关于石墨烯、碳化硅、氮化硼和氮化铝纳米片作为钠离子电池阳极的密度泛函理论研究。

A DFT study on graphene, SiC, BN, and AlN nanosheets as anodes in Na-ion batteries.

作者信息

Hosseinian A, Khosroshahi E Saedi, Nejati K, Edjlali E, Vessally E

机构信息

Department of Engineering Science, College of Engineering, University of Tehran, P.O. Box 11365-4563, Tehran, Iran.

Department of Chemistry, Tabriz Branch, Islamic Azad University, Tabriz, Iran.

出版信息

J Mol Model. 2017 Nov 25;23(12):354. doi: 10.1007/s00894-017-3527-1.

DOI:10.1007/s00894-017-3527-1

PMID:29177629

Abstract

A great concern exists about the lifetime, cost, low-temperature performance, and safety of Li-ion batteries. Na-ion batteries (NIB) are an alternative to the Li-ion batteries due to the wide availability of sodium, its low cost, and nontoxicity. Here, we examined the Na and Na adsorption on nanosheets of carbon (graphene), AlN, BN, and SiC to explore their potential use as an anode in NIBs. The interaction of atomic Na was found to play the main role in producing different nanosheet cell voltages. Unlike the graphene and SiC nanosheets, the lone pairs on the surface of the AlN and BN nanosheets hinder the Na adsorption and significantly increase the cell voltage. The order of magnitude of the nanosheet cell voltage as an anode in NIBs is as follows: AlN (1.49 V) > BN (1.46 V) > > C (0.69 V) > SiC (0.61 V). The AlN and BN nanosheets may be appropriate compounds for NIBs and their cell voltages are comparable with carbon nanotubes.

摘要

人们对锂离子电池的寿命、成本、低温性能和安全性极为关注。由于钠资源丰富、成本低廉且无毒，钠离子电池（NIB）成为了锂离子电池的一种替代选择。在此，我们研究了钠和钠在碳（石墨烯）、氮化铝、氮化硼和碳化硅纳米片上的吸附情况，以探索它们作为钠离子电池阳极的潜在用途。发现原子钠的相互作用在产生不同的纳米片电池电压中起主要作用。与石墨烯和碳化硅纳米片不同，氮化铝和氮化硼纳米片表面的孤对电子阻碍了钠的吸附，并显著提高了电池电压。作为钠离子电池阳极时，纳米片电池电压的量级如下：氮化铝（1.49 V）＞氮化硼（1.46 V）＞＞碳（0.69 V）＞碳化硅（0.61 V）。氮化铝和氮化硼纳米片可能是适用于钠离子电池的化合物，并且它们的电池电压与碳纳米管相当。

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关于石墨烯、碳化硅、氮化硼和氮化铝纳米片作为钠离子电池阳极的密度泛函理论研究。

A DFT study on graphene, SiC, BN, and AlN nanosheets as anodes in Na-ion batteries.

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