基本信息
唐永炳 男 博导 中国科学院深圳先进技术研究院
电子邮件: tangyb@siat.ac.cn
通信地址: 深圳市南山区西丽深圳大学城学苑大道1068号
邮政编码: 518055
电子邮件: tangyb@siat.ac.cn
通信地址: 深圳市南山区西丽深圳大学城学苑大道1068号
邮政编码: 518055
研究领域
(1)新型储能材料及器件的研发与应用
(2)功能薄膜材料的制备及产业化应用
(3)二维材料的技术开发及应用研究
(4)纳米材料的合成、器件制备及应用
唐永炳研究员主要从事新型储能材料及器件、功能薄膜材料的研发与应用,近年来围绕新型储能材料及器件开展了前沿性研究,取得了系列研究成果:(1)首次研发出了高性能宽温域铝基电池技术,实现了电池在-70~80℃的宽温域工作范围,突破了传统锂电池低温性能差、工作温度范围窄的行业技术壁垒,为促进民用、国防、空天探测、极地科考等多场景的储能应用提供了先进的技术支撑;(2)突破了传统锂离子电池的单离子“摇椅式”反应机理的局限,首次发现了阳离子合金化与阴离子插层具有良好的电化学可逆协同反应,发明了铝-石墨双离子电池体系,解决了锂电、超电等传统电化学储能技术难以兼顾高能量和高功率密度的难题,为发展新型高效低成本储能技术提供了新思路;3)进一步发展了不依赖于有限锂资源的钠、钾、钙等储能体系,突破了新型储能体系缺乏合适电极材料的瓶颈,并通过材料结构设计与界面调控等策略,解决了双离子电池的共性关键问题,实现了电池性能的整体提升。
唐永炳研究员还将这种设计思路运用到了廉价环保碱土金属离子电池体系,突破了钙离子电池多年发展无法克服的室温不可逆的瓶颈。美国德克萨斯大学电化学及储能材料著名学者Manthiram教授在《Chem》上对该研究工作做了专题评论(Chem, 2018, 4, 1194-1207),指出:“该研究工作不同于传统思想,为发展新型电池化学反应原理或结构带来了新视角”( ..brings new insights to the broad battery community with respect to developing new battery chemistries or configurations; it represents a departure from conventional thinking.. )。Manthiram教授还认为:“该工作为发展室温下可逆循环的钙离子电池提供了希望,并且这种电池设计策略将为发展高能量密度、低成本的钙离子电池或其他电池体系扩大了活性电极材料的选择范围”(..the interesting results presented in this article offer hope for the feasibility of operating reversible CIBs at room temperature. It is also expected that this battery design strategy will expand the options for active electrode materials for a variety of CIB systems or other battery chemistries toward developing high energy battery systems at an affordable cost..)。
获得国家优秀青年基金(2018)和国家杰出青年基金(2021),广东省创新领军人才(2019)、爱思唯尔中国高被引学者(2022),全球前2%顶尖科学家(2022年度及终身),英国皇家化学学会会士,广东省电池行业协会首席科学家&副理事长等。主持国家重点研发计划、国家自然科学基金、JW、中科院、广东省等科研项目20余项。基于新型储能材料及器件研究成果,在Nature Chemistry, Nature Sustainability, Nature Communication, Advanced Materials, Angewandte Chem, Advanced Energy Materials等高水平期刊上发表SCI论文240篇,IF>10论文146篇,H指数76,他引>17000次,48篇入选ESI高被引论文。已申请专利476项,中国发明专利306项,美欧日韩专利12项,PCT专利68项;已获授权专利240项。58项电池相关专利实现转化或许可,其中26项发明专利依托单位作价6518万实现了转移转化,32项专利获得许可费1000万元。所研发的新型电池技术已进入量产阶段,产品性能通过第三方检测及多项资质认证,并通过比亚迪、爱玛、华为等客户实测;比亚迪实测结果表明:开发的宽温域电池具有优异的低温充电能力,在-20 ℃和-30 ℃的充电容量保持率分别为96%和91%,可解决我国北方新能源汽车和储能等领域的应用难题。基于研究成果,相关产品被第十九届高交会专家委员会从1000个单位推荐产品中评为十大人气产品奖,并获得2021年深圳市自然科学一等奖(第1完成人)、第二十四届中国专利奖银奖(第1发明人)、2022年中国产学研合作促进会个人创新奖等。
招生信息
1、学科专业:物理化学(含化学物理)、表面处理、纳米材料、材料学、材料工程
2、报考要求:
(1)对实验设备、容器、化学基本实验及操作等有充分的了解和掌握,有扎实的理论基础和实践经验;
(2)具备较强的沟通能力与分析能力,有一定解决问题能力;
(4)有较强的责任心和事业心,能吃苦耐劳;
(5)具有较强的英语听说读写能力。
3、计划招生数:20人
招生专业
070304-物理化学0703J1-纳米科学与技术070301-无机化学
招生方向
新型储能材料与器件,功能薄膜材料及产业化纳米材料,复合材料,无机非金属材料双离子电池,超硬涂层材料
教育背景
2002-09--2007-07 中国科学院金属研究所 博士研究生
学历
博士研究生
学位
博士
工作经历
l 2002.09~2007.07 中国科学院金属研究所材料科学与工程博士学位
l 2007.09~2012.12 香港城市大学,应用物理与材料科学系研究员
l 2013. 01~2013.08 香港城市大学,应用物理与材料科学系高级研究员
l 2013.09~2021.09 中国科学院深圳先进技术研究院,功能薄膜材料研究中心
研究员/中心主任
l 2021.09~至今 中国科学院深圳先进技术研究院,碳中和技术研究所(筹)副所长、先进储能技术研究中心主任
工作简历
2021-11~现在, 中国科学院深圳先进技术研究院, 碳中和技术研究所(筹)副所长、先进储能技术研究中心主任2013-08~现在, 中国科学院深圳先进技术研究院, 研究员/中心主任2013-01~2013-08,香港城市大学, 高级研究员2007-09~2012-12,香港城市大学, 研究员
学术兼职
2020-04-30-2023-04-30,光电材料器件网专家委员会, 副理事长
2019-07-31-2023-07-30,广东省电池行业协会理事会, 副理事长
2019-05-31-今,《储能科学与技术》编委, 编委
2018-12-10-今,《Green Energy&Environment》期刊青年编委, 被Elsevier出版社聘为《Green Energy&Environment》期刊青年编委
2017-05-31-今,深圳市电源技术学会, 理事
2016-08-31-2017-08-31,中国机械工程学会表面工程分会青工委委员会, 委员
2015-11-01-今,深圳市真空学会理事会, 理事
2015-11-01-2016-11-01,中国真空学会《真空科学与技术学报》理事会, 学会理事
2014-10-16-今,International Advisory Panel Member of Materials Research Express, 顾问
2014-06-16-今,Associate Editor of Journal of Nanoscience Letters, 副主编
2019-07-31-2023-07-30,广东省电池行业协会理事会, 副理事长
2019-05-31-今,《储能科学与技术》编委, 编委
2018-12-10-今,《Green Energy&Environment》期刊青年编委, 被Elsevier出版社聘为《Green Energy&Environment》期刊青年编委
2017-05-31-今,深圳市电源技术学会, 理事
2016-08-31-2017-08-31,中国机械工程学会表面工程分会青工委委员会, 委员
2015-11-01-今,深圳市真空学会理事会, 理事
2015-11-01-2016-11-01,中国真空学会《真空科学与技术学报》理事会, 学会理事
2014-10-16-今,International Advisory Panel Member of Materials Research Express, 顾问
2014-06-16-今,Associate Editor of Journal of Nanoscience Letters, 副主编
教授课程
新能源材料与器件
专利与奖励
代表性授权专利:
(1) 丛洪涛, 唐永炳,成会明,一种氮化铝增强金属铝的双纳米复合材料,发明专利,申请号:200410050349.2, 授权公告号:CN100370047C,授权日:2008-2-20;
(2) 丛洪涛, 唐永炳,成会明, 一种纳米氮化铝/纳米铝双纳米复合材料的制备方法,发明专利,申请号:200410050348.8, 授权公告号:CN100496818C,授权日:2009-6-10;
(3) 丛洪涛,唐永炳,成会明, 一种电子封装复合材料, 发明专利,申请号: 200510046366.3, 授权公告号:CN100577768C,授权日:2010-1-6;
(4) 丛洪涛,唐永炳,成会明, 一种纳米棒阵列材料, 发明专利,申请号:200510046365.9, 授权公告号:CN100413780C,授权日:2008-8-27;
(5) 丛洪涛, 唐永炳, 成会明, 一种刻蚀基板法外延定向生长AlN 纳米片网格的方法, 发明专利,申请号:200710010519.8, 授权公告号:CN100578736C,授权日:2010-1-6;
(6) 丛洪涛, 唐永炳, 成会明, 一种高强度、低热膨胀的AlN 纳米线和Al复合材料, 发明专利,申请号:200710111662.6, 授权公告号:CN101255538B,授权日:2011-7-20;
(7) 丛洪涛, 唐永炳, 成会明, 一种催化剂“种子”法制备准一维掺杂AlN 阵列的方法, 发明专利,申请号:200710010518.3, 授权公告号:CN101255064B,授权日:2012-8-22;
(8) 李振声,李述汤,唐永炳,冯敏强,陈昭仪, 多孔基底与一维纳米材料的复合材料及其制备方法、其表面改性的复合材料及制备方法, 发明专利,申请号:201110241568.9, 授权公告号:CN102949981B,授权日:2015-9-30;
(9) C.S. Lee, S.T. Lee, Y.B. Tang, M.K. Fung, composite of porous substrate and one-dimensional nanomatrial and method for preparing the same, surface-modified composite and method for preparing the same, 美国发明专利13/585,707,授权日:2013-2-21;
(10)唐永炳;张小龙;张帆,이차전지및그제조방법,韩国发明专利,申请号:KR1020187012967,申请日:2016-11-12,授权日:2020-03-14;
(11)唐永炳;张小龙;张帆,Secondary battery and preparation method therefor,美国发明专利,申请号:US15/773805,申请日:2016-11-12,授权日:2020-05-08;
(12)唐永炳;张小龙;张帆,一种二次电池及其制备方法,发明专利,申请号:CN201610998823.7,申请日:2016-11-12,授权日:2019-06-28;
(13)唐永炳;张小龙,一种二次电池及其制备方法,发明专利,申请号:CN201510856238.9,申请日:2015-11-30,授权日:2018-11-27;
(14)唐永炳;张帆,二硫化钼/聚苯胺复合材料、制备方法及锂离子电池,发明专利, 申请号: CN201410638073.3,申请日:2014-11-12,授权日:2018-05-11;
(15)唐永炳;张帆;李振声,一种钛酸钠纳米线/石墨烯复合负极材料及其制备方法,发明专利,申请号: CN201510682930.4,申请日: 2015-10-20,授权日:2018-06-05;
(16)唐永炳;李文跃;李振声,石墨烯/聚苯胺/硫复合正极材料及其制备方法、锂硫电池,发明专利,申请号: CN201510960678.9,申请日:2015-12-21,授权日:2018-08-14;
(17)唐永炳;张小龙,注水发电环保电池及其正电极和电池组,发明专利,申请号:CN201510660753.X,申请日: 2015-10-14,授权日:2018-10-16;
(18)唐永炳;谢呈德;圣茂华,一种多孔锡箔负极及其制备方法和钠离子二次电池,发明专利,申请号:CN201611248878.2,申请日:2016-12-29,授权日:2020-04-21;
(19)杨扬;唐永炳;张帆,一种钴酸锌/石墨烯复合负极材料及其制备方法和锂离子电池,发明专利, 申请号: CN201710155025.2,申请日:2017-03-14,授权日:2020-02-11;
(20)唐永炳;吴石;张帆,钾离子混合超级电容器及其制备方法, 发明专利,申请号:CN201710583412.6,申请日:2017-07-17,授权日:2020-03-20;
(21)唐永炳;王恒;王蒙,钠离子混合超级电容器及其制备方法,发明专利,申请号:CN201710583421.5,申请日: 2017-07-17,授权日:2020-02-11;
(22)唐永炳;朱海莉;张帆,金属导电材料用作镁离子混合超级电容器负极和镁离子混合超级电容器及其制备方法,发明专利,申请号:CN201710583516.7,申请日:2017-07-17,授权日:2019-11-15;
(23)唐永炳;谢呈德;方月,钠离子电池用电解液、制备方法及包含该钠离子电池用电解液的钠离子电池,发明专利,申请号:CN201710760819.1,申请日:2017-08-29,授权日:2020-01-14;
(24)唐永炳;谢呈德,电池的充电方法及充电设备,发明专利,申请号:CN201710771361.X,申请日:2017-08-29,授权日:2019-11-15;
(25)唐永炳;谢呈德;张桂河,锂离子电池圆形垫片及锂离子电池,新型专利,申请号:CN201720832602.2,申请日:2017-07-10,授权日: 2018-06-19;
(26)唐永炳;蒋春磊;石磊,电池极片附着力测试设备,新型专利,申请号:CN201721309229.9,申请日:2017-10-09,授权日:2018-05-01;
(27)唐永炳;曹建红,电池浆料的喷涂装置及电池极片生产设备,新型专利, 申请号: CN201721481790.5,申请日:2017-11-08,授权日:2018-06-19;
(28)唐永炳;李星星;黄磊;王陶;杨扬,表面具有金刚石层的铝电极及其锂二次电池,新型专利,申请号:CN201721762972.X,申请日:2017-12-15,授权日:2018-07-17;
(29)杨扬;唐永炳;李子豪;谷继腾;张文军,一种金属空气电池, 新型专利,申请号:CN201721845762.7,申请日: 2017-12-26,授权日:2018-08-28;
(30)唐永炳;李子豪;杨扬;谷继腾;张文军,一种超级电容器,新型专利, 申请号:CN201820358005.5,申请日:2018-03-15,授权日:2018-10-26;
(31)唐永炳;蒋春磊;项磊;石磊, 具有涂层的极耳、电芯、电池和电动工具, 新型专利, 申请号:CN201821128441.X,申请日:2018-07-16,授权日:2019-02-12;
(32)唐永炳;石磊;蒋春磊,电池原位拉曼测试装置,新型专利, 申请号:CN201821824585.9,申请日:2018-11-06, 授权日:2019-08-16;
(33)唐永炳;蒋春磊;石磊;方月,电池原位应力测试装置,新型专利,申请号:CN201821868416.5,申请日:2018-11-13,授权日:2019-08-16;
(34)唐永炳;闫家肖;蒋春磊;石磊,复合负极片、二次电池,新型专利,申请号:CN201822080185.8,申请日:2018-12-11,授权日:2019-08-02;
(35)唐永炳;刘齐荣;石磊;蒋春磊,电池原位X射线衍射测试辅助装置,新型专利, 申请号:CN201822112688.9, 申请日:2018-12-14,授权日:2019-11-19;
(36)唐永炳;蒋春磊,一种过渡金属硼化物涂层及其制备方法,发明专利, 申请号:CN201410635526.7,申请日: 2014-11-12,授权日:2018-08-14;
(37)唐永炳;朱雨,等离子源系统和等离子生成方法,发明专利,申请号:CN201410638080.3,申请日:2014-11-12,授权日:2017-12-19;
(38)杨扬;杨映虎;唐永炳,辐射式蒸发加热器及该辐射式蒸发加热器的制造方法,发明专利,申请号:CN201410658772.4,申请日:2014-11-18,授权日:2017-09-26;
(39)唐永炳;蒋春磊,轴类零部件涂层摩擦磨损试验机,发明专利, 申请号:CN201410663763.4,申请日:2014-11-19,授权日:2017-07-28;
(40)杨扬;张文军;唐永炳,金刚石纳米针阵列复合材料及其制备方法和应用,发明专利,申请号:CN201410720492.1,申请日:2014-12-02,授权日:2017-05-03;
(41)唐永炳;蒋春磊, 一种测定含氢类金刚石涂层在低温下的热膨胀系数的方法, 发明专利, 申请号:CN201510690729.0,申请日:2015-10-22,授权日:2019-10-08;
(42)杨扬;唐永炳;李刚, 一种植入式芯片的封装结构及其制备方法,发明专利,申请号:CN201510742481.8,申请日:2015-11-04,授权日:2019-03-01;
(43)唐永炳;蒋春磊,一种仿生结构立方氮化硼涂层及其制备方法,发明专利,申请号:CN201510822743.1,申请日:2015-11-24,授权日:2019-03-01;
(44)唐永炳;蒋春磊;张静,一种金刚石/类金刚石多层复合涂层及其制备方法,发明专利,申请号:CN201510824541.0,申请日:2015-11-24,授权日:2019-03-01;
(45)唐永炳;朱雨;牛卉卉,一种用于制备金刚石的基台组件,发明专利, 申请号:CN201510870990.9,申请日: 2015-12-02,授权日:2019-05-07;
(46)唐永炳;朱雨;牛卉卉;刘辉,等离子体源单元、等离子体源装置及其应用,发明专利,申请号:CN201510870305.2,申请日:2015-12-02,授权日:2018-08-31;
(47)唐永炳;李刚;杨扬,一种硬质合金衬底的金刚石/碳化硼复合涂层及制备方法,发明专利,申请号:CN201510945923.9,申请日:2015-12-16,授权日:2018-08-31;
(48)唐永炳;牛卉卉;朱雨,用于金刚石单晶同质外延的籽晶托盘、基台组件及其应用,发明专利,申请号:CN201510974331.X,申请日:2015-12-23,授权日:2018-05-01;
(49)唐永炳;朱海莉;蒋春磊,一种类金刚石/立方氮化硼多层复合涂层及其制备方法,发明专利,申请号: CN201610436286.7,申请日:2016-06-17,授权日:2019-07-02;
(50)唐永炳;王陶;张文军,一种具有金刚石涂层的硬质合金件及其制备方法,发明专利,申请号:CN201610626731.6, 申请日:2016-08-03,授权日:2018-12-21;
(51)唐永炳;朱海莉;蒋春磊;申京受,含类金刚石复合涂层及其制备方法,发明专利,申请号:CN201611093220.9,申请日:2016-12-01,授权日:2019-04-05;
(52)唐永炳;王陶;张文军;李振声,一种具有金刚石/碳化硅复合涂层的工具及其制备方法,发明专利,申请号:CN201611173709.7,申请日:2016-12-16,授权日:2019-06-25;
(53)唐永炳;杨扬;秦盼盼;张文军,一种具有类金刚石阵列的结构件及其制备方法, 发明专利,申请号: CN201611185457.X,申请日:2016-12-20,授权日:2019-06-25;
(54)唐永炳;蒋春磊;朱海莉,一种具有过渡金属硼化物涂层的PCB用微钻及其制备方法, 发明专利,申请号: CN201611193431.X,申请日:2016-12-21,授权日: 2019-06-25;
(55)唐永炳;陈光海;蒋春磊;朱海莉;王陶,具有涂层的硬质合金件,新型专利,申请号: CN201621428712.4,申请日:2016-12-24,授权日:2017-08-22;
(56)唐永炳;谷继腾;杨扬,一种聚晶金刚石复合片及其制备方法,发明专利,申请号:CN201710104716.X, 申请日:2017-02-24,授权日:2018-10-19;
(57)唐永炳;张松全;王陶;张文军,热丝承载架及金刚石薄膜沉积设备,新型专利,申请号:CN201720203832.2,申请日:2017-03-03,授权日:2017-11-14;
(58)唐永炳;谢友能;王陶,热丝组件及金刚石薄膜沉积设备,新型专利,申请号:CN201720206816.9,申请日: 2017-03-03,授权日:2017-11-14;
(59)唐永炳;张松全;王陶,热丝承载架及金刚石薄膜沉积设备,发明专利,申请号:CN201710124589.X,申请日: 2017-03-03,授权日:2019-11-05;
(60)唐永炳;谷继腾;杨扬,一种具有金刚石涂层的硬质合金件及其制备方法,发明专利,申请号:CN201710147177.8,申请日:2017-03-13,授权日:2019-12-03;
(61)唐永炳;张松全;王陶,一种拉丝模具内孔制备金刚石涂层的装置,新型专利, 申请号:CN201720240029.6,申请日:2017-03-13, 授权日:2017-10-10;
(62)唐永炳;石磊;蒋春磊,一种具有富硼化钨涂层的工件,新型专利,申请号:CN201720311824.X,申请日:2017-03-28,授权日:2017-12-08;
(63)唐永炳;石磊;蒋春磊,刀片涂层夹具及涂层机,新型专利,申请号:CN201720323017.X,申请日:2017-03-29,授权日:2018-02-23;
(64)唐永炳;蒋春磊;石磊,镀膜夹具和镀膜设备, 新型专利,申请号:CN201720341029.5,申请日:2017-04-01,授权日:2018-02-02;
(65)唐永炳;石磊;蒋春磊,衬底,新型专利,申请号:CN201720388304.9,申请日:2017-04-11,授权日:2017-12-26;
(66)唐永炳;张松全;王陶,具有多种涂层的拉丝模具, 新型专利,申请号: CN201720410260.5,申请日:2017-04-18,授权日:2017-11-14;
(67)唐永炳;石磊;蒋春磊,涂层夹具及涂层机,新型专利, 申请号:CN201720440410.7,申请日:2017-04-24, 授权日:2017-12-15;
(68)唐永炳;王陶;黄磊,一种表面具有高致密纳米金刚石薄膜的工件,新型专利,申请号:CN201720724618.1, 申请日:2017-06-20,授权日:2018-03-27;
(69)唐永炳;谢呈德;张桂河,热交换器及NMP废气回收系统,新型专利,申请号: CN201720752722.1,申请日: 2017-06-26,授权日:2018-01-26;
(70)唐永炳;谷继腾;杨扬,聚晶金刚石复合片,新型专利,申请号:CN201720767033.8,申请日:2017-06-28,授权日:2018-01-16;
(71)唐永炳;陈光海;蒋春磊,一种具有含钛化合物涂层的剪线钳,新型专利,申请号:CN201720824223.9,申请日:2017-07-06,授权日:2018-01-23;
(72)唐永炳;黄磊;王陶,具有复合渗层的钛铝合金件、具有金刚石涂层的钛铝合金件,新型专利,申请号:CN201720958916.7,申请日:2017-08-02,授权日:2018-02-23;
(73)唐永炳;黄磊;王陶,具有复合渗层的钛铝合金件、具有金刚石涂层的钛铝合金件,新型专利,申请号:CN201720959125.6,申请日:2017-08-02,授权日: 2018-04-06;
(74)唐永炳;谷继腾;杨扬,聚晶金刚石复合片,新型专利,申请号:CN201720999608.9,申请日:2017-08-08, 授权日:2018-04-06;
(75)唐永炳;石磊;蒋春磊,立铣刀前处理夹具,新型专利, 申请号:CN201721021794.5,申请日:2017-08-15,授权日:2018-05-01;
(76)唐永炳;石磊;蒋春磊,一种薄膜应力测试用衬底夹具,新型专利,申请号:CN201721042157.6,申请日:2017-08-18,授权日:2018-05-01;
(77)唐永炳;谷继腾;杨扬,聚晶金刚石复合片,新型专利,申请号:CN201721043377.0,申请日:2017-08-18,授权日:2018-06-29;
(78)唐永炳;陈光海;蒋春磊,过渡金属硼化物-金属复合靶材与镀膜设备,新型专利,申请号:CN201721115049.7, 申请日:2017-08-30,授权日:2018-07-13;
(79)唐永炳;蒋春磊;石磊,掺杂CaF2的TiB2涂层、CaF2和TiB2复合涂层、其制备方法和应用及刀具,发明专利,申请号:CN201711019913.8,申请日:2017-10-25,授权日:2019-08-23;
(80)唐永炳;蒋春磊;陈光海;石磊,钳子,新型专利,申请号:CN201721398465.2,申请日:2017-10-25,授权日:2018-05-01;
(81)唐永炳;蒋春磊;陈光海;石磊,样品台,新型专利,申请号:CN201721395198.3,申请日:2017-10-25, 授权日:2018-06-26;
(82)唐永炳;杨扬;谷继腾,制备金刚石涂层的热丝架及装置,新型专利,申请号:CN201721416517.4,申请日:2017-10-27,授权日:2018-08-28;
(83)杨扬;唐永炳;谷继腾,金刚石/石墨烯复合导热膜和散热系统,新型专利,申请号:CN201721418398.6,申请日:2017-10-30, 授权日:2018-08-28;
(84)杨扬;唐永炳;谷继腾,一种硼掺杂金刚石电极,新型专利, 申请号:CN201721474192.5,申请日:2017-11-07,授权日:2018-07-24;
(85)唐永炳;谷继腾;杨扬,一种聚晶金刚石复合片,新型专利,申请号:CN201721579432.8,申请日:2017-11-22,授权日:2018-07-17;
(86)唐永炳;李星星;黄磊;王陶;杨扬,一种具有金刚石薄膜的硬质合金,新型专利,申请号:CN201721788799.0,申请日:2017-12-20,授权日:2018-07-24;
(87)唐永炳;谷继腾;杨扬;李子豪;张文军,一种多孔掺硼金刚石电极,新型专利,申请号:CN201721798227.0, 申请日:2017-12-20,授权日:2018-11-09;
(88)唐永炳;谷继腾;杨扬;石磊,一种掺硼金刚石电极, 新型专利,申请号:CN201721801225.2,申请日:2017-12-20,授权日:2018-08-28;
(89)唐永炳;蒋春磊;项磊;石磊;孟醒,碳-过渡金属硼化物复合涂层和切削工具, 新型专利, 申请号:CN201721828294.2,申请日:2017-12-22,授权日: 2018-09-14;
(90)唐永炳;黄磊;王陶;杨扬,沉积金刚石涂层的装置,新型专利,申请号:CN201721839690.5,申请日:2017-12-25,授权日:2018-08-28;
(91)唐永炳;蒋春磊;石磊;项磊;孟醒,类金刚石复合涂层及涂层工具,新型专利,申请号:CN201721842720.8,申请日:2017-12-25,授权日:2019-01-18;
(92)唐永炳;黄磊;王陶;李星星;杨扬,中空微针与药物注射装置,新型专利,申请号:CN201721884312.9,申请日:2017-12-28,授权日:2019-08-02;
(93)唐永炳;谷继腾;杨扬;李子豪;张文军,一种掺硼金刚石电极,新型专利,申请号:CN201820323056.4,申请日:2018-03-09,授权日:2019-03-15;
(94)唐永炳;李星星;王陶;黄磊;杨扬,金属网沉积金刚石涂层装置和金属网沉积金刚石涂层系统,新型专利, 申请号:CN201820338175.7,申请日:2018-03-12,授权日:2019-01-08;
(95)唐永炳;陈波;王陶;杨扬;张松全,夹持装置及前处理装置, 新型专利,申请号:CN201820369545.3,申请日:2018-03-16,授权日:2019-01-08;
(96)唐永炳;陈波;王陶;杨扬;张松全,热丝固定装置及金刚石薄膜生长设备, 新型专利,申请号:CN201820365870.2,申请日:2018-03-16,授权日:2019-01-04;
(97)唐永炳;李子豪;杨扬;谷继腾;张文军,一种多孔硼氮镍共掺杂金刚石电极和电化学脱卤工作站,新型专利, 申请号:CN201820636156.2,申请日:2018-04-28,授权日:2019-04-02;
(98)唐永炳;陈波;王陶;杨扬,刀具清洗辅助装置及刀具清洗装置,新型专利,申请号:CN201820654825.9,申请日:2018-05-03,授权日:2019-06-04;
(99)唐永炳;谷继腾;杨扬;李子豪;张文军,掺硼金刚石/石墨复合电极、双电池反应器,新型专利,申请号:CN201820695741.X,申请日:2018-05-10,授权日: 2019-05-14;
(100) 唐永炳;陈波;王陶;杨扬,热丝夹具和热丝沉积设备,新型专利,申请号:CN201820707020.6,申请日:2018-05-11,授权日: 2019-02-01;
(101) 唐永炳;李子豪;杨扬;谷继腾;张文军,一种高导热结构, 新型专利,申请号:CN201820740142.5,申请日:2018-05-17,授权日:2019-03-15;
(102) 唐永炳;蒋春磊;石磊,具有颜色层的金刚石涂层刀具及加工设备, 新型专利, 申请号:CN201820872682.9,申请日:2018-06-06,授权日:2019-05-03;
(103) 唐永炳;陈波;王陶;杨扬,热丝夹具与热丝沉积设备,新型专利,申请号:CN201820909937.4,申请日:2018-06-12, 授权日:2019-01-29;
(104) 唐永炳;陈波;王陶;杨扬,刀具清洗风干装置及刀具清洗风干系统,新型专利,申请号:CN201821126381.8,申请日:2018-07-11,授权日:2019-03-29;
(105)唐永炳;陈波;杨扬;王陶,刀具承载台及应用其的刀具加工系统, 新型专利,申请号:CN201821122636.3,申请日:2018-07-13,授权日:2019-03-29;
(106) 唐永炳;陈波;杨扬;王陶,刀具承载台及刀具加工系统,新型专利, 申请号:CN201821117312.0,申请日: 2018-07-13,授权日:2019-03-29;
(107) 唐永炳;陈波;杨扬;王陶,刀具承载台及刀具加工装置,新型专利, 申请号:CN201821117682.4,申请日:2018-07-13,授权日:2019-03-29;
(108) 唐永炳;陈波;杨扬;王陶,刀具清洗装置及刀具清洗系统,新型专利,申请号:CN201821119492.6,申请日:2018-07-13,授权日:2019-03-29;
(109) 唐永炳;陈波;杨扬;王陶,用于片材双面沉积涂层的夹具及沉积装置,新型专利, 申请号:CN201821137629.0, 申请日: 2018-07-16,授权日:2019-03-29;
(110) 唐永炳;陈波;王陶;孟醒,刀具夹具及刀具清洗装置,新型专利,申请号:CN201821400737.2,申请日:2018-08-28,授权日:2019-04-26;
(111) 唐永炳;陈波;王陶;孟醒,刀粒清洗板及刀粒清洗装置,新型专利,申请号:CN201821706584.4,申请日:2018-10-19,授权日:2019-08-23;
(112) 唐永炳;陈波;王陶;杨扬,用于片材沉积涂层的夹具及沉积装置,新型专利,申请号:CN201821704780.8,申请日:2018-10-19,授权日:2019-08-13;
(113) 唐永炳;孟醒;陈波;王陶,片材夹具及沉积设备,新型专利,申请号:CN201821704778.0,申请日:2018-10-19,授权日:2019-08-02;
(114) 唐永炳;孟醒;陈波;王陶,用于在片材上沉积掺杂涂层的夹具及沉积装置,新型专利,申请号:CN201821708390.8,申请日:2018-10-19,授权日:2019-08-02;
(115) 唐永炳;陈波;王陶;孟醒,用于片材连续沉积涂层的夹具及沉积装置,新型专利,申请号:CN201821708429.6,申请日:2018-10-19,授权日:2019-08-02;
(116) 唐永炳;徐阳;王陶;陈波;李星星;黄磊,冲裁装置,新型专利,申请号:CN201822090531.0,申请日:2018-12-12,授权日:2019-08-23;
(117) 唐永炳;王星永;王陶;黄磊;李星星,热丝化学气相沉积用基片台及热丝化学气相沉积装置,新型专利,申请号:CN201822113118.1,申请日:2018-12-14,授权日:2019-08-23;
(118) 唐永炳;黄磊;王陶;王星永,钛合金复合材料、外科植入物和医疗器械, 新型专利,申请号:CN201822129956.8,申请日:2018-12-18, 授权日:2019-08-23;
(119) 唐永炳;周小龙,薄膜涂层色度分析设备和薄膜涂层分类系统,新型专利,申请号:CN201822143468.2, 申请日:2018-12-19,授权日:2019-10-18;
(120) 唐永炳;蒋春磊,TiB2自润滑涂层及其制备方法和耐磨构件,发明专利,申请号:CN201611246668.X, 申请日:2016-12-19,授权日:2020-06-02;
(121) 唐永炳;石磊;蒋春磊,超疏水医疗器具,新型专利,申请号:CN201822071845.6, 申请日:2018-12-10
,授权日:2020-06-12;
(122) 唐永炳;雷新;张帆,金属氧化物或其复合材料的制备方法、金属氧化物或其复合材料和应用、电池,发明专利,申请号:CN201811543888.8, 申请日:2018-12-17,授权日:2020-06-16;
(123) 唐永炳;张阁;欧学武,预嵌锂负极的制备方法及制备得到的预嵌锂负极、储能器件、储能系统及用电设备,发明专利,申请号:CN201811545143.5,申请日:2018-12-17,授权日:2020-07-17;
(124) 唐永炳;蒋春磊;焦国华;鲁远甫,薄膜应力测试仪及其测试方法,发明专利,申请号:CN201610162358.3,申请日:2016-03-21,授权日:2020-07-21;
(125) 唐永炳;丁璇;张帆,铝离子混合超级电容器及其制备方法,发明专利,申请号:CN201711439316.0,申请日:2017-12-26,授权日:2020-07-24
奖励信息
(1) 深圳市自然科学奖, 一等奖, 市地级, 2021(2) 广东省特支计划领军人才, , 省级, 2019(3) 深圳市高层次专业人才(地方级领军人才), , 市地级, 2018(4) 超硬纳米金刚石涂层精密刀具 , , 专项, 2017(5) 用于废水处理的高效硼掺杂金刚石阳极 , , 专项, 2017(6) 一体化超高倍率双离子电池, , 专项, 2017(7) 基于铝负极的高效低成本新型电池, , 专项, 2017(8) 环保型高效低成本铝-石墨双离子电池, , 专项, 2017(9) 柔性超快充放电池, 特等奖, 专项, 2017(10) 深圳市孔雀人才B类计划, , 市地级, 2014(11) 葛庭燧奖研金, , 其他, 2009(12) 师昌绪奖学金二等奖, 二等奖, 其他, 2007(13) 刘永龄奖学金特别奖, 特等奖, 院级, 2007(14) 优秀论文奖, , 其他, 2006(15) 师昌绪奖学金一等奖, 一等奖, 其他, 2005(16) 院长奖学金优秀奖, , 院级, 2005
代表性专利
[1] 唐永炳, 苟佳利, 郑勇平, 季必发. 一种燃料电池催化剂的制备方法、燃料电池催化剂及燃料电池. CN: CN114094126A, 2022-02-25.[2] 唐永炳, 黎重重, 周小龙. 一种金属负极电池的改性隔膜、制备方法及应用. CN: CN110828749B, 2022-01-25.[3] 唐永炳, 张晓明, 薛松, 章罗江, 蒋春磊. 负极材料及其制备方法和钠离子电池. CN: CN113937281A, 2022-01-14.[4] 张帆, 徐思奇, 唐永炳. 钛酸锂/锂离子导体/碳复合材料及制备方法和应用. CN: CN113937260A, 2022-01-14.[5] 唐永炳, 谷继腾, 杨扬, 石磊. 一种掺硼金刚石电极及其制备方法. CN: CN111254434B, 2022-01-04.[6] 唐永炳, 郑勇平, 雷新, 苟佳利. 一种可充电锰离子电池及其制备方法. CN: CN113851738A, 2021-12-28.[7] 唐永炳, 蒋春磊, 项磊, 缪仕杰, 石磊. 柔性电池负极及其制备方法、柔性电池. CN: CN111276700B, 2021-11-26.[8] 唐永炳, 王海涛, 谢呈德. 铝负极材料、制备方法及二次电池. CN: CN111326717B, 2021-11-16.[9] 唐永炳, 蒋春磊, 孟醒, 石磊. 电池极耳表面处理方法. CN: CN110616431B, 2021-11-16.[10] 唐永炳, 潘庆广, 仝兆鹏. 一种金属离子电池硫化物复合材料及其制备方法和应用. PCT/CN2021/130980, 2021-11-16.[11] 唐永炳, 潘庆广, 仝兆鹏. 一种氮掺杂碳包覆的金属硫化物异质结材料、制备方法及电池应用. CN202111357448.5, 2021-11-16.[12] 唐永炳, 徐阳, 王陶. 一种抗菌多级次金刚石复合材料及其制备方法和应用. CN: CN110947030B, 2021-11-16.[13] 唐永炳, 杨凯, 刘齐荣. 含锡负极材料、负极及其制备方法与负极浆料、二次电池和用电设备. CN: CN109671936B, 2021-10-29.[14] 唐永炳, 李娜, 王蒙. 金属箔材用作镧离子二次电池负极和镧离子二次电池及其制备方法. CN: CN109962231B, 2021-10-29.[15] 杨扬, 唐永炳, 张文军. 金刚石纳米针结构及其制备方法与应用. CN: CN109705857B, 2021-10-26.[16] 唐永炳, 木赛男, 刘齐荣. 纳米材料及其制备方法、电极和二次电池. CN: CN111063870B, 2021-09-24.[17] 唐永炳, 王海涛, 王琛. 一种电池负极及其制备方法和二次电池. CN: CN110993955B, 2021-09-24.[18] 唐永炳, 王陶, 张文军, 李振声. 一种超分散纳米金刚石及其制备方法. CN: CN108502879B, 2021-09-07.[19] 唐永炳, 王陶, 徐阳, 黄磊. 薄膜电极及制备方法. CN: CN110808181B, 2021-09-03.[20] 唐永炳, 宋天一, 姚文娇. 钠离子电池正极活性材料、钠离子电池正极材料、钠离子电池正极和钠离子电池及制备方法. CN: CN111354924B, 2021-08-24.[21] 唐永炳, 袁超平, 谢呈德. 储能器件铝负极、储能器件及其制备方法. CN: CN109346725B, 2021-08-03.[22] 唐永炳, 谢呈德, 徐子俊. 电池材料测试装置及方法. CN: CN109283087B, 2021-08-03.[23] 唐永炳, 蒋春磊, 方月. 一种一体化二次电池及其制备方法. CN: CN108631010B, 2021-07-27.[24] 唐永炳, 常兴奇, 周小龙. 电解液、钙离子二次电池及其制备方法. CN: CN111326794B, 2021-07-20.[25] 唐永炳, 丁璇, 张帆. 电荷转移型自动氧化还原纳米材料及其制备方法与防污抗菌涂料. CN: CN109423094B, 2021-07-20.[26] 唐永炳, 谢东豪, 张苗. 负极材料、负极及其制备方法与负极浆料、二次电池和用电设备. CN: CN109638221B, 2021-06-18.[27] 唐永炳, 王蒙, 王恒. 一种基于钙离子的二次电池及其制备方法. CN: CN108630979B, 2021-06-15.[28] 唐永炳, 张阁, 欧学武. 过渡金属硫属化合物复合材料及其制备方法和应用. CN: CN110690419B, 2021-06-08.[29] 唐永炳, 吴越, 张苗. 硒基复合材料用作正极活性材料在钡离子电池中的应用、钡离子电池及其制备方法. CN: CN108054376B, 2021-05-25.[30] 杨扬, 李东, 唐永炳. 高臭氧催化活性金刚石电极及其制备方法和应用. CN: CN112795945A, 2021-05-14.[31] 唐永炳, 尹航, 张帆. 水系钙离子电池正极材料、水系钙离子电池正极和水系钙离子电池. CN: CN111063885B, 2021-05-14.[32] 唐永炳, 王勇, 张帆. 锌离子电池正极活性材料、正极材料、锌离子电池正极、锌离子电池及其制备方法和应用. CN: CN109671946B, 2021-04-20.[33] 唐永炳, 雷新, 张帆. 钾离子电池及其负极活性材料、负极、制备方法和应用. CN: CN109671948B, 2021-04-20.[34] 唐永炳, 仝雪峰, 李金芮, 张帆. 钠基双离子电池及其制备方法. CN: CN108172816B, 2021-04-20.[35] 唐永炳, 季必发, 张帆. 锌基双离子电池及其制备方法. CN: CN108242560B, 2021-04-20.[36] 唐永炳, 王琛, 王海涛. 一种钠离子二次电池负极的制备方法及钠离子二次电池. CN: CN112670452A, 2021-04-16.[37] 唐永炳, 谷继腾, 杨扬. 一种掺硼金刚石薄膜的制备方法. CN: CN109811328B, 2021-04-09.[38] 唐永炳, 陈闪闪, 谢呈德, 徐建龙. 一种金属型负极浆料、负极极片及二次电池. CN: CN112599760A, 2021-04-02.[39] 唐永炳, 李星星, 黄磊, 王陶, 杨扬. 金刚石管及其制备方法. CN: CN109972116B, 2021-03-23.[40] 唐永炳, 季必发, 张帆. 一种二次电池及其制备方法. CN: CN108511803B, 2021-02-26.[41] 唐永炳, 蔡菁华, 姚文娇. 一种新型二次电池及其制备方法. CN: CN112397768A, 2021-02-23.[42] 唐永炳, 王伟科, 姚文娇, 蔡菁华. 一种层状聚阴离子正极材料、制备方法、钾离子电池正极、钾离子电池及应用. CN: CN110492099B, 2021-02-19.[43] 唐永炳, 王敏, 刘齐荣. 铝碳复合材料及其制备方法、负极、二次电池和用电设备. CN: CN109671932B, 2021-02-19.[44] 唐永炳, 黄磊, 王陶, 李星星, 杨扬. 金刚石管及其改性方法. CN: CN109970055B, 2021-02-19.[45] 唐永炳, 张小龙, 张帆. 一种二次电池及其制备方法. CN: CN108470908B, 2021-02-09.[46] 唐永炳, 周小燕, 张苗. 金属材料用作锌离子水系超级电容器负极及锌离子水系混合超级电容器. CN: CN109637837B, 2021-01-19.[47] 唐永炳, 张松全, 王陶. 具有微纳米金刚石涂层的硬质合金刀具及其制备方法. CN: CN109972115B, 2021-01-19.[48] 唐永炳, 丁璇, 张帆. 钾基双离子电池及其制备方法. CN: CN108063217B, 2021-01-19.[49] 唐永炳, 吴石, 张帆. 钙离子二次电池及其制备方法. CN: CN108172896B, 2021-01-19.[50] 唐永炳, 吴越, 张苗. 丙烯酸乙酯类化合物用作电解液添加剂、电解液、基于铝负极的二次电池及其制备方法. CN: CN108172902B, 2021-01-19.[51] 唐永炳, 吴越, 张苗. 双离子电池及其制备方法. CN: CN108155408B, 2021-01-19.[52] 唐永炳, 欧学武, 张阁, 向立. 二次电池的制备方法. CN: CN110707364B, 2021-01-01.[53] 唐永炳, 杨凯, 刘齐荣. 正极活性材料、正极和二次电池. CN: CN112151795A, 2020-12-29.[54] 唐永炳, 韩承均, 张帆. 钙离子电池正极材料、正极和钙离子电池. CN: CN111029579B, 2020-12-25.[55] 唐永炳, 李娜, 张帆. 钾离子电池负极活性材料、钾离子电池负极材料、钾离子电池负极、钾离子电池及其应用. CN: CN109659528B, 2020-12-18.[56] 唐永炳, 徐子俊, 谢呈德, 祝佳丽, 张凡. 铝负极储能器件电解液、铝负极储能器件及其制备方法. CN: CN109546222B, 2020-12-18.[57] 严睿婷, 张帆, 张业正, 唐永炳. 合金化负极及其制备方法、锂离子电池. CN: CN112103473A, 2020-12-18.[58] 蒋春磊, 郑银银, 石磊, 唐永炳. 锂金属负极复合集流体及其制备方法、锂离子电池. CN: CN112072118A, 2020-12-11.[59] 唐永炳, 潘庆广, 仝兆鹏, 苏元强. 一种基于多羧酸钾盐石墨复合负极材料的制备及钾离子电池应用. CN202011423103.0, 2020-12-08.[60] 唐永炳, 潘庆广, 仝兆鹏, 苏元强. 一种基于多羧酸钾盐石墨复合负极材料的制备及钾离子电池应用. PCT/CN2020/134647, 2020-12-08.[61] 唐永炳, 张帆, 王勇. 自修复聚合物电解质基体及其制备方法、自修复聚合物电解质、锂离子电池及其应用. CN: CN109659605B, 2020-11-24.[62] 唐永炳, 丁璇, 季必发, 张帆. 锌基双离子电池及其制备方法. CN: CN108172833B, 2020-11-24.[63] 唐永炳, 张苗. 电解液、钠离子二次电池及其制备方法. CN: CN108172903B, 2020-11-03.[64] 唐永炳, 张苗, 于奥. 高分子涂层在铝负极中的应用、铝负极、其制备方法及二次电池. CN: CN108155363B, 2020-11-03.[65] 唐永炳, 吴南中, 姚文娇. 一种碱土金属六氟磷酸盐电解质及电解液制备方法. CN: CN111834673A, 2020-10-27.[66] 唐永炳, 王勇, 张帆. 钙离子电池负极活性材料、负极材料、钙离子电池负极、钙离子电池及其制备方法和应用. CN: CN109686936B, 2020-10-27.[67] 唐永炳, 祝佳丽, 谢呈德. 镀膜铝负极及其制备方法和应用、锂二次电池及其应用. CN: CN109244361B, 2020-10-27.[68] 唐永炳, 蒋春磊, 张晓明, 石磊. 复合材料及其制备方法和负极. CN: CN111816856A, 2020-10-23.[69] 唐永炳, 吴石, 张帆, 陈光海. 镁离子混合超级电容器及其制备方法. CN: CN107369565B, 2020-10-20.[70] 唐永炳, 张帆, 陈光海, 申京受. 电解液和锂离子二次电池及其制备方法. CN: CN108183261B, 2020-08-25.[71] 唐永炳, 丁璇, 张帆. 铝离子混合超级电容器及其制备方法. CN: CN108172415B, 2020-07-24.[72] 唐永炳, 李晋, 李翔, 龚德才, 欧学武. 一体化结构的隔膜负极材料及其制备方法和二次电池. CN: CN111446422A, 2020-07-24.[73] 唐永炳, 蒋春磊, 焦国华, 鲁远甫. 薄膜应力测试仪及其测试方法. CN: CN107219030B, 2020-07-21.[74] 唐永炳, 张阁, 欧学武. 预嵌锂负极的制备方法及制备得到的预嵌锂负极、储能器件、储能系统及用电设备. CN: CN109686923B, 2020-07-17.[75] 唐永炳, 姚文娇, 周小龙. 草酸盐材料、制备方法、用途、锂离子电池正极材料及锂离子电池. CN: CN111349005A, 2020-06-30.[76] 唐永炳, 吴南中, 姚文娇. 晶体材料及其制备方法和用途、钾离子电池正极材料及包括该正极材料的钾离子电池. CN: CN111349004A, 2020-06-30.[77] 唐永炳, 何海燕, 姚文娇. 晶体材料及制备方法和应用、电池正极活性材料、电池正极材料及电池和用电设备. CN: CN111349001A, 2020-06-30.[78] 唐永炳, 姚文娇, 宋天一, 吴南中. 晶体材料及其制备方法和用途、钠离子电池正极材料、钠离子电池和设备. CN: CN111348687A, 2020-06-30.[79] 唐永炳, 姜文尧, 姚文娇. 含锂过渡金属水合物及其制备方法. CN: CN111349002A, 2020-06-30.[80] 唐永炳, 何海燕, 姚文娇. KLi 3 Fe(C 2 O 4 ) 3 的制备方法、电池正极活性材料、电池及用电设备. CN: CN111349000A, 2020-06-30.[81] 唐永炳, 季必发, 姚文娇. 氟化草酸盐材料的应用以及包含氟化草酸盐材料的产品、制备方法及其用途. CN: CN111354943A, 2020-06-30.[82] 唐永炳, 周小龙. 薄膜涂层色度分析设备及其应用、薄膜涂层分类方法. CN: CN111337436A, 2020-06-26.[83] 唐永炳, 缪仕杰, 蒋春磊, 石磊. 疏水类金刚石复合涂层及其制备方法与疏水器件及其制备方法. CN: CN111334776A, 2020-06-26.[84] 唐永炳, 王陶, 黄磊, 李星星. 掺硼金刚石薄膜及其制备方法、油水分离元件、水处理电极及其制备方法与水处理装置. CN: CN111334779A, 2020-06-26.[85] 唐永炳, 王陶, 李星星, 黄磊. 具有多级次微纳结构的金刚石薄膜及其制备方法和应用. CN: CN111334777A, 2020-06-26.[86] 唐永炳, 黄磊, 王陶, 王星永. 钛合金复合材料及其制备方法、外科植入物和医疗器械. CN: CN111334778A, 2020-06-26.[87] 唐永炳, 王陶, 陈波, 欧学武, 徐阳, 孟醒, 黄磊. 锂硫电池隔膜及其制备方法、锂硫电池和电子装置. CN: CN111341971A, 2020-06-26.[88] 唐永炳, 周继伟, 周小龙. SnX 2 纳米纤维材料、制备方法、负极活性材料、负极、二次电池或电容器及其制备方法. CN: CN111321477A, 2020-06-23.[89] 唐永炳, 王星永, 王陶, 黄磊, 李星星. 复合金刚石涂层及其制备方法、微流体通道和微流体器件. CN: CN111321389A, 2020-06-23.[90] 唐永炳, 徐梦琦, 杨扬, 胡渊, 张文军. 一种二硼化钛/碳化硼复合电极及其制备方法与应用. 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CN: CN110600736A, 2019-12-20.[118] 杨扬, 唐永炳, 徐梦琦, 胡渊, 张文军. 硼掺杂金刚石负载金属单原子及其制备方法和应用. CN: CN110560034A, 2019-12-13.[119] 唐永炳, 陈波, 王陶, 杨扬. 碳化硅-纳米金刚石复合涂层、其制备方法和应用、冷挤压模具凸模及模具. CN: CN110565065A, 2019-12-13.[120] 唐永炳, 蒋春磊, 石磊. 具有颜色层的金刚石涂层刀具及其制备方法、加工设备. CN: CN110565051A, 2019-12-13.[121] 唐永炳, 谷继腾, 杨扬. 一种具有金刚石涂层的硬质合金件及其制备方法. CN: CN107034467B, 2019-12-03.[122] 唐永炳, 朱俞宣, 刘齐荣. 全固态二次电池及其制备工艺、电动汽车. CN: CN110518283A, 2019-11-29.[123] 杨扬, 唐永炳, 胡渊, 徐梦琦, 张文军. 光电催化的负载金属的硼掺杂金刚石及制备方法和应用. CN: CN110496616A, 2019-11-26.[124] 唐永炳, 李子豪, 杨扬, 谷继腾, 张文军. 一种高导热材料及其制备方法和应用. CN: CN110504229A, 2019-11-26.[125] 唐永炳, 刘齐荣, 石磊, 蒋春磊. 电池原位X射线衍射测试辅助装置. CN: CN209656593U, 2019-11-19.[126] 唐永炳, 陈波, 张松权, 王陶. 微-纳米复合金刚石涂层、其制备方法和应用、冷挤压模具冲头及模具. CN: CN110468385A, 2019-11-19.[127] 唐永炳, 陈波, 王陶, 杨扬. 热丝夹具和热丝沉积设备与其应用及刀具的制备方法. CN: CN110468386A, 2019-11-19.[128] 唐永炳, 谢呈德. 电池的充电方法及充电设备. CN: CN107516921B, 2019-11-15.[129] 唐永炳, 朱海莉, 张帆. 金属导电材料用作镁离子混合超级电容器负极和镁离子混合超级电容器及其制备方法. 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Lithium ion battery application of porous composite oxide microcubes prepared via metal-organic frameworks. JOURNAL OF POWER SOURCES[J]. 2015, 284: 109-114, http://dx.doi.org/10.1016/j.jpowsour.2015.02.155.[152] Kang, Wenpei, Tang, Yongbing, Li, Wenyue, Yang, Xia, Xue, Hongtao, Yang, Qingdan, Lee, ChunSing. High interfacial storage capability of porous NiMn2O4/C hierarchical tremella-like nanostructures as the lithium ion battery anode. NANOSCALE[J]. 2015, 7(1): 225-231, https://www.webofscience.com/wos/woscc/full-record/WOS:000346919200023.[153] Yang, Yang, Yuen, MukFung, Chen, Xianfeng, Xu, Shanshan, Tang, Yongbing, Zhang, Wenjun. Fabrication of arrays of high-aspect-ratio diamond nanoneedles via maskless ECR-assisted microwave plasma etching. CRYSTENGCOMM[J]. 2015, 17(14): 2791-2800, https://www.webofscience.com/wos/woscc/full-record/WOS:000351764600003.[154] Xu, Jun, Yang, Xia, Yang, QingDan, Huang, Xing, Tang, Yongbing, Zhang, Wenjun, Lee, ChunSing. Controllable Synthesis of Bandgap-Tunable CuSxSe1-x Nanoplate Alloys. CHEMISTRYANASIANJOURNAL[J]. 2015, 10(7): 1490-1495, https://www.webofscience.com/wos/woscc/full-record/WOS:000357206500008.[155] High interfacial storage capability of porous NiMn2O4/C hierarchical tremella-like nanostructures as the lithium ion battery anode. 2015, 7(1): 225-231, http://ir.siat.ac.cn:8080/handle/172644/6484.[156] Kang, Wenpei, Yu, Denis Yau Wai, Li, Wenyue, Zhang, Zhenyu, Yang, Xia, Ng, TszWai, Zou, Rujia, Tang, Yongbing, Zhang, Wenjun, Lee, ChunSing. Nanostructured porous manganese carbonate spheres with capacitive effects on the high lithium storage capability. NANOSCALE[J]. 2015, 7(22): 10146-10151, https://www.webofscience.com/wos/woscc/full-record/WOS:000355560200025.[157] Li, Zhangpeng, Xue, Hongtao, Wang, Jinqing, Tang, Yongbing, Lee, ChunSing, Yang, Shengrong. 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Facile solution synthesis without surfactant assistant for ultra long Alq3 sub-microwires and their enhanced field emission and waveguide properties. JOURNAL OF MATERIALS CHEMISTRY[J]. 2010, 20(15): 3006-3010, https://www.webofscience.com/wos/woscc/full-record/WOS:000276152100014.[176] Dou, Weidong, Tang, Yongbing, Lee, C S, Bao, S N, Lee, S T. Investigation on the orderly growth of thick zinc phthalocyanine films on Ag(100) surface. JOURNAL OF CHEMICAL PHYSICS[J]. 2010, 133(14): https://www.webofscience.com/wos/woscc/full-record/WOS:000283200400050.[177] Xu, Jun, Luan, ChunYan, Tang, YongBing, Chen, Xue, Zapien, Juan Antnio, Zhang, WenJun, Kwong, HoiLun, Meng, XiangMin, Lee, ShuitTong, Lee, ChunSing. Low-Temperature Synthesis of CuInSe2 Nanotube Array on Conducting Glass Substrates for Solar Cell Application. ACS NANO[J]. 2010, 4(10): 6064-6070, https://www.webofscience.com/wos/woscc/full-record/WOS:000283453700076.[178] Yuan, G D, Zhou, Y B, Guo, C S, Zhang, W J, Tang, Y B, Li, Y Q, Chen, Z H, He, Z B, Zhang, X J, Wang, P F, Bello, I, Zhang, R Q, Lee, C S, Lee, S T. Tunable Electrical Properties of Silicon Nanowires via Surface-Ambient Chemistry. ACS NANO[J]. 2010, 4(6): 3045-3052, https://www.webofscience.com/wos/woscc/full-record/WOS:000278888600012.[179] Song, H S, Zhang, W J, Tang, Y B, He, Z B, Yuan, G D, Fan, X, Lee, C S, Bello, I, Lee, S T. Field Electron Emission of ZnO Nanowire Pyramidal Bundle Arrays. JOURNAL OF NANOSCIENCE AND NANOTECHNOLOGY[J]. 2010, 10(4): 2360-2365, https://www.webofscience.com/wos/woscc/full-record/WOS:000273984900012.[180] Tang, YongBing, Lee, ChunSing, Xu, Jun, Liu, ZengTao, Chen, ZhenHua, He, Zhubing, Cao, YuLin, Yuan, Guodong, Song, Haisheng, Chen, Limiao, Luo, Linbao, Cheng, HuiMing, Zhang, WenJun, Bello, Igor, Lee, ShuitTong. Incorporation of Graphenes in Nanostructured TiO2 Films via Molecular Grafting for Dye-Sensitized Solar Cell Application. ACS NANO[J]. 2010, 4(6): 3482-3488, http://www.irgrid.ac.cn/handle/1471x/410568.[181] Xu, Jun, Lee, ChunSing, Tang, YongBing, Chen, Xue, Chen, ZhenHua, Zhang, WenJun, Lee, ShuitTong, Zhang, Weixin, Yang, Zeheng. Large-Scale Synthesis and Phase Transformation of CuSe, CuInSe2, and CuInSe2/CuInS2 Core/Shell Nanowire Bundles. ACS NANO[J]. 2010, 4(4): 1845-1850, https://www.webofscience.com/wos/woscc/full-record/WOS:000276956800011.[182] Cao, Y L, Tang, Y B, Liu, Y, Liu, Z T, Luo, L B, He, Z B, Jie, J S, Vellaisamy, Roy, Zhang, W J, Lee, C S, Lee, S T. Coaxial nanocables of p-type zinc telluride nanowires sheathed with silicon oxide: synthesis, characterization and properties. NANOTECHNOLOGY[J]. 2009, 20(45): https://www.webofscience.com/wos/woscc/full-record/WOS:000270904600022.[183] 唐永炳. Vertically aligned ZnO nanorod arrays sensitized with Au nanoparticles for Schottky barrier photovoltaic cells. J. Phys. Chem. C. 2009, [184] Xu, Jun, Tang, YongBing, Zhang, Weixin, Lee, ChunSing, Yang, Zeheng, Lee, ShuitTong. Fabrication of Architectures with Dual Hollow Structures: Arrays of Cu2O Nanotubes Organized by Hollow Nanospheres. CRYSTAL GROWTH & DESIGN[J]. 2009, 9(10): 4524-4528, https://www.webofscience.com/wos/woscc/full-record/WOS:000270461400048.[185] Tang, Y B, Lee, C S, Chen, Z H, Yuan, G D, Kang, Z H, Luo, L B, Song, H S, Liu, Y, He, Z B, Zhang, W J, Elello, I, Lee, S T. High-Quality Graphenes via a Facile Quenching Method for Field-Effect Transistors. NANO LETTERS[J]. 2009, 9(4): 1374-1377, https://www.webofscience.com/wos/woscc/full-record/WOS:000265030000017.[186] Yuan, G D, Zhang, W J, Yang, Y, Tang, Y B, Li, Y Q, Wang, J X, Meng, X M, He, Z B, Wu, C M L, Bello, I, Lee, C S, Lee, S T. Graphene sheets via microwave chemical vapor deposition. CHEMICAL PHYSICS LETTERS[J]. 2009, 467(4-6): 361-364, http://dx.doi.org/10.1016/j.cplett.2008.11.059.[187] 唐永炳. Control synthesis of ZnO nanowire arrays on Al:ZnO buffer layer and their enhanced field emissions. JAPPLPHYS. 2009, [188] He, Z B, Zhang, W J, Tang, Y B, Wang, H B, Cao, Y L, Song, H S, Bello, I, Lee, C S, Lee, S T. Crossbar heterojunction field effect transistors of CdSe:In nanowires and Si nanoribbons. APPLIED PHYSICS LETTERS[J]. 2009, 95(25): https://www.webofscience.com/wos/woscc/full-record/WOS:000273037700046.[189] Chen, Z H, Tang, Y B, Liu, Y, Kang, Z H, Zhang, X J, Fan, X, Lee, C S, Bello, I, Zhang, W J, Lee, S T. Dye degradation induced by hydrogen-terminated silicon nanowires under ultrasonic agitations. JOURNAL OF APPLIED PHYSICS[J]. 2009, 105(3): https://www.webofscience.com/wos/woscc/full-record/WOS:000263409700096.[190] Tang, YongBing, Bo, XiangHui, Lee, ChunSing, Cong, HongTao, Cheng, HuiMing, Chen, ZhenHua, Zhang, WenJun, Bello, Igor, Lee, ShuitTong. Controllable Synthesis of Vertically Aligned p-Type GaN Nanorod Arrays on n-Type Si Substrates for Heterojunction Diodes. ADVANCEDFUNCTIONALMATERIALS[J]. 2008, 18(21): 3515-3522, http://www.irgrid.ac.cn/handle/1471x/412195.[191] Tang, Y B, Chen, Z H, Song, H S, Lee, C S, Cong, H T, Cheng, H M, Zhang, W J, Bello, I, Lee, S T. Vertically Aligned p-Type Single-Crystalline GaN Nanorod Arrays on n-Type Si for Heterojunction Photovoltaic Cells. NANO LETTERS[J]. 2008, 8(12): 4191-4195, http://www.irgrid.ac.cn/handle/1471x/412196.[192] Tang, YongBing, Cong, HongTao, Cheng, HuiMing. Synthesis and properties of one-dimensional aluminum nitride nanostructures. NANO[J]. 2007, 2(6): 307-331, http://dx.doi.org/10.1142/S1793292007000763.[193] Tang, Y B, Liu, Y Q, Sun, C H, Cong, H T. AlN nanowires for Al-based composites with high strength and low thermal expansion. 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UV-to-IR Highly Transparent Ultrwathin Diamond Nanofilms with Intriguing Performances: Anti-fogging, Self-cleaning and Self-lubricating. APPLIED SURFACE SCIENCE. http://dx.doi.org/10.1016/j.apsusc.2020.146733.[204] Min Wang, Qirong Liu, Guangming Wu, Jianmin Ma, Yongbing Tang. Coral-like and binder-free carbon nanowires for potassium dual-ion batteries with superior rate capability and long-term cycling life. GREEN ENERGY & ENVIRONMENT. http://dx.doi.org/10.1016/j.gee.2021.03.007.
发表著作
(1) 纳米科学与技术, Nano Science and Technology , Springer, 2008-06, 第 1 作者
科研活动
代表性科研项目
( 1 ) 多种衬底上AlN一维纳米结构阵列的大面积可控制备及其掺杂与器件应用研究, 负责人, 国家任务, 2014-01--2016-12( 2 ) 串联式一维核壳结构纳米阵列太阳能电池的设计、制备及光伏性能, 参与, 国家任务, 2013-01--2016-12( 3 ) 金刚石与立方氮化硼功能薄膜材料的产业化应用, 参与, 地方任务, 2013-07--2018-12( 4 ) 一维氮化铝纳米材料的合成及其在聚合物复合材料的应用研究, 负责人, 地方任务, 2015-01--2016-12( 5 ) 功能全自动薄膜应力测试仪的研制, 负责人, 中国科学院计划, 2015-01--2016-12( 6 ) 氮化铝纳米纤维增强高分子电子封装复合材料的制备及其复合机理研究, 负责人, 地方任务, 2015-01--2017-01( 7 ) 深圳航空航天超硬涂层材料与技术工程实验室, 负责人, 地方任务, 2016-01--2017-12( 8 ) 海洋船舶环保防污膜关键技术研发, 负责人, 地方任务, 2015-08--2017-08( 9 ) 广东省金刚石与立方氮化硼超硬涂层工程技术研究中心, 负责人, 地方任务, 2015-10--2100-01( 10 ) 新型涂层材料与技术研发, 负责人, 企业委托, 2015-10--2017-10( 11 ) 重20160001 难加工材料用高性能涂层刀具的关键技术研发, 参与, 地方任务, 2016-07--2018-07( 12 ) 新型高效低成本储能电池技术联合实验室, 负责人, 企业委托, 2017-05--2019-05( 13 ) 重20170139 新型高功率铝-石墨二次电池关键技术研发, 参与, 地方任务, 2018-01--2019-12( 14 ) 基于非贵金属负极的高性能电化学储能器件应用关键技术研发, 负责人, 地方任务, 2018-01--2019-12( 15 ) 多功能全自动薄膜应力测试仪研制, 负责人, 地方任务, 2017-01--2018-12( 16 ) 新型双离子电池及其电极材料研究, 负责人, 国家任务, 2019-01--2021-12( 17 ) 廉价金属铝基负极高效低沉本储能器件研发, 负责人, 中国科学院计划, 2018-01--2018-12( 18 ) 高效低成本储能器件关键技术研发团队, 参与, 地方任务, 2017-11--2022-10( 19 ) 薄膜材料产业化应用, 参与, 地方任务, 2013-07--2018-06( 20 ) 用于野外生存的仿生多级次金刚石薄膜及污水处理性能研究, 负责人, 国家任务, 2018-10--2020-12( 21 ) 基于廉价金属负极的高性能储能器件应用关键技术研发, 负责人, 地方任务, 2018-09--2021-12( 22 ) 新型高能量低成本铝基电池研发(广东省重点领域研发计划专项-新能源汽车), 负责人, 地方任务, 2019-05--2022-04( 23 ) 室温钙离子电池钙负极界面膜形成机理及改性研究, 负责人, 国家任务, 2020-01--2023-12( 24 ) 低成本长寿命大规模储能技术项目, 负责人, 企业委托, 2019-10--2020-11( 25 ) 中国科学院深圳先进技术研究院—湖南久森新能源有限公司 中科久森新能源技术联合实验室, 负责人, 企业委托, 2020-03--2023-03( 26 ) 2019年广东特支计划领军人才, 负责人, 地方任务, 2020-08--2023-08( 27 ) 基2020N034 自支撑超薄金属纳米片的制备及性能研究, 负责人, 地方任务, 2020-11--2023-10( 28 ) 双离子电池关键材料与器件, 负责人, 国家任务, 2022-01--2026-12
参与会议
(1)新型低成本环保聚阴离子正极材料 先进功能材料研讨会 2021-05-21(2)新型双离子电池 第二届国际电化学能源系统会议 2021-05-14(3)材料表面与界面结构和性能 2020中国有色金属学会青年科技论坛 2020-08-19(4)Novel Energy Storage Devices Based on Multi-Ion Strategy 电池研讨会:下一代能源应用材料 2019-11-18(5)X-ray Absorption Spectroscopy application on new energy storage devices and materials 2019 亚洲X射线吸收光谱研讨会 2019-08-28(6)Research on novel energy storage devices and materials 第十届全国无机化学学术会议 2019-08-20(7)Research on novel energy storage devices and materials 宁波固态电池会议 2019-08-17(8)Research on new energy storage devices and materials 2019电化学能源国际会议 2019-08-04(9)Research on new energy storage devices and materials 秦皇岛高端材料化学论坛 2019-07-16(10)The Way to Calcium-ion Energy Storage Technology 第四届青岛储能技术论坛暨第一届多价金属离子及多电子转移电池会议 2019-05-11(11)The Way to Calcium-ion Energy Storage Technology WILEY-黄鹤楼先进纳米材料高端论坛 2019-05-10(12)The Way to Calcium-ion Energy Storage Technology 自然学术会议 新兴材料与器件: 2019-04-12(13)一种环保节能、低成本铝薄膜-石墨双离子电池 第二届中国科大节能环保产业校友高峰论坛 2016-07-29(14)Recent Progress of Aluminum-Graphite Dual-Ion Battery 第8届薄膜与涂层技术进展国际学术会议 2016-07-12(15)Core-Shell Si/C Nanostructures with Enhanced Performance as Lithium Ion Battery Anodes 中国化学会第29届学术年会中新青年化学家论坛 唐永炳、李文跃 2014-08-05
合作情况
中心与以下单位都有密切学术合作与交流:
香港城市大学 City University of Hong Kong;
英国圣安德鲁斯大学 University of St Andrews;
泰国国立同步辐射光源研究所 Synchrotron Light Research Institute;
澳洲格里菲斯大学 Griffith University;
广东天劲新能源股份有限公司 TeamGiant
项目协作单位
指导正式学生
已指导学生
仝雪峰 硕士研究生 085204-材料工程
李娜 硕士研究生 070304-物理化学
吴南中 硕士研究生 070304-物理化学
季必发 博士研究生 070304-物理化学
雷新 硕士研究生 070304-物理化学
张晓明 硕士研究生 085204-材料工程
谢东豪 硕士研究生 085204-材料工程
兰元其 硕士研究生 085204-材料工程
苟佳利 硕士研究生 085204-材料工程
现指导学生
许欢 硕士研究生 085600-材料与化工
吴南中 博士研究生 070304-物理化学
武晨 硕士研究生 085600-材料与化工
梁潇 硕士研究生 085600-材料与化工
雷新 博士研究生 070304-物理化学
汤彬 硕士研究生 070300-化学
林雨薇 硕士研究生 085600-材料与化工
刘志鹏 硕士研究生 085600-材料与化工