随着纳米科技的快速发展,出现了不少可用于生物体系的植入式纳米器件,因而开发一种全新的、与植入式纳米器件相匹配的纳米供能系统意义重大。自驱动纳米技术可以从环境中收集能量转化为电能,实现能量自给,有望成为植入式纳米器件能源问题的有效解决方案。对纳米发电机、生物燃料电池、太阳能电池这3种自驱动纳米技术的研究现状、面临问题以及未来研究方向进行了综述,以期为自驱动纳米技术的应用与发展提供参考和借鉴。
Increasing implantable nanosystems can be applied to biological systems due to the rapid development of nanotech-nology.Therefore,it is important to develop new energy nanosystems in this area.Self-driven nanotechnologies can collect energy from the environment and convert into electric power as a self-power-supported device,which is expected to become an effective solu-tion for powering implantable nanosystems.In this paper,systematical summary has been reported on current research status,con-fronting problems and future research directions of nanogenerators,biofuel batteries and solar cells for further application and deve-lopment of self-driven nanotechnologies.
参考文献
[1] | Zhong Lin Wang.Towards Self-powered Nanosystems: From Nanogenerators To Nanopiezotronics[J].Advanced functional materials,200822(22):3553-3567. |
[2] | Wang ZL;Song J.Piezoelectric nanogenerators based on zinc oxide nanowire arrays.[J].Science,20065771(5771):242-246. |
[3] | Wang, Z.L..Triboelectric nanogenerators as new energy technology for self-powered systems and as active mechanical and chemical sensors (Review)[J].ACS nano,201311(11):9533-9557. |
[4] | 潘春旭;李伟平;张豫鹏;余超智;黎德龙.基于纳米材料与纳米结构的纳米电源研究进展[J].无机材料学报,2014(09):897-904. |
[5] | Wang X;Song J;Liu J;Wang ZL.Direct-current nanogenerator driven by ultrasonic waves.[J].Science,20075821(5821):102-105. |
[6] | Yong Qin;Xudong Wang;Zhong Lin Wang.Microfibre–nanowire hybrid structure for energy scavenging[J].Nature,20087180(7180):809-813. |
[7] | Yang, RS;Qin, Y;Dai, LM;Wang, ZL.Power generation with laterally packaged piezoelectric fine wires[J].Nature nanotechnology,20091(1):34-39. |
[8] | Zhu, G.;Yang, R.;Wang, S.;Wang, Z.L..Flexible high-output nanogenerator based on lateral ZnO nanowire array[J].Nano letters,20108(8):3151-3155. |
[9] | Hu, Y.;Zhang, Y.;Xu, C.;Zhu, G.;Wang, Z.L..High-output nanogenerator by rational unipolar assembly of conical nanowires and its application for driving a small liquid crystal display[J].Nano letters,201012(12):5025-5031. |
[10] | Zhu, G.;Wang, A.C.;Liu, Y.;Zhou, Y.;Wang, Z.L..Functional electrical stimulation by nanogenerator with 58 v output voltage[J].Nano letters,20126(6):3086-3090. |
[11] | Chen, X.;Xu, S.;Yao, N.;Shi, Y..1.6 v nanogenerator for mechanical energy harvesting using PZT nanofibers[J].Nano letters,20106(6):2133-2137. |
[12] | 郭隐犇;张青红;李耀刚;王宏志.可穿戴摩擦纳米发电机的研究进展[J].中国材料进展,2016(2):91-100. |
[13] | Fan, F.-R.;Tian, Z.-Q.;Lin Wang, Z..Flexible triboelectric generator[J].Nano Energy,20122(2):328-334. |
[14] | Youfan Hu;Jin Yang;Simiao Niu;Wenzhuo Wu;Zhong Lin Wang.Hybridizing Triboelectrification and Electromagnetic Induction Effects for High-Efficient Mechanical Energy Harvesting[J].ACS nano,20147(7):7442-7450. |
[15] | Xiuhan Li;Zong-Hong Lin;Gang Cheng;Xiaonan Wen;Ying Liu;Simiao Niu;Zhong Lin Wang.3D Fiber-Based Hybrid Nanogenerator for Energy Harvesting and as a Self-Powered Pressure Sensor[J].ACS nano,201410(10):10674-10681. |
[16] | Muscle-Driven In Vivo Nanogenerator[J].Advanced Materials,201023(23):P.2534. |
[17] | Zhou Li;Rusen Yang;Min Yu.Cellular Level Biocompatibility and Biosafety of ZnO Nanowires[J].The journal of physical chemistry, C. Nanomaterials and interfaces,200851(51):20114-20117. |
[18] | Yuan, Miaomiao;Cheng, Li;Xu, Qi;Wu, Weiwei;Bai, Suo;Gu, Long;Wang, Zhe;Lu, Jun;Li, Huanping;Qin, Yong;Jing, Tao;Wang, Zhong Lin.Biocompatible Nanogenerators through High Piezoelectric Coefficient 0.5Ba(Zr0.2Ti0.8)O-3-0.5(Ba0.7Ca0.3)TiO3 Nanowires for In-Vivo Applications[J].Advanced Materials,201444(44):7432-7437. |
[19] | Cheng, Li;Yuan, Miaomiao;Gu, Long;Wang, Zhe;Qin, Yong;Jing, Tao;Wang, Zhong Lin.Wireless, power-free and implantable nanosystem for resistance-based biodetection[J].Nano Energy,2015:598-606. |
[20] | 张巍;刁力为;陈航;马维国;郑军;孙立忠;冯雪.纳米压电发电技术在人体植入式电子设备中的应用[J].北京生物医学工程,2013(5):541-547. |
[21] | Halámková, L.;Halámek, J.;Bocharova, V.;Szczupak, A.;Alfonta, L.;Katz, E..Implanted biofuel cell operating in a living snail[J].Journal of the American Chemical Society,201211(11):5040-5043. |
[22] | Rasmussen, M.;Ritzmann, R.E.;Lee, I.;Pollack, A.J.;Scherson, D..An implantable biofuel cell for a live insect[J].Journal of the American Chemical Society,20123(3):1458-1460. |
[23] | Alon Szczupak;Jan Halamek;Lenka Halamkova;Vera Bocharova;Lital Alfonta;Evgeny Katz.Living battery - biofuel cells operating in vivo in clams[J].Energy & environmental science: EES,201210(10):8891-8895. |
[24] | Kevin MacVittie;Jan Halamek;Lenka Halamkova;Mark Southcott;William D. Jemison;Robert Lobel;Evgeny Katz.From 'cyborg' lobsters to a pacemaker powered by implantable biofuel cells[J].Energy & environmental science: EES,20131(1):81-86. |
[25] | Caofeng Pan;Ying Fang;Hui Wu;Mashkoor Ahmad;Zhixiang Luo;Qiang Li;Jianbo Xie;Xinxu Yan;Lihua Wu;Zhong Lin Wang;Jing Zhu.Generating Electricity from Biofluid with a Nanowire-Based Biofuel Cell for Self-Powered Nanodevices[J].Advanced Materials,201047(47):5388-5328. |
[26] | Hansen, B.J.;Liu, Y.;Yang, R.;Wang, Z.L..Hybrid nanogenerator for concurrently harvesting biomechanical and biochemical energy[J].ACS nano,20107(7):3647-3652. |
[27] | Lori E.Greene;Matt Law;Benjamin D.Yuhas.ZnO-TiO2 Core-Shell Nanorod/P3HT Solar Cells[J].The journal of physical chemistry, C. Nanomaterials and interfaces,200750(50):18451-18456. |
[28] | Tang, J.;Huo, Z.;Brittman, S.;Gao, H.;Yang, P..Solution-processed core-shell nanowires for efficient photovoltaic cells[J].Nature nanotechnology,20119(9):568-572. |
[29] | Cui, S.;Yin, D.;Chen, Y.;Di, Y.;Chen, H.;Ma, Y.;Achilefu, S.;Gu, Y..In vivo targeted deep-tissue photodynamic therapy based on near-infrared light triggered upconversion nanoconstruct[J].ACS nano,20131(1):676-688. |
[30] | 陈志钢;匡兴羽;宋琳琳;田启威;胡俊青.近红外光驱动的纳米材料和器件的研究进展[J].无机化学学报,2013(8):1574-1590. |
[31] | 王敏;王武斌;吴靓;丁忙;陈中胜.上转换纳米材料及其在提高太阳能电池光电效率中的应用?[J].材料导报,2015(15):142-148. |
[32] | 980-nm Laser-Driven Photovoltaic Cells Based on Rare-Earth Up-Converting Phosphors for Biomedical Applications[J].Advanced functional materials,200923(23):3815. |
[33] | Lisha Zhang;Qiwei Tian;Wenju Xu.Construction of 980 nm laser-driven dye-sensitized photovoltaic cell with excellent performance for powering nanobiodevices implanted under the skin[J].Journal of Materials Chemistry: An Interdisciplinary Journal dealing with Synthesis, Structures, Properties and Applications of Materials, Particulary Those Associated with Advanced Technology,201235(35):18156-18163. |
[34] | Jyh-Lih Wu;Fang-Chung Chen;Ming-Kai Chuang;Kim-Shih Tan.Near-infrared laser-driven polymer photovoltaic devices and their biomedical applications[J].Energy & environmental science: EES,20119(9):3374-3378. |
[35] | Wu, J.-L.;Chen, F.-C.;Chang, S.-H.;Tan, K.-S.;Tuan, H.-Y..Upconversion effects on the performance of near-infrared laser-driven polymer photovoltaic devices[J].Organic electronics,201210(10):2104-2108. |
- 下载量()
- 访问量()
- 您的评分:
-
10%
-
20%
-
30%
-
40%
-
50%