Advances in organic thermoelectric materials and devices for smart applications 被引量：4

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摘要 Organic thermoelectric(OTE)materials have been considered to be promising candidates for large area and low‐cost wearable devices owing to their tailorable molecular structure,intrinsic flexibility,and prominent solution processability.More importantly,OTE materials offer direct energy conversion from the human body,solid‐state cooling at low electric consumption,and diversified functions.Herein,we summarize recent developments of OTE materials and devices for smart applications.We first review the fundamentals of OTE materials from the viewpoint of thermoelectric performance,mechanical properties and bionic functions.Second,we describe OTE devices in flexible generators,photothermoelectric detectors,self‐powered sensors,and ultra‐thin cooling elements.Finally,we present the challenges and perspectives on OTE materials as well as devices in wearable electronics and fascinating applications in the Internet of Things.

作者 Yue Zhao Liyao Liu Fengjiao Zhang Chong‐an Di Daoben Zhu

机构地区 School of Chemical Science Beijing National Laboratory for Molecular Sciences

出处《SmartMat》 2021年第4期426-445,共20页 智能材料（英文）

基金 supported by the National Key Research and Development Program of China(2017YFA0204700 and 2018YFE0200700) the National Natural Science Foundation of China(21805285,22021002,21905276,61971396) the Natural Science Foundation of Beijing(4202077) Beijing National Laboratory for Molecular Sciences(BNLMS201912) UCAS(Y954011XX2)and CAS(ZDBS‐LY‐SLH034).

关键词 flexible generators organic thermoelectric materials self‐powered sensors smart electronics thin‐film cooling

分类号 TB3 [一般工业技术—材料科学与工程]

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参考文献7

1Chong-an Di,Wei Xu,Daoben Zhu.Organic thermoelectrics for green energy[J].National Science Review,2016,3(3):269-271. 被引量：3
2Jun Pei,Bowen Cai,Hua-Lu Zhuang,Jing-Feng Li.Bi_(2)Te_(3)-based applied thermoelectric materials: research advances and new challenges[J].National Science Review,2020,7(12):1856-1858. 被引量：10
3Pengchong Li,Zhi Shang,Kejian Cui,Huan Zhang,Zhi Qiao,Caizhen Zhu,Ning Zhao,Jian Xu.Coaxial electrospinning core-shell fibers for self-healing scratch on coatings[J].Chinese Chemical Letters,2019,30(1):157-159. 被引量：4
4Mengnan He,Xiaosong Chen,Donghua Liu,Dacheng Wei.Two-dimensional self-healing hydrogen-bond-based supramolecula polymer film[J].Chinese Chemical Letters,2019,30(5):961-965. 被引量：5
5Dehui XU,Yuelin WANG,Bin XIONG,Tie LI.MEMS-based thermoelectric infrared sensors： A review[J].Frontiers of Mechanical Engineering,2017,12(4):557-566. 被引量：11
6Wenping Hu,Hua Zhang,Khalid Salaita,Henning Sirringhaus.SmartMat:Smart materials to Smart world[J].SmartMat,2020,1(1):131-131. 被引量：5
7Danfeng Zhi,Chong-an Di,Daoben Zhu.Organic topological insulators (OTI): a dream coming true?[J].National Science Review,2020,7(6):996-997. 被引量：1

二级参考文献2

1吴杨,侯宏伟,杨丛林,陆洋,辛显峰,于洋,刘家丰.α2-Heremans-Schimid糖蛋白基因多态性与脑梗死相关性的探讨[J].中国急救医学,2014,34(11):1017-1021. 被引量：4
2洪敏,陈志刚,邹进.Fundamental and progress of Bi_2Te_3-based thermoelectric materials[J].Chinese Physics B,2018,27(4):50-74. 被引量：7

共引文献32

1关一浩,雷程,梁庭,白悦杭,齐蕾,武学占.RIE反应离子刻蚀氮化硅工艺的研究[J].电子测量技术,2021,44(7):107-112. 被引量：2
2白悦杭,雷程,梁庭,宫明峰,王丙寅,陈国锋.一种交叉式圆形MEMS热电堆红外探测器[J].微纳电子技术,2023,60(8):1265-1273.
3蒋丰兴,刘聪聪,徐景坤.导电PEDOT热电材料发展简史[J].科学通报,2017,62(19):2063-2076. 被引量：8
4张琛琛,毛海央,白乐乐,熊继军,王玮冰,陈大鹏.MEMS红外探测器响应时间测量方法研究[J].红外与毫米波学报,2020,39(5):619-625.
5Yan-Jie Zhang,Min Xia,Wei Yang,Fan-Zhi Yang,Guo-Ping Li,Yun-Jun Luo.The Latest Research Progress of New Self-Repairing Energetic Compositest[J].Chinese Journal of Chemistry,2020,38(12):1807-1816.
6齐丽杰,丁逸涵,肖唐鑫,吴浩然,刁凯,鲍成,申永,李正义,孙小强,王乐勇.对亚苯基桥联双脲基嘧啶酮衍生物的超分子自组装研究[J].有机化学,2020,40(11):3847-3852.
7聂晓飞,尹伊哲,甄红楼,董天阳,黄高山,梅永丰,陆卫.金属腔量子阱红外探测器共振波长的角度依赖性[J].红外与毫米波学报,2021,40(4):465-470.
8武学占,雷程,梁庭,关一浩,马野,白悦杭,齐蕾.圆形热电堆红外探测器的结构优化与仿真分析[J].电子测量技术,2021,44(13):17-22. 被引量：1
9王文杰,王晓军.In填充下In_(0.3)Co_(4-x)Ni_(x)Sb_(12-y)Te_(y)系热电材料的研究[J].陶瓷学报,2021,42(4):607-613.
10蔡博文,裴俊,董金峰,庄华鹭,顾津宇,曹茜,胡海华,林子皓,李敬锋.(Bi,Sb)_(2)Te_(3)/SiC纳米复合材料的热电性能增强:纳米SiC的尺寸和组分调控的影响[J].Science China Materials,2021,64(10):2551-2562.

同被引文献86

1陈悦,陈超美,刘则渊,胡志刚,王贤文.CiteSpace知识图谱的方法论功能[J].科学学研究,2015,33(2):242-253. 被引量：6538
2张冬霞,郭凤芝.相变材料在调温服装中的应用[J].针织工业,2007(3):28-31. 被引量：38
3赵朝义,孙金镖.舱外航天服温控系统的研究现状与展望[J].航天医学与医学工程,1999,12(2):149-153. 被引量：8
4欧阳骅,任兆生.从苏-27一体化防护服看抗高过载措施[J].国际航空,1999(2):58-58. 被引量：7
5郭新梅,杨春信,袁修干.气冷式个体热防护系统关键技术分析[J].航天医学与医学工程,2010,23(4):262-266. 被引量：7
6亓玉栋,程卫民,于岩斌,潘刚.我国煤矿高温热害防治技术现状综述与进展[J].煤矿安全,2014,45(3):167-170. 被引量：33
7邱义芬,袁修干,梅志光,贾司光,欧阳骅,任兆生.舱外航天液冷服传热分析[J].航天医学与医学工程,2001,14(5):364-367. 被引量：15
8朱方龙,樊建彬,冯倩倩,周宇.相变材料在消防服中的应用及可行性分析[J].纺织学报,2014,35(8):124-132. 被引量：36
9高凯.文献计量分析软件VOSviewer的应用研究[J].科技情报开发与经济,2015,28(12):95-98. 被引量：191
10黄瑶瑶.矿井制冷降温技术发展综述[J].科技与企业,2016(6):195-195. 被引量：10

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1Hanwei Wang,Jinzhou Fu,Chao Wang,Ruiwang Zhang,Yingying Li,Yushan Yang,Haobo Li,Qingfeng Sun,Huiqiao Li.Foldable high-strength electrode enabled by nanosheet subunits for advanced sodium-ion batteries[J].InfoMat,2022,4(2):152-161. 被引量：1
2Chuang-Jian Su,Chao-Lin Li,Wen-Hui Wang.Efficient piezocatalytic activation of peroxydisulfate over Bi_(2)Fe_(4)O_(9):thickness-dependent synergy effect between peroxydisulfate activation and piezocatalysis[J].Rare Metals,2023,42(12):4005-4014.
3Jin Jia,Yuanyuan Zhu,Pratteek Das,Jiaxin Ma,Sen Wang,Guang Zhu,Zhong-Shuai Wu.Advancing MXene-based integrated microsystems with microsupercapacitors and/or sensors:Rational design,key progress,and challenging perspectives[J].Journal of Materiomics,2023,9(6):1242-1262.
4汪思婧,吴巧英.国内外降温服的研究热点及发展趋势[J].浙江理工大学学报（自然科学版）,2024,51(3):347-357.

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1Ruiwang Zhang,Sijie Yang,Haobo Li,Tianyou Zhai,Huiqiao Li.Air sensitivity of electrode materials in Li/Na ion batteries:Issues and strategies[J].InfoMat,2022,4(6):83-108. 被引量：3

1陆楠,管杰.Thermoelectric performance of Xl_(2)(X=Ge,Sn,Pb)bilayers[J].Chinese Physics B,2022,31(4):608-615.
2Yichuan Zhang,Qichun Zhang,Guangming Chen.Carbon and carbon composites for thermoelectric applications[J].Carbon Energy,2020,2(3):408-436. 被引量：5
3彭盼盼,王超,李岚伟,李淑瑶,陈艳群.Research status and performance optimization of medium-temperature thermoelectric material SnTe[J].Chinese Physics B,2022,31(4):18-30.
4Hu Keyi.Ammonia Fuel Ship Looks Near,But a Bit Far Further Ahead[J].船舶经济贸易,2022(2):64-67.
5Ping Zhang,Zhihao Lou,Mengjie Qin,Jie Xu,Jiatong Zhu,Zongmo Shi,Qian Chen,Michael J.Reece,Haixue Yan,Feng Gao.High-entropy(Ca_(0.2)Sr_(0.2)Ba_(0.2)La_(0.2)Pb_(0.2))TiO_(3) perovskite ceramics with A-site short-range disorder for thermoelectric applications[J].Journal of Materials Science & Technology,2022(2):182-189. 被引量：4
6WANG Qingsong,SU Xinrong,YUAN Xin.Assessment of the Turbulence Characteristics of Shaped Film Cooling Hole with Scale Resolving Simulation[J].Journal of Thermal Science,2022,31(1):47-61.
7Zhijun Chen,Haicai Lv,Qichun Zhang,Hanfu Wang,Guangming Chen.Construction of a cement-rebar nanoarchitecture for a solution-processed and flexible film of a Bi_(2)Te_(3)/CNT hybrid toward low thermal conductivity and high thermoelectric performance[J].Carbon Energy,2022,4(1):115-128.
8M.Nicaise,Chen Lin,Mohsen Azadi,Tara Bozorg-Grayeli,Promise Adebayo-Ige,Drew E.Lilley,Yann Pfitzer,Wujoon Cha,Kyana Van Houten,Nicholas A.Melosh,Roger T.Howe,Jared W.Schwede,Igor Bargatin.Micron-gap spacers with ultrahigh thermal resistance and mechanical robustness for direct energy conversion Samuel[J].Microsystems & Nanoengineering,2019,5(1):344-355. 被引量：1
9Underlining the Fundamentals[J].Beijing Review,2022,65(9):2-2.
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