边界对石墨烯量子点非线性光学性质的影响

李海鹏; 周佳升; 吉炜; 杨自强; 丁慧敏; 张子韬; 沈晓鹏; 韩奎

doi:10.7498/aps.70.20201643

摘要

石墨烯作为一种新型非线性光学材料, 在光子学领域具有重要的应用前景, 引起研究人员的极大兴趣. 本文运用量子化学计算方法研究了边界引入碳碳双键(C=C)和掺杂环硼氮烷(B₃N₃)环对石墨烯量子点非线性光学性质和紫外-可见吸收光谱的影响. 研究发现, 扶手椅边界上引入C=C双键后, 六角形石墨烯量子点分子结构对称性降低, 电荷分布对称性发生破缺, 导致分子二阶非线性光学活性增强. 石墨烯量子点在从扶手椅型边界向锯齿型边界过渡的过程中, 随着边界C=C双键数目的增加, 六角形石墨烯量子点和B₃N₃掺杂六角形石墨烯量子点的极化率和第二超极化率分别呈线性增加. 此外, 边界对石墨烯量子点的吸收光谱也有重要影响. 无论是石墨烯量子点还是B₃N₃掺杂石墨烯量子点, 扶手椅型边界上引入C=C双键导致最高占据分子轨道能级升高, 最低未占分子轨道能级的降低, 前线分子轨道能级差减小, 因而最大吸收波长发生了红移. 中心掺杂B₃N₃环后会增大石墨烯量子点的分子前线轨道能级差, 导致B₃N₃掺杂后的石墨烯量子点紫外-可见吸收光谱发生蓝移. 本文研究为边界修饰调控石墨烯量子点非线性光学响应提供了一定的理论指导.

关键词:

Abstract

Graphene is a two-dimensional material with single-layer honeycomb lattice structure formed by sp² hybrid connection of carbon atoms. Graphene has excellent optical, electrical, thermal and mechanical properties, and it is considered to be an ideal material for future flexible optoelectronic devices. In recent years, the nonlinear optical properties and regulation of graphene nanostructures have attracted experimental and theoretical interest. Graphene has good delocalization of π-electrons and its unique plane structure, showing good nonlinear optical properties. Graphene quantum dots can be regarded as small graphene nanoflakes. Their unique electronic structure is closely related to the non-bond orbitals on the boundary/edge. Therefore, it is very important to study the boundary/edge effect on the electronic and optical properties of nanographene. In this paper, effects of the number of edge C=C double bonds and Borazine (B₃N₃) doping on the nonlinear optical properties and UV-Vis absorption spectrum of graphene quantum dots are studied by the quantum chemical calculation methods, respectively. It is found that the symmetry of hexagonal graphene quantum dots decreases and the symmetry of charge distribution is broken when C=C double bond is introduced into the armchair edge, which leads the second-order nonlinear optical activity to be enhanced. During the transition from armchair to zigzag edge, the polarizability and the second hyperpolarizability of hexagonal graphene quantum dots and B₃N₃-doped graphene quantum dots increase linearly with the number of introduced C=C double bonds incrrasing. In addition, the edge also has an important influence on the absorption spectrum of graphene quantum dots. For graphene quantum dots and B₃N₃-doped graphene quantum dots, the introduction of C=C double bond at the armchair edge increases the highest occupied molecular orbital energy level and also reduces the lowest unoccupied molecular orbital energy level, which reduces the energy gap between the frontier molecular orbitals, and thus resulting in the red-shift of the maximum absorption wavelength. The doping of B₃N₃ ring will increase the energy gap between molecular frontier orbitals of graphene quantum dots, leading the UV-Vis absorption spectrum of graphene quantum dots to be blue-shifted. This study provides theoretical guidance for controlling the nonlinear optical response of graphene quantum dots by edge modification.

Keywords:

作者及机构信息

中国矿业大学材料与物理学院, 徐州　221116

通信作者: 李海鹏, haipli@cumt.edu.cn

基金项目: 国家自然科学基金(批准号: 11504418)和中央高校基本科研业务费项目(批准号: 2019ZDPY16)资助的课题

Authors and contacts

School of Materials Science and Physics, China University of Mining and Technology, Xuzhou 221116, China

Corresponding author: Li Hai-Peng, haipli@cumt.edu.cn

Funds: Project supported by the National Natural Science Foundation of China (Grant No. 11504418) and the Fundamental Research Funds for the Central Universities of China (Grant No. 2019ZDPY16)

文章全文 : translate this paragraph

参考文献

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施引文献

图 1 石墨烯量子点和B₃N₃掺杂石墨烯量子点的结构

Fig. 1. Structures of graphene quantum dots and B₃N₃-doped graphene quantum dots.

下载: 全尺寸图片幻灯片

图 2 GQD-n和B₃N₃-GQD-n的极化率α

Fig. 2. The polarizabilities α of GQD-n and B₃N₃ -GQD-n.

下载: 全尺寸图片幻灯片

图 3 GQD-n和B₃N₃-GQD-n的第二超极化率γ

Fig. 3. The second hyperpolarizabilities γ of GQD-n and B₃N₃-GQD-n.

下载: 全尺寸图片幻灯片

图 4 GQD-0, GQD-6, B₃N₃-GQD-0和B₃N₃-GQD-6的紫外-可见吸收光谱

Fig. 4. Ultraviolet-visible absorption spectra of GQD-0, GQD-6, B₃N₃-GQD-0 and B₃N₃-GQD-6.

下载: 全尺寸图片幻灯片

表 1 GQD-n和B₃N₃-GQD-n的极化率α、第一超极化率β和第二超极化率γ计算值

Table 1. Calculated polarizability α, first hyperpolarizability β, second hyperpolarizability γ of GQD-n and B₃N₃-GQD-n.

分子	α/(10^–39 C²·m²·J^–1)	β/(10^–51 C³·m³·J^–2)	γ/(10^–59 C⁴·m⁴·J^–3)
GQD-0	8.856	0	1.807
GQD-1	9.455	4.167	2.069
GQD-2	10.070	4.630	2.312
GQD-3	10.666	7.037	2.521
GQD-4	11.298	8.505	2.875
GQD-5	11.928	2.332	3.185
GQD-6	12.549	0	3.380
B₃N₃-GQD-0	8.206	0	1.381
B₃N₃-GQD-1	8.803	3.871	1.735
B₃N₃-GQD-2	9.413	0.330	2.011
B₃N₃-GQD-3	10.019	10.875	2.310
B₃N₃-GQD-4	10.629	6.387	2.689
B₃N₃-GQD-5	11.259	9.293	3.157
B₃N₃-GQD-6	11.883	0	3.446

下载: 导出CSV

表 2 GQD-n和B₃N₃-GQD-n的HOMO能级、LUMO能级、HOMO-LUMO能级差(HLG)和最大吸收波长λ_max计算值

Table 2. Calculated HOMO energy level, LUMO energy level, HOMO-LUMO energy gap (HLG) and maximum absorption wavelength λ_max of GQD-n and B₃N₃-GQD-n.

分子	HOMO/eV	LUMO/eV	HLG/eV	λ_max/nm
GQD-0	–6.606	–0.995	5.611	308.6
GQD-1	–6.324	–1.287	5.037	316.7
GQD-2	–6.203	–1.419	4.784	334.1
GQD-3	–6.266	–1.387	4.878	353.3
GQD-4	–6.078	–1.584	4.493	355.1
GQD-5	–6.038	–1.627	4.411	354.8
GQD-6	–6.126	–1.554	4.572	365.3
B₃N₃-GQD-0	–6.982	–0.778	6.204	254.6
B₃N₃-GQD-1	–6.594	–0.987	5.607	253.4
B₃N₃-GQD-2	–6.593	–1.227	5.366	256.9
B₃N₃-GQD-3	–6.403	–1.207	5.196	252.2
B₃N₃-GQD-4	–6.443	–1.398	5.044	263.6
B₃N₃-GQD-5	–6.273	–1.370	4.903	268.4
B₃N₃-GQD-6	–6.348	–1.307	5.041	320.6

下载: 导出CSV

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[2]	Li H, Yu X, Shen X, Tang G, Han K 2019 J. Phys. Chem. C 123 20020 Google Scholar
[3]	吴晨晨, 郭相东, 胡海, 杨晓霞, 戴庆 2019 物理学报 68 148103 Google Scholar Wu C C, Guo X D, Hu H, Yang X X, Dai Q 2019 Acta Phys. Sin. 68 148103 Google Scholar
[4]	白家豪, 郭建刚 2020 物理学报 69 056201 Google Scholar Bai J H, Guo J G 2020 Acta Phys. Sin. 69 056201 Google Scholar
[5]	Guo Z, Zhang D, Gong X G 2009 Appl. Phys. Lett. 95 163103 Google Scholar
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