个人简介

董凯，男，副研究员，硕士生导师，2018年获东华大学纺织科学与工程博士学位。2018-2019年在东华大学担任教职工作。2019年调动到中科院北京纳米能源与系统研究所工作，任副研究员。现主要从事智能纺织纤维材料的设计和开发、纤维基可穿戴能量采集和存储组合器件及多功能自驱动传感纤维及织物的设计和研究等方面的研究工作。在纤维基可穿戴摩擦纳米发电机和多功能自驱动式信号传感方面取得了一系列研究成果。近年来在AdvancedMaterials,AdvancedEnergyMaterials,ACSNano,NanoEnergy,AdvancedFunctionalMaterials等高水平SCI期刊上发表论文20余篇，其中第一作者11篇。申请国家专利4项。作为项目负责人主持上海市青年扬帆计划项目1项和中央高校基本科研业务专项资金自由探索类项目1项，参与国家自然科学基金面上项目3项。 获奖及荣誉： 2019年东华大学优秀博士学位论文 2018年东华大学优秀毕业生 2018年上海市复合材料创新成就奖 2016年获博士研究生国家奖学金

研究领域

1.智能纺织纤维材料和纤维电子学 2.纤维基纳米发电和传感器件的开发与应用 3.纤维基能量采集和存储组合器件的设计与研究

承担科研项目情况： 1.上海市青年科技英才扬帆计划，摩擦纳米发电和传感织物及纺织结构复合材料，2019/05-2022/04，主持 2.中央高校基本科研业务专项资金自由探索类项目，可穿戴机械能采集发电和自驱动传感织物，2019/05-2022.04，主持

近期论文

查看导师最新文章 （温馨提示：请注意重名现象，建议点开原文通过作者单位确认）

1.DongK#,PengX,WangZL*.Fiber/fabric-basedpiezoelectricandtriboelectricnanogeneratorsforflexible/stretchableandwearableelectronicsandartificialintelligence.AdvancedMaterials.2019.1902549. 2.DongK#,WuZ,DengJ,WangA.C,ZouH,WangZL*,etal.AStretchableYarnEmbeddedTriboelectricNanogeneratorasElectronicSkinforBiomechanicalEnergyHarvestingandMultifunctionalPressureSensing.AdvancedMaterials,2018,30(43):1804944. 3.DongK#,DengJ,DingW,WangZL*,etal.Versatilecore-sheathyarnforsustainablebiomechanicalenergyharvestingandreal-timehuman-interactivesensing.AdvancedEnergyMaterials,2018,8(23):1801114. 4.DongK#,DengJ,ZiY,etal.3DOrthogonalWovenTriboelectricNanogeneratorforEffectiveBiomechanicalEnergyHarvestingandasSelf-PoweredActiveMotionSensors.AdvancedMaterials,2017,29(38):201702648. 5.DongK#,WangY-C,DengJ,etal.AHighlyStretchableandWashableAll-Yarn-BasedSelf-ChargingKnittingPowerTextileComposedofFiberTriboelectricNanogeneratorsandSupercapacitors.ACSNano,2017,11(9):9490-9499. 6.DongK#,LiuK,ZhangQ,etal.Experimentalandnumericalanalysesonthethermalconductivebehaviorsofcarbonfiber/epoxyplainwovencomposites.InternationalJournalofHeatandMassTransfer,2016,102:501-517. 7.DongK#,PengX,ZhangJ,etal.Temperature-dependentthermalexpansionbehaviorsofcarbonfiber/epoxyplainwovencomposites:Experimentalandnumericalstudies.CompositeStructures,2017,176:329-341. 8.DongK#,ZhangJ,JinL,etal.Multi-scalefiniteelementanalysesonthethermalconductivebehaviorsof3Dbraidedcomposites.CompositeStructures,2016,143:9-22. 9.DongK#,LiuK,PanL,etal.Experimentalandnumericalinvestigationonthethermalconductionpropertiesof2.5Dangle-interlockwovencomposites.CompositeStructures,2016,154:319-333. 10.DongK#,ZhangJ,CaoM,etal.Amesoscalestudyofthermalexpansionbehaviorsofepoxyresinandcarbonfiber/epoxyunidirectionalcompositesbasedonperiodictemperatureanddisplacementboundaryconditions.PolymerTesting,2016,55:44-60. 11.DongK#,GuB,SunB.Comparisonsofthermalconductivebehaviorsofepoxyresininunidirectionalcompositematerials.JournalofThermalAnalysisandCalorimetry,2016,124(2):775-789. 12.DongK#,PengX,NishonovA,ZhangW,ZhangJ,JinL,GuB,SunB.In-planeTensileBehaviorsofBi-axialWarp-knittedCompositesunderQuasi-staticandHighStrainRateLoading.JournalofDonghuaUniversity(EnglishEdition),2017,34(4):487-491. 13.WuZ,DingW,DaiY,DongK,WuC,ZhangL,Lin,Z,ChengJ,WangZL.Self-PoweredMultifunctionalMotionSensorEnabledbyMagnetic-RegulatedTriboelectricNanogenerator.ACSNano,2018,12(6):5726-5733. 14.DengJ,KuangX,LiuR,DingW,WangA,LaiY,DongK,WenZ,WangZL.VitrimerElastomer-BasedJigsawPuzzle-LikeHealableTriboelectricNanogeneratorforSelf-PoweredWearableElectronics.AdvancedMaterials,2018,30(14):1705918. 15.DaiY,WangX,PengW,XuCheng,WuC,DongK,LiuR,WangZL.Self-PoweredSi/CdSFlexiblePhotodetectorwithBroadbandResponsefrom325to1550nmBasedonPyro-phototronicEffect:AnApproachforPhotosensingbelowBandgapEnergy.AdvancedMaterials,2018,30(9),1705893. 16.WangP,PanL,WangJ,XuM,DaiG,ZouH,DongK,WangZL,AnUltra-Low-FrictionTriboelectric-ElectromagneticHybridNanogeneratorforRotationEnergyHarvestingandSelf-poweredWindSpeedSensor.ACSNano,2018,12(9):9433-9440. 17.WangP,LiuR,DingW,ZhangP,PanL,DaiG,ZouH,DongK,XuC,WangZL.ComplementaryElectromagnetic-TriboelectricActiveSensorforDetectingMultipleMechanicalTriggering.AdvancedFunctionalMaterials,2018,28(11):1705808. 18.DaiY,WangX,PengW,WuC,DingY,DongK,WangZL.EnhancedPerformancesofSi/CdSHeterojunctionNear-InfraredPhotodetectorbythePiezo-PhototronicEffect.NanoEnergy,2017,44:311-318.