Research Progress of Bioinspired Photonic Crystal Fibers

doi:10.6023/A20120556

Acta Chimica Sinica ›› 2021, Vol. 79 ›› Issue (4): 414-429.DOI: 10.6023/A20120556 Previous Articles Next Articles

Review

仿生光子晶体纤维的研究进展

裴广晨^a^,^c, 王京霞^a^,^b^,^c^,^*(), 江雷^a^,^c

a 中国科学院理化技术研究所仿生材料与界面科学重点实验室北京 100190
b 中国科学院大学材料与光电研究中心北京 101407
c 中国科学院大学未来技术学院北京 101407

投稿日期:2020-12-07 发布日期:2021-02-05
通讯作者: 王京霞

作者简介:

裴广晨, 女, 汉族, 中国科学院理化技术研究所硕士, 主要从事光子晶体的制备, 静电纺丝光子晶体纤维的制备及应用性能研究.

王京霞, 女, 中国科学院理化技术研究所研究员, 博士生导师, 中国科学院大学未来技术学院岗位教授. 多年来聚焦在浸润性对光子晶体制备及应用性能研究. 2004年1月毕业于清华大学高分子研究所, 师从刘德山教授. 2004年2月~2006年8月在中国科学院化学所有机固体实验室江雷研究员课题组做博士后研究, 研究方向为聚合物光子晶体浸润性研究. 2006年8月~2014年4月留在中国科学院化学所新材料实验室宋延林研究员课题组任副研究员, 研究方向为聚合物光子晶体的大面积制备及应用. 2014年至今, 调到中国科学院理化所仿生材料与界面科学重点实验室任研究员, 研究方向为特殊浸润性在光子晶体制备及应用中的作用. 目前在包括Chem. Soc. Rev.,Acc. Chem. Res.,J. Am. Chem. Soc.,Adv. Funct. Mater.等国际期刊发表研究论文100余篇, 相关研究成果申请并授权专利50余项. 参与宋延林研究员主持的项目“纳米材料绿色打印印刷基础研究”, 获得2016年北京市科学技术一等奖(第四排名)(No.2016 基-1-001-04).

基金资助:
国家重大研究计划(2016YFA0200803); 国家重大研究计划(2017YFA0204504); 国家重大研究计划(2016YFB0402004); 国家自然科学基金(51673207); 国家自然科学基金(51873221); 国家自然科学基金(52073292); 中科院-荷兰合作项目(1A111KYSB20190072); 北京市科技计划(Z181100004418012)

Research Progress of Bioinspired Photonic Crystal Fibers

Guangchen Pei^a^,^c, Jingxia Wang^a^,^b^,^c^,^*(), Lei Jiang^a^,^c

a Key Laboratory of Bioinspired Materials and Interfaces Sciences, Technical Institute of Physics and Chemistry, Chinese Academy of Sciences, Beijing 100190
b Center of Materials Science and Optoelectronic Engineering, University of Chinese Academy of Sciences, Beijing 101407
c School of Future Technology, University of Chinese Academy of Sciences, Beijing 101407

Received:2020-12-07 Published:2021-02-05
Contact: Jingxia Wang
About author:
* E-mail: jingxiawang@mail.ipc.ac.cn; Tel.: 010-82543510
Supported by:
Ministry of Science and Technology of China(2016YFA0200803); Ministry of Science and Technology of China(2017YFA0204504); Ministry of Science and Technology of China(2016YFB0402004); National Natural Science Foundation of China(51673207); National Natural Science Foundation of China(51873221); National Natural Science Foundation of China(52073292); Chinese Academy of Sciences and Dutch research project(1A111KYSB20190072); Beijing Municipal Science & Technology Commission(Z181100004418012)

Photonic crystal (PC) fibers exist in many creatures in nature, which give them bright structural colors. PC fibers refer to fibers with the PC structure, which have a highly saturated structural color. Traditional chemical dyes in the textile industry are difficult to degrade to produce chemical pollution and waste of water resources. PC fibers with structural colors are of great significance for replacing traditional chemical dyes in the textile industry and have great potential in making wearable smart sensing devices. They can be used to prepare various sensor-responsive PC fibers when combined with responsive materials or flexible substrates. This paper reviews the fabrication methods, performance, applications and other related research works of PC fibers. PC fibers are mainly composed of colloidal microspheres. To show the structure and properties of PCs, the colloidal microsphere units are mixed with fiber materials and arranged in an orderly manner, or are directly assembled to fibrous materials. The fabrication methods of PC fibers mainly include template assembly, electrospinning, microfluidic spinning, extrusion assembly, multilayer crimp assembly, iterative size reduction and fabric assembly method. PC fibers have many excellent properties. For example, PC fibers are superhydrophobic after being stacked and arranged, which are similar to feathers of drakes with self-cleaning effect. The inverse opal PC fibers have high porosity, high specific area and periodic structure, which can greatly improve the application performance. PC fibers or fiber stacked fibrous membranes have a bright structural color, which can be used for the fabrication of various responsive PC fibers, such as strain-, humidity-, photothermal-, solvent-, and magnetic-response fiber, which are of great significance to the research and application of wearable smart sensors. Finally, the application prospects of PC fibers in the textile industry and intelligent sensing field are discussed.

Key words: photonic crystal fibers, bioinspired, textile, sensing

Cite this article

Guangchen Pei, Jingxia Wang, Lei Jiang. Research Progress of Bioinspired Photonic Crystal Fibers[J]. Acta Chimica Sinica, 2021, 79(4): 414-429.

Export EndNote|Reference Manager|ProCite|BibTeX|RefWorks

share this article

Fig. & Tab. 16

Figure 1. PC fibers in nature. (A) Edelweiss flower and its surface white filamentary wool[1]. (B) A Saharan silver ant and its triangular hairs[2]. (C) A Margaritaria nobilis fruit and its surface cells[3]. (D) Peacock feathers and barbules[4-5]. (E) Mallard neck feathers and its barbules[8]. (F) Black-billed magpie feathers and barbules[9]

Figure 2. Fabrication of PC fibers by capillary assembly method. (A) Assemble colloidal microspheres on the inner and outer surfaces of capillary and remove the PS colloidal template to obtain hollow or solid PC fibers with inverse opal structure[10-11]. (B) Silica colloidal microspheres were assembled inside the capillary to form PC fibers with structural color striped pattern[12]. (C) An aqueous surfactant is used to extrude the colloidal microsphere dispersion inside the capillary, meanwhile, the silica microspheres self-assemble on the inner wall of the capillary forming PC fibers[13]. (D) The colloidal microspheres inside the capillary self-assemble on the fiber surface by capillary force to form PC fibers[14]. (E) Inverse opal structure carbon fibers were prepared by using capillary[4]

Figure 3. Fabrication of PC fibers by dip-coating method. (A) Colloidal microspheres were assembled on the fiber surface by drawing bare fibers, then opal structure PC fibers were obtained, or then by removing colloidal microspheres and center fibers inverse opal structure PC fibers were obtained[15-16]. (B) The continuous fabrication of PC fibers by drawing the spandex fiber from the colloidal microspheres dispersion using two electric motors[17]

Figure 4. Fabrication of PC fibers by electrophoretic deposition. (A) PS microspheres are deposited on the surface of carbon fibers to obtain structural color PC fibers[18]. (B) PS microspheres are deposited on the surface of graphene fibers to obtain PC fibers with high brightness and saturation structural color[19]. (C) Cylindrical colloidal crystals of 400 nm PS microspheres exhibit a semi-crystalline structure[20]. (D) PC fibers with organic solvent response formed by electrophoretic deposition of PNIPAM-co-AAc hydrogel microspheres on the surface of carbon fibers[21]. (E) A micro-cylindrical system for continuously preparing PC fibers[22]. (F) PC fibers with core-sheath structure assembled by PS microspheres, carbon nanotubes and PDMS[23]. (G) Electrochromic fiber formed by depositing electrochromic material on the surface of stainless steel wire[24]

Figure 5. PC fibers fabricated from magnetic nanoparticles. (A) The magnetic field induced the formation of PC fibers in micro-space[25]. (B) Mechanical strain response PC fibers composed of superparamagnetic colloidal nanocrystal clusters and polyacrylamide[26]. (C) PC fibers with magnetic field response formed by the magnetic nanoparticles present in the droplets of ethylene glycol embedded in PDMS fiber[27]

Figure 6. Fabrication of PC fibers by electrospinning. (A) Schematic diagram and SEM images of PC fibers prepared by electrospinning of PVA dispersion of PS microspheres[32]. (B) Uniform PC fibers are formed by electrospinning PVA dispersion of P(St-MMA-AA). The fibrous membrane exhibits a high-contrast structural color after water treatment[33]. (C) Optical microscopy images of electrospun PC fibers of P(St-MMA-AA) and photos of the electrospun fibrous membrane[34]

Figure 7. Fabrication of PC fiber by microfluidic spinning. (A) Silica PC fibers and PC fiber with humidity response fabricated by microfluidic spinning[36]. (B) Bead-shaped PC fibers fabricated by Rayleigh instability guiding and microfluidic spinning[37]

Figure 8. Fabrication of PC fibers by extrusion assembly. (A) Flexible PC fibers fabricated by extruding PS-ALMA-PEA hard core soft shell microsphere solution using extruder[38]. (B) Freestanding colloidal crystal fibers fabricated by direct-write 3D printing[39]. (C) Fabrication of PC fibers assembled by P(St-DVB)@PDA particles using microfluidic emulsification and solvent diffusion[40]. (D) PC fibers assembled from cellulose nanocrystals fabricated by wet-spinning[41]

Figure 9. Fabrication of PC fibers by multilayer rolling assembly. (A) Multilayer fibers inspired by Margaritaria nobilis fruit[3]. (B) Artificial barbule fabricated by imitating black-billed magpie feather barbules[9]

Figure 10. PC fibers fabricated by iterative size reduction method inspired by mallard drakes neck feathers[8]

Figure 11. PCs assembled by fabrics. (A) Non-iridescent structural color fiber fabrics fabricated by facile spray coating of P(St-MMA-AA) colloidal microsphere[42]. (B) Non-iridescent structural color patterns obtained by using silica microspheres assembled on silk fabrics by atomization deposition[43]. (C) Iridescent structural color patterns on the textile surface fabricated by ink-jet printing technology[44]. (D) Structural color textiles based on PS@PDA melanin-like nanospheres assembled under the action of gravity and capillary force[45]

Figure 12. Optical properties of PC fibers or fibrous membranes. (A) Optical microscope images and reflection spectra of PC fibers fabricated by dip-coating[16]. (B) “Optical switching pattern” was fabricated by electrospinning and hydrothermal. When the light is parallel to the nanofibers, the pattern is almost invisible, and when the light is perpendicular to the nanofiber, the pattern is clearly visible [35]. (C) The PC patterns were fabricated by ink-jet printing of colloidal microsphere ink on fabrics, and the structural color can change with the observation angle[44]. (D) The PC fibrous membrane with non-iridescent structural color fabricated by electrospinning[33], direct-writing structural color patterns on electrospun fibrous membranes[34]. (E) Structural color rose pattern fabricated by depositing colloidal microspheres on the surface of the fabric[43]. (F) Fabrics knitted by cross-linked fibers fabricated by extrusion assembly[38]. (G) Structural color patterns woven from PC fibers fabricated by electrophoretic deposition[23]. (H) A hand chain, fabrics, and color patterns made from PC fibers fabricated by dip-coating[17]

Figure 13. (A) Schematic diagram of supercapacitor based on two inverse opal carbon rods and relative capacitance curve for eye movement monitoring[4]. (B) Reflection spectra and digital photographs of electrochromic fibers under positive and negative voltages[24]

Figure 14. Sensing response performance of PC fibers: photothermal-, strain-, humidity-, solvent-, and magnetic-response

Figure 15. (A) Schematic diagram of the fabrication of the striped structural color fiber with photothermal response and the light-triggered dynamic bending process[12]. (B) The PC fibers with humidity response and its structural color and reflection spectra in different humidity[36]. (C) Schematic diagram of the discoloration mechanism of PC fibers with solvent response and the structural color transition under acetone and ethanol vapor[21]. (D) Reflection spectra and digital photographs of PC fiber with magnetic field response withdrawal/within a magnetic field[27]. (E) Structural color changes images of PC fiber with strain response induced by increasing strain[3]

Figure 16. PC fibrous membrane with superhydrophobicity. (A) Structure and contact angle of mallard neck feathers and superhydrophobicity of PC fibrous membrane[8]. (B) Superhydrophobic fibrous membrane fabricated by electrospinning[31]

References 62

[1]	Kertész, K.; Bálint, Z.; Vértesy, Z.; Márk, G.I.; Lousse, V.; Vigneron, J.P.; Biró, L.P. Curr. Appl. Phys. 2006, 6,252.
[2]	Shi, N.N.; Tsai, C.C.; Camino, F.; Bernard, G.D.; Yu, N.F.; Wehner, R. Science 2015, 349,298.
[3]	Kolle, M.; Lethbridge, A.; Kreysing, M.; Baumberg, J.J.; Aizenberg, J.; Vukusic, P. Adv. Mater. 2013, 25,2239.
[4]	Gao, B.B.; He, Z.Z.; He, B.F.; Gu, Z.Z. Sens. Actuator B Chem. 2019, 288,734.
[5]	Yoshioka, S.; Kinoshita, S. Forma 2002, 17,169.
[6]	Zi, J.; Yu, X.D.; Li, Y.Z.; Hu, X.H.; Xu, C.; Wang, X.J.; Liu, X.H.; Fu, R.T. Proc. Natl. Acad. Sci. U. S. A. 2003, 100,12576.
[7]	Burg, S.L.; Parnell, A.J. J. Phys. Condes. Matter 2018, 30,413001.
[8]	Khudiyev, T.; Dogan, T.; Bayindir, M. Sci. Rep. 2014, 4,4718.
[9]	Han, C.; Kim, H.; Jung, H.; Lee, S.I.; Jablonski, P.G.; Jeon, H. Optica 2017, 4,464.
[10]	Moon, J.H.; Kim, S.; Yi, G.R.; Lee, Y.H.; Yang, S.M. Langmuir 2004, 20,2033.
[11]	Ni, H.B.; Wang, M.; Chen, W. Opt. Express 2011, 19,25900.
[12]	Zhao, Z.; Wang, H.; Shang, L.R.; Yu, Y.R.; Fu, F.F.; Zhao, Y.J.; Gu, Z.Z. Adv. Mater. 2017, 29,1704569.
[13]	Kim, S.H.; Hwang, H.; Yang, S.M. Angew. Chem. Int. Ed. 2012, 51,3601.
[14]	Liu, Z.; Zhang, Q.; Wang, H.; Li, Y. Chem. Commun. 2011, 47,12801.
[15]	Moon, J.H.; Yi, G.R.; Yang, S.M. J. Colloid Interf. Sci. 2005, 287,173.
[16]	Yuan, W.; Li, Q.; Zhou, N.; Zhang, S.; Ding, C.; Shi, L.; Zhang, K.Q. ACS Appl. Mater. Interfaces 2019, 11,19388.
[17]	Zhang, J.; He, S.S.; Liu, L.M.; Guan, G.Z.; Lu, X.; Sun, X.M.; Peng, H.S. J. Mater. Chem. C 2016, 4,2127.
[18]	Zhou, N.; Zhang, A.; Shi, L.; Zhang, K.Q. ACS Macro Lett. 2013, 2,116.
[19]	Meng, J.Y.; Li, X.; Gong, Y.; Wang, R.; Zheng, Y.P.; Zhang, D.Q. Acta Polym. Sin. 2018, (3),389. (in Chinese)
	( 孟佳意, 李昕, 龚龑, 王锐, 郑一平, 张德权, 高分子学报, 2018, (3),389.)
[20]	Lai, C.H.; Yang, Y.L.; Chen, L.Y.; Huang, Y.J.; Chen, J.Y.; Wu, P.W.; Cheng, Y.T.; Huang, Y.T. J. Electrochem. Soc. 2011, 158,37.
[21]	Yuan, X.F.; Liu, Z.F.; Shang, S.L.; Wang, H.Z.; Zhang, Q.H.; Li, Y.G.; Jin, W.S. RSC Adv. 2016, 6,16319.
[22]	Liu, Z.F.; Zhang, Q.H.; Wang, H.Z.; Li, Y.G. Nanoscale 2013, 5,6917.
[23]	Sun, X.; Zhang, J.; Lu, X.; Fang, X.; Peng, H.S. Angew. Chem. Int. Ed. 2015, 54,3630.
[24]	Li, K.; Zhang, Q.; Wang, H.; Li, Y. ACS Appl. Mater. Interfaces 2014, 6,13043.
[25]	Liu, Z.F.; Zhang, Q.H.; Wang, H.Z.; Li, Y.G. J. Colloid Interf. Sci. 2013, 406,18.
[26]	Shang, S.L.; Liu, Z.F.; Zhang, Q.H.; Wang, H.Z.; Li, Y.G. J. Mater. Chem. A 2015, 3,11093.
[27]	Shang, S.L.; Zhang, Q.H.; Wang, H.Z.; Li, Y.G. J. Colloid Interf. Sci. 2016, 483,11.
[28]	Zhang, K.Q.; Yuan, W.; Zhou, N.; Wu, C.J., Electrospun Nanofibers for Energy and Environmental Applications, Eds.: Ding, B.; Yu, J., Springer-Verlag Berlin Heidelberg, 2014, p. 403.
[29]	Wu, C.; Yuan, W.; Al-Deyab, S.S.; Zhang, K.Q. Appl. Surf. Sci. 2014, 313,389.
[30]	Lim, J.M.; Moon, J.H.; Yi, G.R.; Heo, C.J.; Yang, S.M. Langmuir 2006, 22,3445.
[31]	Lim, J.M.; Yi, G.R.; Moon, J.H.; Heo, C.J.; Yang, S.M. Langmuir 2007, 23,7981.
[32]	Yuan, W.; Zhang, K.Q. Langmuir 2012, 28,15418.
[33]	Yuan, W.; Zhou, N.; Shi, L.; Zhang, K.Q. ACS Appl. Mater. Interfaces 2015, 7,14064.
[34]	Yuan, S.J.; Meng, W.H.; Du, A.H.; Cao, X.Y.; Zhao, Y.; Wang, J.X.; Jiang, L. Chinese J. Polym. Sci. 2019, 37,729.
[35]	Kim, G.H.; An, T.; Lim, G. Nanoscale Res. Lett. 2018, 13,204.
[36]	Li, G.X.; Shen, H.X.; Li, Q.; Tian, Y.; Wang, C.F.; Chen, S. Mater. Lett. 2019, 242,179.
[37]	Zhang, Y.; Tian, Y.; Xu, L.L.; Wang, C.F.; Chen, S. Chem. Commun. 2015, 51,17525.
[38]	Finlayson, C.E.; Goddard, C.; Papachristodoulou, E.; Snoswell, D.R. E.; Kontogeorgos, A.; Spahn, P.; Hellmann, G.P.; Hess, O.; Baumberg, J.J. Opt. Express 2011, 19,3144.
[39]	Tan, A.T. L.; Beroz, J.; Kolle, M.; Hart, A.J. Adv. Mater. 2018, 30,e1803620.
[40]	Kohri, M.; Yanagimoto, K.; Kawamura, A.; Hamada, K.; Imai, Y.; Watanabe, T.; Ono, T.; Taniguchi, T.; Kishikawa, K. ACS Appl. Mater. Interfaces 2018, 10,7640.
[41]	Meng, X.; Pan, H.; Lu, T.; Chen, Z.X.; Chen, Y.R.; Zhang, D.; Zhu, S.M. Nanotechnology 2018, 29,325604.
[42]	Zeng, Q.; Ding, C.; Li, Q.S.; Yuan, W.; Peng, Y.; Hu, J.C.; Zhang, K.Q. RSC Adv. 2017, 7,8443.
[43]	Li, Q.S.; Zhang, Y.F; Shi, L.; Qiu, H.H.; Zhang, S.M.; Qi, N.; Hu, J.C.; Yuan, W.; Zhang, X.H.; Zhang, K.Q. ACS Nano 2018, 12,3095.
[44]	Liu, G.J.; Zhou, L.; Zhang, G.Q.; Li, Y.C.; Chai, L.Q.; Fan, Q.G.; Shao, J.Z. Mater. Design 2017, 114,10.
[45]	Wang, X.H.; Li, Y.C.; Zhou, L.; Chai, L.Q.; Fan, Q.G.; Shao, J.Z. Dyes. Pigments 2019, 169,36.
[46]	Shi, X.; He, J.; Wu, L.; Chen, S.; Lu, X. J. Coat. Technol. Res. 2020, 17,1033.
[47]	Liu, G.; Han, P.; Chai, L.; Li, Z.; Zhou, L. Colloid Surf. A-Physicochem. Eng. Asp. 2020, 600,124991.
[48]	Liu, G.; Han, P.; Wu, Y.; Li, H.; Zhou, L. Opt. Mater. 2019, 98,109503.
[49]	Liu, G.; Guo, Y.; Zhou, L.; Wu, Y.; Chen, M.; He, Z. J. Mater. Sci. 2019, 54,10929.
[50]	Shi, X.; He, J.; Xie, X.; Dou, R.; Lu, X. Dyes. Pigments 2019, 165,137.
[51]	Zhao, Y.; Xie, Z.; Gu, H.; Zhu, C.; Gu, Z. Chem. Soc. Rev. 2012, 41,3297.
[52]	Shang, L.; Zhang, W.; Xu, K.; Zhao, Y. Mater. Horizons 2019, 6,945.
[53]	Gao, W.; Rigout, M.; Owens, H. J. Nanopart. Res. 2017, 19,303.
[54]	Wang, H.; Zhang, K.Q. Sensors 2013, 13,4192.
[55]	Wang, Z.; Guo, Z. J. Bionic Eng. 2018, 15,1.
[56]	Zhao, C.; Ma, Y.; Wang, Y.; Zhou, X.; Li, H.; Li, M.; Song, Y. Acta Chim. Sinica 2018, 76,9. (in Chinese)
	( 赵聪, 马颖, 汪洋, 周雪, 李会增, 李明珠, 宋延林, 化学学报, 2018, 76,9.)
[57]	Liu, X.; Qin, L.; Zhan, Y.; Chen, M.; Yu, Y. Acta Chim. Sinica 2020, 78,478. (in Chinese)
	( 刘晓珺, 秦朗, 詹媛媛, 陈萌, 俞燕蕾, 化学学报, 2020, 78,478.)
[58]	Wu, P.; Wang, J.; Jiang, L. Mater. Horizons 2020, 7,338.
[59]	Wan, L.; Zhang, M.; Wang, J.; Jiang, L. Acta Chim. Sinica 2016, 74,639. (in Chinese)
	( 万伦, 张漫波, 王京霞, 江雷, 化学学报, 2016, 74,639.)
[60]	Cui, L.; Fan, S.; Yu, C.; Kuang, M.; Wang, J. Acta Chim. Sinica 2017, 75,967. (in Chinese)
	( 崔丽影, 范莎莎, 于存龙, 邝旻旻, 王京霞, 化学学报, 2017, 75,967.)
[61]	Wu, P.; Liu, J.; Xie, Z.; Guo, J.; Wang, J. Chinese J. Polym. Sci. 2018, 36,555.
[62]	Liu, J.; Shang, Y.; Zhang, D.; Xie, Z.; Hu, R.; Wang, J. Chinese J. Polym. Sci. 2017, 35,1043.

仿生光子晶体纤维的研究进展

Research Progress of Bioinspired Photonic Crystal Fibers

RichHTML

PDF

Knowledge

Abstract

Cite this article

share this article

Fig. & Tab. 16

References 62

Related Articles 15

Recommended Articles

Metrics

Comments

[1]	Ye Tian, Duanhui Si, Shuiying Gao, Rong Cao. Ultra-Long Organic Room Temperature Phosphorescence of Phthalic Acid Derivative Modified Polymer^★ [J]. Acta Chimica Sinica, 2023, 81(9): 1129-1134.
[2]	Liwei Hu, Xianhu Liu, Chuntai Liu, Yanlin Song, Mingzhu Li. Self-assembly Fabrication and Applications of Photonic Crystal Structure Color Materials^★ [J]. Acta Chimica Sinica, 2023, 81(7): 809-819.
[3]	Tianjiao Ma, Jin Li, Xiaodong Ma, Xuesong Jiang. Temperature-controlled Dynamic Moisture-responsive Wrinkled Patterns^★ [J]. Acta Chimica Sinica, 2023, 81(7): 749-756.
[4]	Juan Wang, Huamin Xiao, Ding Xie, Yuanru Guo, Qingjiang Pan. Density Functional Theory Study of Structures of Copper-doped and Graphitic Carbon Nitride-combined Zinc Oxides and Their Boosted Nitrogen Dioxide-sensing Performance [J]. Acta Chimica Sinica, 2023, 81(11): 1493-1499.
[5]	Huarun Liang, Haoxuan Ma, Xinrong Duan, Jie Yu, Haomin Wang, Shuo Li, Mengjia Zhu, Aibing Chen, Hui Zheng, Yingying Zhang. Flexible Electrochemical Sensors and Their Applications in Noninvasive Medical Detection^★ [J]. Acta Chimica Sinica, 2023, 81(10): 1402-1419.
[6]	Ge-Hua Wen, Wendurina, Xiumei Chen, Xiu-Fang Ma, Guo-Guo Weng, Yi-Fan Wei, Song-Song Bao, Xiaoji Xie, Shu-Xian Hu, Li-Min Zheng. Layered Uranyl Phosphonate as A Dual-response Luminescence Thermometer^★ [J]. Acta Chimica Sinica, 2023, 81(10): 1311-1317.
[7]	Chao Liu, Fei Tian, Jinqi Deng, Jiashu Sun. Thermomicrofluidic Biosensing Systems^※ [J]. Acta Chimica Sinica, 2022, 80(5): 679-689.
[8]	Guang-ling Liang, Xiao-liang Ye, Guan-E Wang, Gang Xu. In situ Alkylation Regulation of the Structure and Properties of Inorganic-Organic Hybrid Perovskite-Like Materials^※ [J]. Acta Chimica Sinica, 2022, 80(4): 460-466.
[9]	Hao-Nan Qin, Zhao-Yang Wang, Shuang-Quan Zang. Photoluminescence and Electrochemical Sensing of Atomically Precise Cu₁₃ Cluster [J]. Acta Chimica Sinica, 2021, 79(8): 1037-1041.
[10]	Fan Lei, Jiang Qunying, Pan Min, Wang Wenxiao, Zhang Li, Liu Xiaoqing. Dual-Mode Sensing of Biomarkers by Mimic Enzyme-Natural Enzyme Cascade Signal Amplification [J]. Acta Chimica Sinica, 2020, 78(5): 419-426.
[11]	Wu Yi-Peng, Wang Ze-Kun, Wang Hui, Zhang Dan-Wei, Zhao Xin, Li Zhan-Ting. Self-Assembly of a Highly Fluorescent Three-Dimensional Supramolecular Organic Framework and Selective Sensing for Picric Acid [J]. Acta Chimica Sinica, 2019, 77(8): 735-740.
[12]	Feng Tingting, Gao Shouqin, Wang Kun. Colorimetric Sensing of Prostate Specific Membrane Antigen Based on Gold Nanoparticles [J]. Acta Chim. Sinica, 2019, 77(5): 422-426.
[13]	Chi Jingyuan, Li Jing, Ren Shaokang, Su Shao, Wang Lianhui. Construction and Application of DNA-two-dimensional Layered Nanomaterials Sensing Platform [J]. Acta Chimica Sinica, 2019, 77(12): 1230-1238.
[14]	Xiong Lin, Fan Yong, Zhang Fan. Research Progress on Rare Earth Nanocrystals for In Vivo Imaging and Sensing in Near Infrared Region [J]. Acta Chimica Sinica, 2019, 77(12): 1239-1249.
[15]	Zhao Shuai, Zhu Rong. Flexible Electronic Skin with Multisensory Integration [J]. Acta Chimica Sinica, 2019, 77(12): 1250-1262.