Density Functional Theory studies the interaction of neopentane with functionalized porous graphene-Reference-Cited by-同舟云学术

Density Functional Theory studies the interaction of neopentane with functionalized porous graphene

Published:2024-07-05 Issue: Volume: Page:
ISSN:
Container-title:
language:
Short-container-title:

Author:

Zhang Liying¹,Yan Wenda¹,He Dongning¹,Fang Yong²

Affiliation:

1. Lingnan Normal University

2. Sichuan University of Science & Engineering

Abstract

Porous graphenes are one of the ideal separation materials. The interaction between neopentane molecule and chemical groups N-, F- and OH- functionalized single-layer porous graphene model (pore16) was investigated by using first-principles method. The pore size of Pore16 modified by one N atom is almost the same (the difference is only 0.006 Å), while the difference of the energy barrier to neopentane is as high as 0.30 eV. For 2Npore16, the energy barrier varies by 0.88eV, while for 4Npore16, it varies by 0.67eV. It is evident that as the number of N atoms increases, the energy barrier widens, and this phenomenon is also found in the functionalization of F and OH. The same type and number of functional groups may have different pore sizes, which may result in very different separation properties. Interestingly, adding functionalization leads to the formation of hydrogen bonds in OHpore16, which affects the separation performance of molecule. This implies that not only pore size and shape are the main factors, but also the chemical functionalization of specific sites is the main factor. In general, this study emphasizes an important attraction might be encountered in both the design and modeling of two-dimensional membranes for separating purposes.

Publisher

Springer Science and Business Media LLC

Reference37 articles.

1. Uniyal S, Choudhary K, Sachdev S, Kumar S (2024) Nano-biofusion: advancing biomedical applications and biosensing with functional nanomaterials. Opt Laser Technol. 168: 109938. https://doi.10.1016/j. optlastec.2023.109938

2. Zhou N, Qin Y, Liu W, Wu X, Cheng J (2022) Density functional theory investigation of Cs, Co and Ag separation by functionalised graphene membrane.Mol. Phys. 120: 23. https://doi.10.1080/

3. 2022.2137067 3, Li H, Xiang J, Chen L, Xu J, Liu W Dense arrangement of crown ethers in graphene: novel graphitic carbon oxides with enhanced optoelectronic properties.Phys Chem Chem Phys. 26:1428–1435. https://doi.10.1039/d3cp03902a., 4 Anshori I, Kepakisan KAA, Nuraviana Rizalputri L (2024) (2022) Facile synthesis of graphene oxide/Fe3O4 nanocomposite for electrochemical sensing on determination of dopamine. Nanocomposites. 8:155–166. https://doi.10.1080/20550324.2022.2090050. 5 Bunch JS, Vebridge S S, Alden JS, van der zande A M (2008) Impermeable atomic members from graphene sheets. Nano. Lett. 8: 2458–2462. https://doi.10.1021/nl801457b 6 Schrier J (2010) Helium separation using porous graphene members. J. Phy. Chem. Lett. 1: 2284–2287. https://doi.10.1021/jz100748x 7 Guirguis A, Maina JW, Kong L, Henderson LC, Rana A, Li LH, Majumder M, Dumée LF (2019) Perforation routes towards practical nano-porous graphene and analogous materials engineering. Carbon. 155: 660–673. https://doi.10.1016/j.carbon.09.028. 8 Gu Y, Qiu Z, Mullen K (2022) Nanographenes and graphene nanoribbons as multitalents of present and future materials science. J Am Chem Soc. 144:11499–11524. https://doi.10.1021/jacs.2c02491. 9 Son JG, Son M, Moon KJ, Lee BH, Myoung JM, Strano MS, Ham MH, Ross CA (2013) Sub-10 nm graphene nanoribbon array field-effect transistors fabricated by block copolymer lithography. Adv Mater. 25: 4723–4728. https://doi.10.1002/adma.201300813. 10 Verschueren DV, Yang W, Dekker C (2018) Lithography-based fabrication of nanopore arrays in freestanding SiN and graphene membranes. Nanotechnology. 29: 145302. https://doi.10.1088 /1361–6528/aaabce

4. Pourmand S, Abdouss M, Rashidi A (2015) Fabrication of nanoporous graphene by chemical vapor deposition (CVD) and its application in oil spill removal as a recyclable nanosorbent. J Ind Eng Chem. 22:8–18. https://doi.10.1016/j.jiec.2014.06.018

5. Hu Y, Wu Y, Devendran C, Wei J, Liang Y, Matsukata M, Shen W, Neild A, Huang H, Wang H (2017) Preparation of nanoporous graphene oxide by nanocrystalmasked etching: toward a nacre-mimetic metal–organic framework molecular sieving membrane. J Mater Chem A. 5:16255–16262. https://doi.10.1039/C7TA00927E