellent Acetone and Carbon Dioxide Adsorption Performance: The Contributions of Pore Structure and Functional Groups

Cited by 9 publications

References 56 publications

Nanospace Engineering of Triazine−Thiophene-Intertwined Porous-Organic-Polymers via Molecular Expansion in Tweaking CO2 Capture

Nanospace Engineering of Triazine−Thiophene-Intertwined Porous-Organic-Polymers via Molecular Expansion in Tweaking CO2 Capture

The use of electrospun nanofibers for absorption and separation of carbon dioxide: A review

Hydrogen Production, Purification, Storage, Transportation, and Their Applications: A Review

Contact Info

Product

Resources

About

Nanospace Engineering of Triazine−Thiophene-Intertwined Porous-Organic-Polymers via Molecular Expansion in Tweaking CO₂ Capture

Nanospace Engineering of Triazine−Thiophene-Intertwined Porous-Organic-Polymers via Molecular Expansion in Tweaking CO₂ Capture