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二维量子片及其光学研究进展

陈哲学 王卫彪 梁程 张勇

陈哲学, 王卫彪, 梁程, 张勇. 二维量子片及其光学研究进展[J]. 中国光学(中英文), 2021, 14(1): 1-17. doi: 10.37188/CO.2020-0176
引用本文: 陈哲学, 王卫彪, 梁程, 张勇. 二维量子片及其光学研究进展[J]. 中国光学(中英文), 2021, 14(1): 1-17. doi: 10.37188/CO.2020-0176
CHEN Zhe-xue, WANG Wei-biao, LIANG Cheng, ZHANG Yong. Progress on two-dimensional quantum sheets and their optics[J]. Chinese Optics, 2021, 14(1): 1-17. doi: 10.37188/CO.2020-0176
Citation: CHEN Zhe-xue, WANG Wei-biao, LIANG Cheng, ZHANG Yong. Progress on two-dimensional quantum sheets and their optics[J]. Chinese Optics, 2021, 14(1): 1-17. doi: 10.37188/CO.2020-0176

二维量子片及其光学研究进展

doi: 10.37188/CO.2020-0176
基金项目: 中国科学院战略性先导科技专项(No. XDB36000000);国家重点研发计划(No. 2018YFA0703700);国家自然科学基金(No. 61575049);中国科学院“百人计划”项目;国家纳米科学中心启动基金
详细信息
    作者简介:

    陈哲学(1995—),男,江西九江人,中国科学院大学博士研究生,2018年于合肥工业大学获得学士学位,主要从事等离激元、二维材料等方面的研究。Email:chenzx2018@nanoctr.cn

    王卫彪(1993—),男,河南濮阳人,中国科学院大学硕士研究生,2018年于青岛科技大学获得学士学位,主要从事二维材料等方面的研究。Email:wangwb2019@nanoctr.cn

    梁 程(1993—),男,广西防城港人,硕士,2020年于中国科学院大学获得硕士学位,主要从事二维纳米材料的可控制备等方面的研究。Email:liangch@nanoctr.cn

    张 勇(1978—),男,河北定州人,博士,国家纳米科学中心研究员,博士生导师,主要从事低维纳米材料,薄膜材料,以及高分子复合材料的研究。Email:zhangyong@nanoctr.cn

  • 中图分类号: TB34; O482.3

Progress on two-dimensional quantum sheets and their optics

Funds: Supported by the Strategic Priority Research Program of Chinese Academy of Sciences (No. XDB36000000), National Key R&D Program of China (No. 2018YFA0703700), National Natural Science Foundation of China (No. 61575049), 100-Talent Program of Chinese Academy of Sciences, Start-Up Funding from National Center for Nanoscience and Technology
More Information
  • 摘要: 以石墨烯为代表的二维材料因其独特的结构和优异性能而受到广泛关注。随着二维材料在无限小的方向不断发展,二维(材料)量子片逐渐引起人们极大的兴趣。二维量子片不仅保留了二维材料的本征特性,而且表现出量子限域和突出的边缘效应,为二维材料的潜在应用带来全新机遇。本文详细介绍了二维量子片的基本概念,制备现状与光学性能的研究进展,特别强调了二维量子片本征、普适和规模制备的实现及其重大意义。此外,重点关注了二维量子片的光致发光特性以及在非线性光学、固态发光器件等领域的应用。最后,分析了二维量子片的发展趋势以及面临的主要挑战。

     

  • 图 1  (a)量子片所处体系的示意图[31];(b)二维量子片的文章发表数目(2007—2016)[4];(c)二维量子片的应用领域:医药[24],生物成像[25],催化[26],太阳能电池[27],非线性光学[28]等。(b)转载自文献[4],版权所有(2018)皇家化学学会。(c) 转载自文献[24],版权所有(2018)施普林格;转载自文献[25],版权所有(2018)施普林格;转载自文献[26],版权所有(2016)自然出版集团;转载自文献[27],版权所有(2018)施普林格;转载自文献[28],版权所有(2020)美国化学学会

    Figure 1.  (a) Schematic diagram of the system in which the quantum sheet is located[31];(b) number of journal publications on 2D QSs from 2007 to 2016[4];(c) application fields of 2D QSs:medicine[24], biological imaging[25],catalysis[26],solar cell[27],nonlinear optics[28],etc. (b) Adapted with permission ref. [4]. Copyright 2018, Royal Society of Chemistry; (c) Reproduced with permission ref. [24]. Copyright 2018, Springer. Reproduced with permission ref. [25]. Copyright 2018, Springer; Reproduced with permission ref. [26]. Copyright 2016, Nature Publishing Group; Reproduced with permission ref. [27]. Copyright 2018, Springer; Reproduced with permission ref. [28]. Copyright 2020, American Chemical Society.

    图 2  二维材料的原子结构。(a)石墨烯[3];(b)氮化硼[3];(c)二硫化钼[48];(d)硒化铟[49];(e)氮化碳[50];(f)黑磷[41]。(a) 和(b)转载自文献[3],版权所有(2017)美国化学学会;(c) 转载自文献[48],版权所有(2011)自然出版集团;(d) 转载自文献[49],版权所有(2017)自然出版集团;(e) 转载自文献[50],版权所有(2017)皇家化学学会;(f) 转载自文献[41],版权所有(2014)自然出版集团

    Figure 2.  Atomic structures of 2D materials. (a) Graphene[3]; (b) BN[3]; (c) MoS2[48]; (d) InSe[49]; (e) C3N4[50]; (f) BP[41]. (a) and (b) Adapted with permission ref. [3]. Copyright 2017, American Chemical Society. (c) Adapted with permission ref. [48]. Copyright 2011, Nature Publishing Group. (d) Adapted with permission ref. [49]. Copyright 2017, Nature Publishing Group. (e) Adapted with permission ref. [50]. Copyright 2017, Royal Society of Chemistry. (f) Adapted with permission ref. [41]. Copyright 2014, Nature Publishing Group.

    图 3  二维量子片的制备方法。自下而上:(a)化学气相沉积[66];(b)湿化学法[35]。自上而下:(c)电化学剥离[54];(d)研磨结合超声剥离[62];(e)液氮预处理和超声剥离[57];(f)回流预处理和超声剥离[63];(g)超薄切片结合液相剥离[59]。(a) 转载自文献[66],版权所有(2016)美国化学学会;(b)转载自文献[35],版权所有(2019)自然出版集团;(c) 转载自文献[54],版权所有(2015)皇家化学学会。(d) 转载自文献[62],版权所有(2015)威立出版集团;(e)转载自文献[57],版权所有(2017)美国科学促进会;(f)转载自文献[63],版权所有(2019)爱思唯尔;(g)转载自文献[59],版权所有(2020)施普林格

    Figure 3.  The preparation methods of 2D QSs. Bottom-up: (a) CVD [66]; (b) wet chemical method[35]. Top-down: (c) electrochemical exfoliation[54]; (d) grinding combined with sonication exfoliation[62]; (e) liquid nitrogen pretreatment combined with sonication exfoliation[57]; (f) reflux pretreatment combined with sonication exfoliation[63]; (g) ultrathin section combined with liquid phase dissection[59]. (a) Reproduced with permission ref. [66]. Copyright 2016, American Chemical Society; (b) adapted with permission ref. [35]. Copyright 2019, Nature Publishing Group; (c) reproduced with permission ref. [54]. Copyright 2015, Royal Society of Chemistry; (d) reproduced with permission ref. [62]. Copyright 2015, Wiley-VCH; (e) reproduced with permission ref. [57]. Copyright 2017, AAAS; (f) adapted with permission ref. [63]. Copyright 2019, Elsevier; (g) reproduced with permission ref. [59]. Copyright 2020, Springer.

    图 4  二维量子片的本征、普适和规模制备。(a)盐辅助球磨和超声辅助溶剂剥离[60];(b)量子片的制备机理示意图[60];(c)硅球辅助球磨和超声辅助溶剂剥离[23];(d)量子片分散液和粉体照片及对应的高分辨透射电镜照片[23];(e)从多壁碳纳米管制备石墨烯量子片[64]。(a-b)转载自文献[60],版权所有(2017)美国化学学会;(c-d)转载自文献[23],版权所有(2019)皇家化学学会;(e)转载自文献[64],版权所有(2020)美国化学学会

    Figure 4.  Universal and scalable production of intrinsic 2D QSs. (a) Salt-assisted ball-milling and sonication-assisted solvent exfoliation[60]; (b) schematic diagram of the fabrication mechanism of 2D QSs[60]; (c) silica-assisted ball-milling and sonication-assisted solvent exfoliation[23]; (d) photographs of the QS dispersions and powders and their HRTEM images; (e) robust strategy for tailoring multi-walled carbon nanotubes into GQSs[64]. (a-b) Reproduced with permission ref. [60]. Copyright 2017, American Chemical Society; (c-d) Reproduced with permission ref. [23]. Copyright 2019, Royal Society of Chemistry; (e) Reproduced with permission ref. [64]. Copyright 2020, American Chemical Society.

    图 5  二维量子片的光致发光性能。(a)发射波长(nm)对GQSs尺寸的依赖关系[74];(b)不同尺寸石墨烯量子片的颜色变化[75];(c)元素掺杂的影响[80];(d-f)激发波长依赖性[23];(g)浓度依赖性[23];(h)溶剂依赖性[23];(i)固态荧光性能[23]。 (a) 转载自文献[74],版权所有(2015)皇家化学学会;(b) 转载自文献[75],版权所有(2014)美国化学学会;(c) 转载自文献[80],版权所有(2014)威立出版集团;(d-i)转载自文献[23],版权所有(2019)皇家化学学会

    Figure 5.  Photoluminescence of 2D QSs. (a) Dependence of emission wavelength (nm) on the size of GQSs[74]; (b) color changes of GQSs with different sizes[75]; (c) effects of elemental doping[80]; (d-f) excitation wavelength dependence[23]; (g) concentration dependence[23]; (h) solvent dependence[23]; (i) solid-state fluorescence[23]. (a) Reproduced with permission ref. [74]. Copyright 2015, Royal Society of Chemistry. (b) Adapted with permission ref. [75]. Copyright 2014, American Chemical Society. (c) Reproduced with permission ref. [80]. Copyright 2014, Wiley-VCH. (d-i) Reproduced with permission ref. [23]. Copyright 2019, Royal Society of Chemistry.

    图 6  二维量子片在非线性光学中的应用。(a)等离激元增强石墨烯量子片二阶非线性效应[89];(b)黑磷量子片的三阶非线性效应[94];(c)锑烯量子片的光学克尔效应[96];(d)N掺杂的石墨烯量子片的非线性生物成像[87];(e)量子片-PMMA复合薄膜的非线性饱和吸收性能[23]。(a) 转载自文献[89],版权所有(2015)美国化学学会;(b)转载自文献[94],版权所有(2016)威立出版集团;(c) 转载自文献[96],版权所有(2017)威立出版集团;(d)转载自文献[87],版权所有(2013)美国化学学会;(e)转载自文献[23],版权所有(2019)皇家化学学会

    Figure 6.  Application of 2D QSs in nonlinear optics.(a)Plasmon-enhanced GQSs second-order nonlinearity[89];(b)third-order nonlinearity of BPQSs[94];(c)Kerr effect of AQSs[96];(d)nonlinear biological imaging of N-GQSs[87];(e)nonlinear saturation absorption of QSs-PMMA hybrid films[23]. (a) Reproduced with permission ref. [89]. Copyright 2015, American Chemical Society. (b) Reproduced with permission ref. [94]. Copyright 2016, Wiley-VCH. (c) Reproduced with permission ref. [96]. Copyright 2017, Wiley-VCH.(d)Reproduced with permission ref. [87]. Copyright 2013, American Chemical Society.(e)Reproduced with permission ref. [23]. Copyright 2019, Royal Society of Chemistry.

    图 7  二维量子片在固态发光器件中的应用情况。(a)基于GQSs的垂直腔面发射激光器[104];(b)基于V2C MXene量子片的白色激光器[110];(c)基于MoS2 QSs的可拉伸和宽带无腔激光器[106];(d)基于MoS2 QSs(组氨酸掺杂)的白色发光二极管[112]。(a) 转载自文献[104],版权所有(2019)美国化学学会;(b) 转载自文献[110],版权所有(2019)威立出版集团;(c) 转载自文献[106],版权所有(2020)威立出版集团; (d) 转载自文献[112],版权所有(2019)威立出版集团

    Figure 7.  Applications of 2D QSs in solid-state light emitting device. (a) Vertical cavity surface-emitting lasers based on GQSs[104];(b)white lasers with V2C MXene quantum sheets (MQSs)[110]; (c) stretchable and broadband cavity-free laser devices based on MoS2 QSs[106]; (d) white-light-emitting diodes based on histidine-doped MoS2 QSs[112]. (a) Reproduced with permission ref. [104]. Copyright 2019, American Chemical Society. (b) Reproduced with permission ref. [110]. Copyright 2019, Wiley-VCH. (c) Reproduced with permission ref. [106]. Copyright 2020, Wiley-VCH. (d) Reproduced with permission ref. [112]. Copyright 2019, Wiley-VCH.

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  • 收稿日期:  2020-09-30
  • 修回日期:  2020-11-09
  • 网络出版日期:  2021-01-14
  • 刊出日期:  2021-01-25

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