專家信息：

陳克求，男，博士�，F(xiàn)任湖南大學(xué)物理與微電子科學(xué)學(xué)院副院長(zhǎng)，教授、博士生導(dǎo)師。

主要教育經(jīng)歷：

1982．9-1986．7:本科，國(guó)防科技大學(xué)，應(yīng)用物理系，激光技術(shù)專業(yè)；

1995．9-1998．7:碩士，湖南大學(xué)應(yīng)用物理系，理論物理專業(yè)；

1998．9-2001．7:博士，中國(guó)科學(xué)院物理研究所，凝聚態(tài)物理專業(yè)。

主要工作經(jīng)歷：

2001-2003：博士后，清華大學(xué)物理系凝聚態(tài)物理研究所；

2003-2005：副研究員，中國(guó)科學(xué)院化學(xué)研究所有機(jī)固體重點(diǎn)實(shí)驗(yàn)室；

2005-2017：教授、博士生導(dǎo)師，湖南大學(xué)物理與微電子科學(xué)學(xué)院；

2017-2024：教授、博士生導(dǎo)師，副院長(zhǎng)，湖南大學(xué)物理與微電子科學(xué)學(xué)院；

2024-現(xiàn)在： 教授、博士生導(dǎo)師，湖南大學(xué)物理與微電子科學(xué)學(xué)院。

學(xué)術(shù)兼職：

1、湖南省物理學(xué)會(huì)副理事長(zhǎng)。

2、高等學(xué)校計(jì)算物理學(xué)會(huì)常務(wù)理事。

3、擔(dān)任教育部高等學(xué)校物理學(xué)類專業(yè)教學(xué)指導(dǎo)委員會(huì)中南地區(qū)工作委員會(huì)副主任委員。

4、湖南省第十一屆政協(xié)委員。

5、湖南省第十二屆政協(xié)委員。

6、《Nanomaterials》、《Applied Physics》、《Modern Physics》、《Advances in Condensed Matter Physics》編委。

教學(xué)情況

主要講授課程：

本科生：《量子力學(xué)》（湖南省一流課程）

研究生：《高等量子力學(xué)》（湖南省研究生優(yōu)質(zhì)課程）、《介觀物理與納米電子學(xué)》、《量子器件物理》。

培養(yǎng)研究生情況：

培養(yǎng)研究生數(shù)十名。

科學(xué)研究：

主要研究方向：

（1）熱輸運(yùn)理論與熱調(diào)控器件；（2）納米與分子電子學(xué)；（3）熱電轉(zhuǎn)換與新能源；（4）光電子器件計(jì)算設(shè)計(jì)；（5）各類生活垃圾與醫(yī)廢熱解焚化原理研究與相關(guān)裝備理論設(shè)計(jì)。

研究領(lǐng)域：

學(xué)科專業(yè)領(lǐng)域：物理學(xué)

科研項(xiàng)目：

自2005年從中科院化學(xué)所調(diào)入湖南大學(xué)工作以來(lái),作為負(fù)責(zé)人先后主持國(guó)家自然科學(xué)基金面上項(xiàng)目和重大研究計(jì)劃培育項(xiàng)目共9項(xiàng)、國(guó)家科技部973課題子項(xiàng)目3項(xiàng)、國(guó)家重點(diǎn)研發(fā)計(jì)劃子課題2項(xiàng)、高等學(xué)校博士點(diǎn)基金博導(dǎo)項(xiàng)目（優(yōu)先發(fā)展領(lǐng)域）1項(xiàng)、高等學(xué)校博士點(diǎn)基金博導(dǎo)項(xiàng)目1項(xiàng)、湖南省自然科學(xué)基金重點(diǎn)項(xiàng)目2項(xiàng)、橫向項(xiàng)目多項(xiàng)，參與完成國(guó)家重大研究計(jì)劃重點(diǎn)項(xiàng)目1項(xiàng)。

學(xué)術(shù)成果：

在國(guó)際重要SCI期刊上發(fā)表學(xué)術(shù)論文350余篇，H因子55；近幾年連續(xù)入選愛(ài)思唯爾高被引學(xué)者（2020，2021，2022，2023），近幾年連續(xù)入選全球前2%頂尖科學(xué)獎(jiǎng)榜單。

發(fā)明專利：

實(shí)用新型：

[1]姚遠(yuǎn), 陳克求, 歐陽(yáng)星星, 任昀. 熱解實(shí)驗(yàn)產(chǎn)物收集系統(tǒng)[P]. 湖南省: CN219377070U, 2023-07-21.

[2]彭娜, 陳克求, 陳慶平, 陳鵬輝, 熊艷. 一種加長(zhǎng)負(fù)壓裂解焚化爐[P]. 北京市: CN218510893U, 2023-02-21.

[3]陳子經(jīng), 曾彥杰, 陳慶平, 陳克求, 劉衛(wèi)國(guó), 曾花. 一種高效農(nóng)村生活垃圾處理裝置[P]. 廣東省: CN218459625U, 2023-02-10.

[4]彭娜, 陳克求, 陳慶平, 姚遠(yuǎn), 彭江艷. 一種帶風(fēng)冷箱的負(fù)壓裂解焚化爐[P]. 北京市: CN218345389U, 2023-01-20.

[5]曾彥杰, 陳慶平, 陳克求, 程煜, 曾花. 一種防止有害氣體外泄的垃圾處理設(shè)備[P]. 廣東省: CN218307113U, 2023-01-17.

[6]彭娜, 陳慶平, 陳克求, 姚遠(yuǎn), 任昀. 一種生物體負(fù)壓裂解火化裝置[P]. 北京市: CN218269076U, 2023-01-10.

[7]陳慶平, 彭娜, 陳克求, 李潔偉, 陳子經(jīng). 一種垃圾焚燒處理系統(tǒng)[P]. 北京市: CN218269082U, 2023-01-10.

[8]陳慶平, 彭娜, 歐陽(yáng)曉平, 陳克求, 陳子經(jīng). 一種燃?xì)庠頪P]. 北京市: CN218269174U, 2023-01-10.

[9]陳慶平, 彭娜, 陳克求, 張寧科, 李潔偉. 一種灶芯底部分布式進(jìn)氣的燃?xì)庠頪P]. 北京市: CN218269178U, 2023-01-10.

[10]陳慶平, 陳克求, 彭娜, 熊艷, 董航. 一種多孔灶除塵除濕熱解爐[P]. 北京市: CN218269083U, 2023-01-10.

[11]曾花, 陳慶平, 陳克求, 程煜, 陳子經(jīng). 一種生活垃圾處理設(shè)備用裂解氣化裝置[P]. 廣東省: CN217816761U, 2022-11-15.

[12]劉衛(wèi)國(guó), 陳慶平, 陳克求, 程煜, 曾越. 一種聚合物垃圾處理用裂解氣化裝置[P]. 廣東省: CN217816762U, 2022-11-15.

[13]陳克求, 任昀, 陳慶平, 李媛, 李華輝, 陳婕. 一體式氣化爐[P]. 湖南省: CN210532380U, 2020-05-15.

[14]陳克求, 任昀, 陳慶平, 李媛, 李華輝, 陳婕. 雙單元垃圾氣化焚化爐[P]. 湖南省: CN210267246U, 2020-04-07.

[15]陳慶平, 陳克求, 任昀, 李媛, 陳婕, 李華輝, 顏港歸. 混合燃燒灶及垃圾氣化焚化爐[P]. 湖南省: CN210267247U, 2020-04-07.

[16]陳克求, 任昀, 陳慶平, 李媛, 李華輝, 陳婕. 垃圾氣化子母爐一體設(shè)備[P]. 湖南省: CN210267249U, 2020-04-07.

[17]陳慶平, 陳克求, 任昀, 李媛, 陳婕, 李華輝, 顏港歸. 垃圾氣化焚化爐[P]. 湖南省: CN210267250U, 2020-04-07.

[18]陳慶平, 陳克求, 任昀, 李媛, 陳婕, 李華輝, 顏港歸. 配氣盤及具有其的氣化爐[P]. 湖南省: CN210085381U, 2020-02-18.

[19]陳克求, 任昀, 陳慶平, 李媛, 李華輝, 陳婕. 氣化爐配套熱水鍋爐成套設(shè)備[P]. 湖南省: CN210088867U, 2020-02-18.

[20]陳慶平, 陳克求, 任昀, 李媛, 陳婕, 李華輝, 顏港歸. 垃圾焚化裝置[P]. 湖南省: CN210069870U, 2020-02-14.

[21]段杰輝, 陳克求, 陳慶平, 曹貴華, 陳石玉, 胡湘榮, 劉洪成. 一種煙氣凈化裝置[P]. 湖南: CN206045698U, 2017-03-29.

[22]陳克求, 段杰輝, 陳慶平, 曹貴華, 陳石玉, 胡湘榮, 劉洪成. 一種燃?xì)夤艿篱_(kāi)關(guān)裝置[P]. 湖南: CN206017897U, 2017-03-15.

[23]段杰輝, 陳克求, 陳慶平, 曹貴華, 陳石玉, 胡湘榮. 垃圾氣化處理裝置[P]. 湖南: CN205974422U, 2017-02-22.

[24]段杰輝, 陳慶平, 陳克求, 曹貴華, 陳石玉, 胡湘榮. 生物質(zhì)氣化裝置[P]. 湖南: CN205974423U, 2017-02-22.

[25]陳慶平, 陳昌永, 陳克求, 劉海力. 一種可連續(xù)出灰的氣化爐[P]. 湖南: CN203382721U, 2014-01-08.

[26]陳慶平, 陳昌永, 陳克求, 劉海力. 一種氣化爐絞龍除灰裝備[P]. 湖南: CN203382723U, 2014-01-08.

[27]陳慶平, 陳克求, 譚哲, 陳碩軍, 蔣青峰. 一種氣化爐刮渣刀[P]. 湖南: CN203382727U, 2014-01-08.

[28]陳慶平, 陳昌永, 陳克求, 劉海力. 氣化爐破渣裝備[P]. 湖南: CN203382728U, 2014-01-08.

[29]陳克求, 陳慶平. 多功能生物質(zhì)氣化爐[P]. 湖南: CN203144346U, 2013-08-21.

[30]陳克求, 陳慶平. 一種上吸式氣化爐旋轉(zhuǎn)壓料裝置[P]. 湖南: CN203007223U, 2013-06-19.

[31]陳克求, 陳慶平. 一種上吸式氣化爐推拉壓料裝置[P]. 湖南: CN203007224U, 2013-06-19.

[32]陳慶平, 陳克求. 生物質(zhì)氣化爐煙氣助燒器[P]. 湖南: CN202973123U, 2013-06-05.

[33]陳慶平, 陳克求. 生物質(zhì)氣化爐不規(guī)則物料進(jìn)料裝置[P]. 湖南: CN202936385U, 2013-05-15.

[34]陳慶平, 陳克求. 生物質(zhì)氣化蒸烤鮮筍裝置[P]. 湖南: CN202932012U, 2013-05-15.

[35]陳慶平, 陳克求. 生物質(zhì)氣化熱交換箱[P]. 湖南: CN202938503U, 2013-05-15.

發(fā)明公開(kāi)：

[1]陳慶平, 陳克求, 曾花, 程煜, 陸瓊芝. 一種裂解氣化型垃圾無(wú)害化處理綜合利用裝置及其處理工藝[P]. 廣東省: CN115046206A, 2022-09-13.

[2]程煜, 陳慶平, 陳克求, 曾花, 曾彥杰. 一種可凈化燃?xì)獾纳�物質(zhì)氣化設(shè)備[P]. 廣東省: CN114891540A, 2022-08-12.

[3]彭娜, 陳慶平, 陳克求, 姚遠(yuǎn), 任昀. 一種生物體負(fù)壓裂解火化裝置[P]. 北京市: CN114001354A, 2022-02-01.

[4]陳克求, 任昀, 陳慶平, 李媛, 李華輝, 陳婕. 氣化爐配套熱水鍋爐成套設(shè)備[P]. 湖南省: CN110296412A, 2019-10-01.

[5]陳慶平, 陳克求, 任昀, 李媛, 陳婕, 李華輝, 顏港歸. 氣化爐配套燃?xì)庠畛商籽b備[P]. 湖南省: CN110081441A, 2019-08-02.

[6]陳克求, 任昀, 陳慶平, 李媛, 李華輝, 陳婕. 一體式氣化爐[P]. 湖南省: CN110006048A, 2019-07-12.

[7]陳慶平, 陳克求, 任昀, 李媛, 陳婕, 李華輝, 顏港歸. 混合燃燒灶及垃圾氣化焚化爐[P]. 湖南省: CN110006053A, 2019-07-12.

[8]陳慶平, 陳克求, 任昀, 李媛, 陳婕, 李華輝, 顏港歸. 垃圾焚化裝置及垃圾焚化處理方法[P]. 湖南省: CN110006054A, 2019-07-12.

[9]陳克求, 任昀, 陳慶平, 李媛, 李華輝, 陳婕. 雙單元垃圾氣化焚化爐及垃圾處理方法[P]. 湖南省: CN110006055A, 2019-07-12.

[10]陳慶平, 陳克求, 任昀, 李媛, 陳婕, 李華輝, 顏港歸. 垃圾氣化焚化爐及垃圾處理方法[P]. 湖南省: CN110006056A, 2019-07-12.

[11]陳克求, 任昀, 陳慶平, 李媛, 李華輝, 陳婕. 垃圾氣化子母爐一體設(shè)備及垃圾氣化處理方法[P]. 湖南省: CN110006057A, 2019-07-12.

[12]陳慶平, 陳克求, 任昀, 李媛, 陳婕, 李華輝, 顏港歸. 配氣盤及具有其的氣化爐[P]. 湖南省: CN109943363A, 2019-06-28.

[13]段杰輝, 陳慶平, 陳克求, 曹貴華, 陳石玉, 胡湘榮. 生物質(zhì)氣化裝置及方法[P]. 湖南: CN106350118A, 2017-01-25.

[14]段杰輝, 陳克求, 陳慶平, 曹貴華, 陳石玉, 胡湘榮. 垃圾氣化處理裝置及方法[P]. 湖南: CN106281467A, 2017-01-04.

[15]段杰輝, 陳克求, 陳慶平, 曹貴華, 陳石玉, 胡湘榮, 劉洪成. 一種煙氣凈化裝置[P]. 湖南: CN106178798A, 2016-12-07.

[16]陳慶平, 陳克求. 污泥氣化處理工藝[P]. 湖南: CN103304116A, 2013-09-18.

[17]陳慶平, 陳昌永, 陳克求, 劉海力. 一種氣化爐絞龍除灰裝置[P]. 湖南: CN103289749A, 2013-09-11.

[18]陳慶平, 陳昌永, 陳克求, 劉海力. 氣化爐破渣裝置[P]. 湖南: CN103289752A, 2013-09-11.

[19]陳克求, 陳慶平. 多功能生物質(zhì)氣化裝置[P]. 湖南: CN102994155A, 2013-03-27.

[20]陳克求, 陳慶平. 一種上吸式氣化爐進(jìn)料箱[P]. 湖南: CN102994159A, 2013-03-27.

[21]陳慶平, 陳克求. 生物質(zhì)氣化炭化料生產(chǎn)工藝[P]. 湖南: CN102942963A, 2013-02-27.

[22]陳慶平, 陳克求. 生物質(zhì)氣化蒸烤鮮筍工藝[P]. 湖南: CN102940168A, 2013-02-27.

[23]陳慶平, 陳克求. 生物質(zhì)氣化熱空氣裝置[P]. 湖南: CN102944060A, 2013-02-27.

[24]陳慶平, 陳克求. 生物質(zhì)氣化爐底部推拉式出灰裝置[P]. 湖南: CN102925217A, 2013-02-13.

[25]陳慶平, 陳克求. 生物質(zhì)氣化爐進(jìn)料斗[P]. 湖南: CN102899092A, 2013-01-30.

發(fā)明授權(quán)：

[1]陳克求, 任昀, 陳慶平, 李媛, 李華輝, 陳婕. 一體式氣化爐[P]. 湖南省: CN110006048B, 2024-09-27.

[2]陳克求, 任昀, 陳慶平, 李媛, 李華輝, 陳婕. 氣化爐配套熱水鍋爐成套設(shè)備[P]. 湖南省: CN110296412B, 2024-09-20.

[3]陳慶平, 陳克求, 任昀, 李媛, 陳婕, 李華輝, 顏港歸. 混合燃燒灶及垃圾氣化焚化爐[P]. 湖南省: CN110006053B, 2024-08-02.

[4]陳慶平, 陳克求, 任昀, 李媛, 陳婕, 李華輝, 顏港歸. 垃圾氣化焚化爐及垃圾處理方法[P]. 湖南省: CN110006056B, 2024-08-02.

[5]陳慶平, 陳克求, 任昀, 李媛, 陳婕, 李華輝, 顏港歸. 垃圾焚化裝置及垃圾焚化處理方法[P]. 湖南省: CN110006054B, 2024-08-02.

[6]陳克求, 任昀, 陳慶平, 李媛, 李華輝, 陳婕. 雙單元垃圾氣化焚化爐及垃圾處理方法[P]. 湖南省: CN110006055B, 2024-06-07.

[7]陳克求, 任昀, 陳慶平, 李媛, 李華輝, 陳婕. 垃圾氣化子母爐一體設(shè)備及垃圾氣化處理方法[P]. 湖南省: CN110006057B, 2024-06-07.

[8]程煜, 陳慶平, 陳克求, 曾花, 曾彥杰. 一種可凈化燃?xì)獾纳�物質(zhì)氣化設(shè)備[P]. 廣東省: CN114891540B, 2023-06-13.

[9]段杰輝, 陳慶平, 陳克求, 曹貴華, 陳石玉, 胡湘榮. 生物質(zhì)氣化裝置及方法[P]. 湖南省: CN106350118B, 2022-03-18.

[10]陳慶平, 陳克求, 任昀, 李媛, 陳婕, 李華輝, 顏港歸. 氣化爐配套燃?xì)庠畛商籽b備[P]. 湖南省: CN110081441B, 2021-10-22.

[11]陳慶平, 陳克求. 生物質(zhì)氣化蒸烤鮮筍工藝[P]. 湖南省: CN102940168B, 2014-03-12.

外觀設(shè)計(jì)：

[1]陳慶平, 陳克求. 方形一體式生物質(zhì)氣化爐[P]. 湖南: CN302436601S, 2013-05-15.

論文專著：

發(fā)表期刊部分論文： 

在國(guó)際有影響的SCI源刊上發(fā)表了240余篇學(xué)術(shù)論文，SCI引用近6000次。

[1]Zeng, Yu-Jia; Feng, Ye-Xin; Tang, Li-Ming; Chen, Ke-Qiu*.Effect of out-of-plane strain on the phonon structures and anharmonicity of twisted multilayer graphene.Applied Physics Letters, 2021, 118(18): 183103.

[2]Jia, Pin-Zhen; Wu, Dan; Zhang, Qian-Qian; Zhou, Wu-Xing; Fan, Zhi-Qiang; Feng, Ye-Xin; Tang, Li-Ming; Chen, Ke-Qiu.Design of Thermal Metamaterials with Excellent Thermal Control Functions by Using Functional Nanoporous Graphene.Physica Status Solidi-Rapid Research Letters, 2020, 2000333.

[3]Peng, Ya-Nan; Yu, Ji-Feng; Cao, Xuan-Hao; Wu, Dan; Jia, Pin-Zhen; Zhou, Wu-Xing; Chen, Ke-Qiu.An efficient mechanism for enhancing the thermoelectricity of twin graphene nanoribbons by introducing defects.Physica E: Low-Dimensional Systems and Nanostructures , 2020, 122: 114160.

[4]Zhang, Qian-Qian; Jia, Pin-Zhen; Chen, Xue-Kun; Zhou, Wu-Xing; Chen, Ke-Qiu.Thermal transport properties in monolayer group-IV binary compounds.Journal of Physics: Condensed Matter , 2020, 32(30): 305301.

[5]Zeng, Jing*; Chen, Ke-Qiu*; Zhou, Yanhong.Exploring how hydrogen at gold–sulfur interface affects spin transport in single-molecule junction[J].Chinese Physics B,2020,29(08):611-616.

[6]Zeng, Yu-Jia; Wu, Dan; Cao, Xuan-Hao; Feng, Ye-Xin; Tang, Li-Ming; Chen, Ke-Qiu*.Significantly enhanced thermoelectric performance of molecular junctions by the twist angle dependent phonon interference effect.Journal of Materials Chemistry A, 2020, 8(23): 11884-11891.

[7]Chen, Xue-Kun; Pang, Min; Chen, Tong; Du, Dan; Chen, Ke-Qiu.Thermal Rectification in Asymmetric Graphene/Hexagonal Boron Nitride van der Waals Heterostructures.ACS Applied Materials & Interfaces, 2020, 12(13): 15517-15526.

[8]Zhou, Wu-Xing; Wu, Dan; Xie, Guofeng; Chen, Ke-Qiu*; Zhang, Gang*.alpha-Ag2S: A Ductile Thermoelectric Material with High ZT.ACS Omega, 2020, 5(11): 5796-5804.

[9]Wu, Dan; Cao, Xuan-Hao; Jia, Pin-Zhen; Zeng, Yu-Jia; Feng, Ye-Xin; Tang, Li-Ming; Zhou, Wu-Xing; Chen, Ke-Qiu.Excellent thermoelectric performance in weak-coupling molecular junctions with electrode doping and electrochemical gating.Science China Physics,Mechanics & Astronomy, 2020, 63(7): 276811.

[10]Jiang, Xingxing; Feng, Yexin; Chen, Ke-Qiu; Tang, Li-Ming*.The coexistence of ferroelectricity and topological phase transition in monolayer alpha-In2Se3 under strain engineering.Journal of Physics: Condensed Matter , 2020, 32(10): 105501.

[11]Tan, Jieyao; Chen, Keqiu; Tang, Li-Ming*.Out-of-plane spontaneous polarization and superior photoelectricity in two-dimensional SiSn.Journal of Physics: Condensed Matter , 2020, 32(6): 065003.

[12]Yu, Juan; Kuang, Xiaofei; Gao, Yuanji; Wang, Yunpeng; Chen, Keqiu; Ding, Zhongke; Liu, Jia; Cong, Chunxiao; He, Jun; Liu, Zongwen; Liu, Yanping.Direct Observation of the Linear Dichroism Transition in Two-Dimensional Palladium Diselenide.Nano Letters, 2020, 20(2): 1172-1182.

[13]Li, Qianze; Chen, Ke-Qiu; Tang, Li-Ming.Large Valley Splitting in van der Waals Heterostructures with Type-III Band Alignment.Physical Review Applied, 2020, 13(1): 014064.

[14]Zhang, Peng-Peng; Peng, Xiao-Fang; Tan, Shi-Hua; Long, Mengqiu; Chen, Ke-Qiu.The electronic transport properties in graphyne and graphyne-like carbon-nitride nanoribbons.Journal of Physics D: Applied Physics , 2020, 53(5): 055301.

[15]Gan, Yu; Xue, Xiong-Xiong; Jiang, Xing-Xing; Xu, Zhengwei; Chen, Keqiu; Yu, Ji-Feng*; Feng, Yexin*.Chemically modified phosphorene as efficient catalyst for hydrogen evolution reaction.Journal of Physics: Condensed Matter , 2020, 32(2): 025202.

[16]Zhu, Junfu; Jiang, Xingxing; Yang, Ye; Chen, Qinjun; Xue, Xiong Xiong*; Chen, Keqiu; Feng, Yexin*.Synergy of tellurium and defects in control of activity of phosphorene for oxygen evolution and reduction reactions.Physical Chemistry Chemical Physics, 2019, 21(41): 22939-22946.

[17]Pin-Zhen Jia#; Chen, Keqiu#*; Dan Wu; Hui Pan; Xuan-Hao Cao; Wu-Xing Zhou*; Zhong-Xiang Xie; Ji-Xu Zhang.Excellent thermoelectric performance induced by interface effect in MoS2/MoSe2 van der Waals heterostructure.J. Phys.: Condens. Matter , 2019, 32(2020): 055302.

[18]Tang, Liang Po; Li, Qian Ze; Zhang, Cai Xin; Ning, Feng; Zhou, Wu Xing; Tang, Li Ming*; Chen, Ke Qiu.Prediction of intrinsic ferromagnetism in two-dimension planar metal-organic framework semiconductors.Journal of Magnetism and Magnetic Materials, 2019, 488: UNSP 165354.

[19]Chen, Shi Zhang; Deng, Yuan Xiang; Cao, Xuan Hao; Zhou, Wu Xing*; Feng, Yexin; Tang, Li Ming; Chen, Ke Qiu*.Exploring high-performance anodes of Li-ion batteries based on the rules of pore-size dependent band gaps in porous carbon foams.Journal of Materials Chemistry A, 2019, 7(38): 21976-21984.

[20]Zeng, Jing*; Chen, Ke Qiu*; Deng, Yuan Xiang.Electron transport properties of boron nitride chains between two-dimensional metallic borophene electrodes.Physica E: Low-Dimensional Systems and Nanostructures , 2019, 114: 113565.

[21]Cao, Xuan Hao; Wu, Dan; Feng, Ye Xin; Zhou, Wu Xing*; Tang, Li Ming; Chen, Ke Qiu.Effect of electrophilic substitution and destructive quantum interference on the thermoelectric performance in molecular devices.Journal of Physics: Condensed Matter , 2019, 31(34): 345303. 

[22]Wu, Dan; Cao, Xuan Hao; Chen, Shi Zhang; Tang, Li Ming; Feng, Ye Xin; Chen, Ke Qiu*; Zhou, Wu Xing*.Pure spin current generated in thermally driven molecular magnetic junctions: a promising mechanism for thermoelectric conversion.Journal of Materials Chemistry A, 2019, 7(32): 19037-19044.

[23]Shen, Shiyu; Gan, Yu; Xue, Xiong xiong; Wei, Jiamou; Tang, Li ming; Chen, Keqiu; Feng, Yexin*.Role of defects on the catalytic property of 2D black arsenic for hydrogen evolution reaction.Applied Physics Express, 2019, 12(7): 075502.

[24]Chen, Xue Kun*; Xie, Zhong Xiang; Zhang, Yong; Deng, Yuan Xiang; Zou, Tong Hua; Liu, Jun*; Chen, Ke Qiu*.Highly efficient thermal rectification in carbon/boron nitride heteronanotubes.Carbon, 2019, 148: 532-539.

[25]Xue, Xiong Xiong; Shen, Shiyu; Jiang, Xingxing; Sengdala, Phoxay; Chen, Keqiu; Feng, Yexin*.Tuning the Catalytic Property of Phosphorene for Oxygen Evolution and Reduction Reactions by Changing Oxidation Degree.Journal of Physical Chemistry Letters, 2019, 10(12): 3440-3446.

[26]Zhang, Cai Xin; Li, Qianze; Tang, Li Ming*; Yang, Kaike; Xiao, Jin; Chen, Ke Qiu; Deng, Hui Xiong*.Abnormal diffusion behaviors of Cu atoms in van der Waals layered material MoS2.Journal of Materials Chemistry C, 2019, 7(20): 6052-6058.

[27]Xiao, Wei Hua; Xie, Fang*; Zhang, Xiao Jiao; Chu, Yu Fang; Liu, Jian Ping; Wang, Hai Yan; Fan, Zhi Qiang*; Long, Meng Qiu; Chen, Ke Qiu*.Large negative differential resistance behavior in arsenene nanoribbons induced by vacant defects.Physics Letters A, 2019, 383(14): 1629-1635.

[28]Zeng, Jing*; Chen, Ke Qiu*.Quantum transport properties of hybrid zigzag C3N and C3B nanoribbons.Journal of Physics D: Applied Physics , 2019, 52(18): 185301.

[29]Wang, Si Qin; Shen, Shiyu; Xue, Xiong Xiong*; He, Yunqiu; Xu, Zheng Wei; Chen, Keqiu; Feng, Yexin*.Improving the phase stability of inorganic lead halide perovskites through K/Rb doping.Applied Physics Express, 2019, 12(5): 051017.

[30]Zhou, Yanhong*; Zheng, Xiaohong; Cheng, Zi Qiang; Chen, Ke Qiu*.Current Superposition Law Realized in Molecular Devices Connected in Parallel.Journal of Physical Chemistry C, 2019, 123(16): 10462-10468.

[31]Zeng, Jing*; Chen, Ke Qiu*.Charge Transport in Borophene: Role of Intrinsic Line Defects.Journal of Physical Chemistry C, 2019, 123(10): 6270-6275.

[32]Xue, Xiong Xiong; Tang, Li Ming; Chen, Keqiu; Zhang, Lixin*; Wang, En ge; Feng, Yexin*.Bifunctional mechanism of N, P co-doped graphene for catalyzing oxygen reduction and evolution reactions.Journal of Chemical Physics, 2019, 150(10): 104701.

[33]Wang, Dan; Tang, Li Ming*; Jiang, Xing Xing; Tan, Jie Yao; He, Meng Dong; Wang, Xin Jun; Chen, Ke Qiu.High Bipolar Conductivity and Robust In-Plane Spontaneous Electric Polarization in Selenene.Advanced Electronic Materials, 2019, 5(2): 1800475.

[34]Liu, Junchi; Liu, Xiao; Chen, Zhuojun; Miao, Lili; Liu, Xingqiang; Li, Bo*; Tang, Liming; Chen, Keqiu; Liu, Yuan; Li, Jingbo; Wei, Zhongming*; Duan, Xidong*.Tunable Schottky barrier width and enormously enhanced photoresponsivity in Sb doped SnS2 monolayer.Nano Research, 2019, 12(2): 463-468.

[35]Tang, Liang Po; Tang, Li Ming*; Wang, Dan; Deng, Hui Xiong; Chen, Ke Qiu.Metal and ligand effects on the stability and electronic properties of crystalline two-dimensional metal-benzenehexathiolate coordination compounds.Journal of Physics: Condensed Matter , 2018, 30(46): 465301.

[36]Chen, Xue Kun*; Liu, Jun; Xie, Zhong Xiang; Zhang, Yong; Deng, Yuan Xiang; Chen, Ke Qiu*.A local resonance mechanism for thermal rectification in pristine/branched graphene nanoribbon junctions.Applied Physics Letters, 2018, 113(12): 121906.

[37]He, Yunqiu; Wang, Si Qin; Xue, Xiong Xiong; Zhang, Lixin; Chen, Keqiu; Zhou, Wu Xing*; Feng, Yexin.Ab initio study of the moisture stability of lead iodine perovskites.Journal of Physics: Condensed Matter , 2018, 30(35): 355501.

[38]Chen, Xue Kun*; Liu, Jun; Du, Dan; Xie, Zhong Xiang; Chen, Ke Qiu.Anisotropic thermal conductivity in carbon honeycomb.Journal of Physics: Condensed Matter , 2018, 30(15): 155702.

[39]Xue, Xiong Xiong; Feng, Yexin*; Chen, Keqiu; Zhang, Lixin*.The vertical growth of MoS2 layers at the initial stage of CVD from first-principles.Journal of Chemical Physics, 2018, 148(13): 134704.

[40]Xue, Xiong Xiong; Feng, Ye Xin; Liao, Lei; Chen, Qin Jun; Wang, Dan; Tang, Li Ming*; Chen, Keqiu.Strain tuning of electronic properties of various dimension elemental tellurium with broken screw symmetry.Journal of Physics: Condensed Matter , 2018, 30(12): 125001.

[41]Li, Zhiqin; Chen, Yiqin; Zhu, Xupeng; Zheng, Mengjie; Dong, Fengliang; Chen, Peipei; Xu, Lihua; Chu, Weiguo*; Chen, Keqiu; Duan, Huigao.Polarization-dependent scattering properties of single-crystalline silicon nanocylindroids.Optical Materials Express, 2018, 8(3): 503-510.

[42]Zeng, Yu Jia; Liu, Yue Yang; Zhou, Wu Xing*; Chen, Ke Qiu*..Nanoscale thermal transport: Theoretical method and application[J].Chinese Physics B,2018,27(03):47-63.

[43]Zou, Juan; Tang, Li Ming*; Chen, Keqiu; Feng, Yexin.Contrasting properties of hydrogenated and protonated single-layer h-BN from first-principles.Journal of Physics: Condensed Matter , 2018, 30(6): 065001.

[44]Li, Zhiqin; Xiang, Quan; Zheng, Mengjie; Bi, Kaixi; Chen, Yiqin; Chen, Keqiu; Duan, Huigao*.Fabrication of 3D SiOx structures using patterned PMMA sacrificial layer.Journal of Micromechanics and Microengineering, 2018, 28(2): 024005.

[45]Kuang, Guowen; Chen, Shi Zhang; Yan, Linghao; Chen, Ke Qiu*; Shang, Xuesong; Liu, Pei Nian*; Lin, Nian*.Negative Differential Conductance in Polyporphyrin Oligomers with Nonlinear Backbones.Journal of the American Chemical Society, 2018, 140(2): 570-573.

[46]Tang, Liang-Po; Tang, Li-Ming*; Geng, Hua; Yi, Yuan-Ping; Wei, Zhongming; Chen, Ke-Qiu; Deng, Hui-Xiong.Tuning transport performance in two-dimensional metal-organic framework semiconductors: Role of the metal d band.Applied Physics Letters, 2018, 112(1): 012101.

[47]Zhou, Yan Hong*; Zhang, Xiang; Ji, Cheng; Liu, Zhi Min; Chen, Ke Qiu*.The length and hydrogenation effects on electronic transport properties of carbon-based molecular wires.Organic Electronics, 2017, 51: 332-340.

[48]Chen, Xue Kun*; Liu, Jun; Du, Dan; Chen, Ke Qiu.Anomalous thermal conductance of graphyne under lower temperature.Journal of Physics: Condensed Matter , 2017, 29(45): 455702.

[49]Deng, Yuan Xiang; Chen, Shi Zhang; Zeng, Yun*; Zhou, Wu Xing*; Chen, Ke Qiu*.Large spin rectifying and high-efficiency spin-filtering in superior molecular junction.Organic Electronics, 2017, 50: 184-190.

[50]Xie, Fang; Fan, Zhi Qiang*; Chen, Ke Qiu*; Zhang, Xiao Jiao; Long, Meng Qiu.Influence of anchoring groups on single-molecular junction conductance: Theoretical comparative study of thiol and amine.Organic Electronics, 2017, 50: 198-203.

[51]Li Qianze; Tang Liangpo; Zhang Caixin; Wang Dan; Chen Qin-Jun; Feng Ye-Xin; Tang Li-Ming; Chen Ke-Qiu.Seeking the Dirac cones in the MoS2/WSe2 van der Waals heterostructure.Applied Physics Letters, 2017, 111(17): 171602.

[52]Li, Xiuqiang; Liu, Yueyang; Zheng, Qinghui; Yan, Xuejun; Yang, Xin; Lv, Guangxin; Xu, Ning; Wang, Yuxi; Lu, Minghui; Chen, Keqiu*; Zhu, Jia.Anomalous thermal anisotropy of two-dimensional nanoplates of vertically grown MoS2.Applied Physics Letters, 2017, 111(16): 163102.

[53]Ning, Feng; Wang, Dan; Feng, Ye Xin; Tang, Li Ming*; Zhang, Yong; Chen, Ke Qiu*.Strong interfacial interaction and enhanced optical absorption in graphene/InAs and MoS2/InAs heterostructures.Journal of Materials Chemistry C, 2017, 5(36): 9429-9438.

[54]Liu Yue Yang; Li Bo Lin; Chen Shi Zhang; Jiang Xiangwei; Chen Ke Qiu*.Effect of room temperature lattice vibration on the electron transport in graphene nanoribbons.Applied Physics Letters, 2017, 111(13): 133107.

[55]Cao, Xuan Hao; Zhou, Wu Xing*; Chen, Chang Yong*; Tang, Li Ming; Long, Mengqiu; Chen, Ke Qiu*.Excellent thermoelectric properties induced by different contact geometries in phenalenyl-based single-molecule devices.Scientific Reports, 2017, 7(1): 10842.

[56]Chen, Xue Kun; Chen, Chang Yong; Liu, Jun; Chen, Ke Qiu*.Remarkable reduction of thermal conductivity in graphyne nanotubes by local resonance.Journal of Physics D: Applied Physics , 2017, 50(34): 345301.

[57]Peng, Xiao Fang*; Zhou, Xin; Jiang, Xiang Tao*; Gao, Ren Bin; Tan, Shi Hua*; Chen, Ke Qiu*.Thermal conductance of electrons in graphene and stanene ribbons modulated via electron-phonon coupling.Journal of Applied Physics, 2017, 122(5): 054302.

[58]Li Bo Lin; Chen Ke Qiu*.Effects of electron-phonon interactions on the spin-dependent Seebeck effect in graphene nanoribbons.Carbon, 2017, 119: 548-554.

[59]Tan, Ting; Chen, Shi Zhang; Cao, Xuan Hao; Zhou, Wu Xing*; Xie, Fang; Chen, Ke Qiu.Large anisotropic thermal conductivity and excellent thermoelectric properties observed in carbon foam.Journal of Applied Physics, 2017, 122(2): 024304.

[60]Xie, Le; Chen, Shi Zhang; Zhou, Wu Xing; Chen, Ke Qiu*.Large rectifying ratio in a nitrogen-doped armchair graphene device modulated by the gate voltage.Organic Electronics, 2017, 46: 150-157.

[61]Xiong, Peng Yu; Chen, Shi Zhang; Zhou, Wu Xing; Chen, Ke Qiu*.Semiconductor-metal transition induced by giant Stark effect in blue phosphorene nanoribbons.Physics Letters A, 2017, 381(24): 2016-2020.

[62]Zeng, Jing*; Chen, Ke Qiu; Long, Mengqiu.An important rule for realizing metal -> half-metal -> semiconductor transition in single-molecule junctions.Journal of Physics D: Applied Physics , 2017, 50(21): 215102.

[63]Wang, Yan; Zhou, Wu Xing; Huang, Le; Xia, Congxin; Tang, Li Ming; Deng, Hui Xiong; Li, Yongtao; Chen, Ke Qiu*; Li, Jingbo; Wei, Zhongming.Light induced double 'on' state anti-ambipolar behavior and self-driven photoswitching in p-WSe2/n-SnS2 heterostructures.2D Materials, 2017, 4(2): 025097.

[64]Zeng, Jing*; Chen, Ke Qiu*.Huge magnetoresistance induced by half-metal-semiconductor phase transition in a one-dimensional spin chain: a first-principles study.Physical Chemistry Chemical Physics, 2017, 19(14): 9417-9423.

[65]Peng, Jun; Chen, Ke Qiu*.Tuning the electronic properties by magnetic fields in zigzag-edge graphyne nanoribbons with symmetric and asymmetric edge hydrogenations.Organic Electronics, 2017, 43: 175-181.

[66]Peng, Xiao Fang*; Zhou, Xin; Tan, Shi Hua; Wang, Xin Jun; Chen, Li Qun; Chen, Ke Qiu*.Thermal conductance in graphene nanoribbons modulated by defects and alternating boron-nitride structures.Carbon, 2017, 113: 334-339.

[67]Zhao, Chen Chen; Tan, Shi Hua; Zhou, Yan Hong; Wang, Rong Ji; Wang, Xin Jun*; Chen, Ke Qiu*.Half-metallicity and high spin-filtering effect of magnetic atoms embedded zigzag 6, 6, 12-graphyne nanoribbon.Carbon, 2017, 113: 170-175.

[68]Chen Xue Kun*; Liu Jun; Peng Zhi Hua; Du Dan; Chen Ke Qiu*.A wave-dominated heat transport mechanism for negative differential thermal resistance in graphene/hexagonal boron nitride heterostructures.Applied Physics Letters, 2017, 110(9): 091907.

[69]Wang, Jue; Xie, Fang; Cao, Xuan Hao; An, Si Cong; Zhou, Wu Xing*; Tang, Li Ming*; Chen, Ke Qiu*.Excellent Thermoelectric Properties in monolayer WSe2 Nanoribbons due to Ultralow Phonon Thermal Conductivity.Scientific Reports, 2017, 7(1): 41418.

[70]Feng, Yexin; Chen, Keqiu; Li, Xin Zheng; Wang, Enge; Zhang, Lixin*.Hydrogen induced contrasting modes of initial nucleations of graphene on transition metal surfaces.Journal of Chemical Physics, 2017, 146(3): 034704.

[71]Chen, Shi Zhang; Xie, Fang; Ning, Feng; Liu, Yue Yang; Zhou, Wu Xing; Yu, Ji Feng; Chen, Ke Qiu*.Breaking surface states causes transformation from metallic to semi-conducting behavior in carbon foam nanowires.Carbon, 2017, 111: 867-877.

[72]Zeng, Jing*; Chen, Ke Qiu; Deng, Xiaohui; Long, Mengqiu.Light-driven strong spin valve effects in an azobenzene-based spin optoelectronic device.Journal of Physics D: Applied Physics , 2016, 49(41): 415104.

[73]Liu Yue Yang; Li Bo Lin; Zhou Wu Xing; Chen Ke Qiu.Triggering piezoelectricity directly by heat to produce alternating electric voltage.Applied Physics Letters, 2016, 109(11): 113107.

[74]Kuang, Guowen; Chen, Shi Zhang; Wang, Weihua; Lin, Tao; Chen, Keqiu; Shang, Xuesong; Liu, Pei Nian*; Lin, Nian*.Resonant Charge Transport in Conjugated Molecular Wires beyond 10 nm Range.Journal of the American Chemical Society, 2016, 138(35): 11140-11143.

[75]Chen Xue Kun; Xie Zhong Xiang; Zhou Wu Xing; Tang Li Ming; Chen Ke Qiu.Phonon wave interference in graphene and boron nitride superlattice.Applied Physics Letters, 2016, 109(2): 023101.

[76]Liao, Gaohua; Luo, Ning; Chen, Ke Qiu*; Xu, H Q*.Electronic Structures of Free-Standing Nanowires made from Indirect Bandgap Semiconductor Gallium Phosphide.Scientific Reports, 2016, 6(1): 28240.

[77]Zhang, Xue; Zhou, Wu Xing*; Chen, Xue Kun; Liu, Yue Yang; Chen, Ke Qiu*.Significant decrease in thermal conductivity of multi-walled carbon nanotube induced by inter-wall van der Waals interactions.Physics Letters A, 2016, 380(21): 1861-1864.

[78]Chen, Xue-Kun; Xie, Zhong-Xiang; Zhou, Wu-Xing; Tang, Li-Ming; Chen, Ke-Qiu*.Thermal rectification and negative differential thermal resistance behaviors in graphene/hexagonal boron nitride heterojunction.Carbon, 2016, 100: 492-500.

[79]Peng, Xiao-Fang*; Chen, Ke-Qiu*; Wang, Xin-Jun; Tan, Shi-Hua.Tunable ballistic thermal conductance of electrons in strained graphene nanoribbons.Carbon, 2016, 100: 36-41.

[80]Zeng, Jing*; Xie, Fang; Chen, Ke-Qiu*.High-efficiency spin-filtering and magnetoresistance effects in supramolecular spin valves.Carbon, 2016, 98: 607-612.

[81]Tan, Chang-Ming; Zhou, Yan-Hong; Chen, Chang-Yong; Yu, Ji-Feng; Chen, Ke-Qiu*.Spin filtering and rectifying effects in the zinc methyl phenalenyl molecule between graphene nanoribbon leads.Organic Electronics, 2016, 28: 244-251.

[82]Pan, Changning*; He, Jun*; Yang, Diwu; Chen, Keqiu.Thermal Transport of Flexural and In-Plane Phonons Modulated by Bended Graphene Nanoribbons.Journal of Nanomaterials, 2016, 2016: 6093673.

[83]Liu, Yue-Yang; Zhou, Wu-Xing; Chen, Ke-Qiu*.Conjunction of standing wave and resonance in asymmetric nanowires: a mechanism for thermal rectification and remote energy accumulation.Scientific Reports, 2015, 5: 17525.

[84]Zhou, Yan-Hong; Chen, Chang-Yong; Li, Bo-Lin; Chen, Ke-Qiu*.Characteristics of classical Kirchhoff's superposition law in carbon atomic wires connected in parallel.Carbon, 2015, 95: 503-510.

[85]Peng, Jun; Zhou, Yan-Hong; Chen, Ke-Qiu*.Influence of boundary types on rectifying behaviors in hexagonal boron-nitride/graphene nanoribbon heterojunctions.Organic Electronics, 2015, 27: 137-142.

[86]Xie, Fang; Fan, Zhi-Qiang*; Liu, Kun; Wang, Hai-Yan; Yu, Ji-Hai; Chen, Ke-Qiu*.Negative differential resistance and stable conductance switching behaviors of salicylideneaniline molecular devices sandwiched between armchair graphene nanoribbon electrodes.Organic Electronics, 2015, 27: 41-45.

[87]Peng, Xiao-Fang*; Chen, Ke-Qiu*.Comparison on thermal transport properties of graphene and phosphorene nanoribbons.Scientific Reports, 2015, 5: 16215.

[88]Tan, Shihua; Chen, Ke-Qiu*.The enhancement of the thermoelectric performance in zigzag graphene nanoribbon by edge states.Carbon, 2015, 94: 942-945.

[89]Zhou, Wu-Xing; Chen, Ke-Qiu*.First-Principles Determination of Ultralow Thermal Conductivity of monolayer WSe2.Scientific Reports, 2015, 5: 15070.

[90]Zheng, Xiao-Xi; Wang, Dan; Tang, Li-Ming*; Chen, Ke-Qiu.The effect of oxygen vacancy on holes-induced d(0) magnetism in CaTiO3 and CaZrO3.Modern Physics Letters B, 2015, 29(24): 1550137.

[91]Liao, Gaohua; Luo, Ning; Yang, Zhihu; Chen, Keqiu; Xu, H. Q.*.Electronic structures of [001]- and [111]-oriented InSb and GaSb free-standing nanowires.Journal of Applied Physics, 2015, 118(9): 094308.

[92]Jiang, Bo; Zhou, Yan-Hong; Chen, Chang-Yong; Chen, Ke-Qiu*.Designing multi-functional devices based on two benzene rings molecule modulated with Co and N atoms.Organic Electronics, 2015, 23: 133-137.

[93]Zhang, Xiaojiao*; Chen, Keqiu; Long, Mengqiu; He, Jun; Gao, Yongli.Effect of length and negative differential resistance behavior in conjugated molecular wire tetrathiafulvalene devices.Modern Physics Letters B, 2015, 29(20): 1550106.

[94]Ning, Feng; Tang, Li-Ming*; Zhang, Yong; Chen, Ke-Qiu*.Remote p-type Doping in GaSb/InAs Core-shell Nanowires.Scientific Reports, 2015, 5: 10813.

[95]Zhou, Wu-Xing; Chen, Ke-Qiu*.Enhancement of thermoelectric performance in beta-graphyne nanoribbons by suppressing phononic thermal conductance.Carbon, 2015, 85: 24-27.

[96]Ling, Yu-Cheng; Ning, Feng; Zhou, Yan-hong; Chen, Ke-Qiu*.Rectifying behavior and negative differential resistance in triangular graphene p-n junctions induced by vertex B-N mixture doping.Organic Electronics, 2015, 19: 92-97.

[97]Zhang, Yong; Tang, Li-Ming*; Ning, Feng; Wang, Dan; Chen, Ke-Qiu*.Structural stability and electronic properties of InSb nanowires: A first-principles study.Journal of Applied Physics, 2015, 117(12): 125707.

[98]Fan, Zhi-Qiang; Zhang, Zhen-Hua*; Xie, Fang; Deng, Xiao-Qing; Tang, Gui-Ping; Yang, Chang-Hu; Chen, Ke-Qiu*.Reversible switching in gold-atom-organic-molecule complex induced by reversible bond formation.Organic Electronics, 2015, 18: 101-106.

[99]Zeng, Jing*; Chen, Ke-Qiu*.Abnormal oscillatory conductance and strong odd-even dependence of a perfect spin-filtering effect in a carbon chain-based spintronic device.Journal of Materials Chemistry C, 2015, 3(22): 5697-5702.

[100]Zhou, Wu-Xing; Chen, Ke-Qiu*.Enhancement of Thermoelectric Performance by Reducing Phonon Thermal Conductance in Multiple Core-shell Nanowires.Scientific Reports, 2014, 4: 7150.

[101]Liu, Yue-Yang; Zhou, Wu-Xing; Tang, Li-Ming; Chen, Ke-Qiu*.An important mechanism for thermal rectification in graded nanowires.Applied Physics Letters, 2014, 105(20): 203111.

[102]Pan, Chang-Ning; Chen, Xue-Kun; Tang, Li-Ming; Chen, Ke-Qiu*.Orientation dependent thermal conductivity in graphyne nanoribbons.Physica E: Low-Dimensional Systems and Nanostructures , 2014, 64: 129-133.

[103]Tan, Shi-Hua; Tang, Li-Ming; Chen, Ke-Qiu*.Band gap opening in zigzag graphene nanoribbon modulated with magnetic atoms.Current Applied Physics, 2014, 14(11): 1509-1513.

[104]Zhou, Yan-Hong; Tan, Shi-Hua; Chen, Ke-Qiu*.Enhance the stability of alpha-graphyne nanoribbons by dihydrogenation.Organic Electronics, 2014, 15(11): 3392-3398.

[105]Zeng, Jing*; Chen, Ke-Qiu*; Chen, Liezun; Deng, Xiaohui; Dai, Zhiping.Designing cross-linked carbon nanotubes as perfect spin filter and spin valve.Organic Electronics, 2014, 15(10): 2561-2567.

[106]Peng, Xiao-Fang*; Chen, Ke-Qiu*。Thermal transport for flexural and in-plane phonons in graphene nanoribbons.Carbon, 2014, 77: 360-365.

[107]Ning, Feng; Wang, Dan; Tang, Li-Ming*; Zhang, Yong; Chen, Ke-Qiu*.The effects of the chemical composition and strain on the electronic properties of GaSb/InAs core-shell nanowires.Journal of Applied Physics, 2014, 116(9): 094308.

[108]Zhou, Yan-Hong; Zeng, Jing; Chen, Ke-Qiu*.Spin filtering effect and magnetoresistance in zigzag 6, 6, 12-graphyne nanoribbon system.Carbon, 2014, 76: 175-182.

[109]Peng, Jun; Zhou, Wu-Xing; Chen, Ke-Qiu*.High-efficiency spin filtering in salophen-based molecular junctions modulated with different transition metal atoms.Physics Letters A, 2014, 378(42): 3126-3130.

[110]Fan, Zhi-Qiang; Chen, Ke-Qiu*.Stable Two-Dimensional Conductance Switch of Polyaniline Molecule Connecting to Graphene Nanoribbons.Scientific Reports, 2014, 4: 5976.

[111]Chen, Qiao; Chen, Ke-Qiu*; Zhao, Hong-Kang.Shot noise in a quantum dot system coupled with Majorana bound states.Journal of Physics: Condensed Matter , 2014, 26(31): 315011.

[112]Yan, Shenlang; Long, Mengqiu*; Zhang, Xiaojiao; He, Jun; Xu, Hui; Chen, Keqiu.Effects of the magnetic anchoring groups on spin-dependent transport properties of Ni(dmit)(2) device.Chemical Physics Letters, 2014, 608: 28-34.

[113]Peng, Xiao-Fang*; Wang, Xin-Jun; Chen, Li-Qun; Li, Jian-Bo; Zhou, Wu-Xing; Zhang, Gui; Chen, Ke-Qiu.Thermal conductance associated with six types of vibration modes in quantum wire modulated with quantum dot.Physics Letters A, 2014, 378(30-31): 2195-2200.

[114]Tan, Shi-Hua; Tang, Li-Ming; Chen, Ke-Qiu*.Phonon scattering and thermal conductance properties in two coupled graphene nanoribbons modulated with bridge atoms.Physics Letters A, 2014, 378(28-29): 1952-1955.

[115]Zeng, Jing*; Chen, Liezun; Chen, Ke-Qiu.Improving spin-filtering efficiency in graphene and boron nitride nanoribbon heterostructure decorated with chromium-ligand.Organic Electronics, 2014, 15(5): 1012-1017.

[116]Zhou, Wu-Xing; Tan, Shihua; Chen, Ke-Qiu*; Hu, Wenping.Enhancement of thermoelectric performance in InAs nanotubes by tuning quantum confinement effect.Journal of Applied Physics, 2014, 115(12): 124308.

[117]Ying, Huahu; Zhou, Wu-Xing; Chen, Ke-Qiu*; Zhou, Guanghui.Negative differential resistance induced by the Jahn-Teller effect in single molecular coulomb blockade devices.Computational Materials Science, 2014, 82: 33-36.

[118]Zhang, Zheng-Long; Chen, Li; Sheng, Shao-Xiang; Sun, Meng-Tao*; Zheng, Hai-Rong; Chen, Ke-Qiu; Xu, Hong-Xing.High-vacuum tip enhanced Raman spectroscopy.Frontiers of Physics, 2014, 9(1): 17-24.

[119]Chen Li; Wei Hong; Chen Ke-Qiu; Xu Hong-Xing*.High-order plasmon resonances in an Ag/Al₂O₃ core/shell nanorice[J].Chinese Physics B,2014,23(02):23-28.

[120]Zeng, Jing; Chen, Ke-Qiu*.Magnetic configuration dependence of magnetoresistance in a Fe-porphyrin-like carbon nanotube spintronic device.Applied Physics Letters, 2014, 104(3): 033104.

[121]Liu, Yue-Yang; Zhou, Wu-Xing; Tang, Li-Ming; Chen, Ke-Qiu*.Core-shell nanowire serves as heat cable.Applied Physics Letters, 2013, 103(26): 263118.

[122]Ning, Feng; Tang, Li-Ming*; Zhang, Yong; Chen, Ke-Qiu*.First-principles study of quantum confinement and surface effects on the electronic properties of InAs nanowires.Journal of Applied Physics, 2013, 114(22): 224304.

[123]Zhou, Wu-Xing; Chen, Ke-Qiu*; Tang, Li-Ming; Yao, Ling-Jiang.Phonon thermal transport in InAs nanowires with different size and growth directions.Physics Letters A, 2013, 377(43): 3144-3147.

[124]Tan, Shi-Hua; Tang, Li-Ming; Xie, Zhong-Xiang; Pan, Chang-Ning; Chen, Ke-Qiu*.Effect of pentagon-heptagon defect on thermal transport properties in graphene nanoribbons.Carbon, 2013, 65: 181-186.

[125]Zhou, Yan-Hong; Zeng, Jing; Tang, Li-Ming; Chen, Ke-Qiu*; Hu, W. P..Giant magnetoresistance effect and spin filters in phthalocyanine-based molecular devices.Organic Electronics, 2013, 14(11): 2940-2947.

[126]Xie, Zhong-Xiang; Tang, Li-Ming; Pan, Chang-Ning; Chen, Qiao; Chen, Ke-Qiu*.Ballistic thermoelectric properties in boron nitride nanoribbons.Journal of Applied Physics, 2013, 114(14): 144311.

[127]Zhang, Yong; Tang, Li-Ming*; Tang, Zhen-Kun; Ning, Feng; Chen, Ke-Qiu.Magnetic properties of a SnO2 quantum dot.Physica E-Low-Dimensional Systems & Nanostructures, 2013, 53: 72-77.

[128]Chen, Qiao; Tang, Li-Ming; Chen, Ke-Qiu*; Zhao, Hong-Kang.Heat generated by electrical current in a mesoscopic system perturbed by alternating current fields.Journal of Applied Physics, 2013, 114(8): 084301.

[129]Tang, Zhen-kun*; Zhang, Deng-Yu; Tang, Li-Ming; Wang, Ling-Ling; Chen, Ke-Qiu.Enhance ferromagnetism by stabilizing the cation vacancies in GaN.European Physical Journal B, 2013, 86(6): 284.

[130]Zhang, Yong; Tang, Li-Ming*; Ning, Feng; Wang, Dan; Chen, Ke-Qiu*.Reducing self-compensating Mn interstitials in (Ga, Mn)As via nanostructure engineering.Journal of Physics D-Applied Physics, 2013, 46(17): 175005.

[131]Gao, Jie; He, Meng-Dong*; Chen, Ke-Qiu.Enhancing the performance of unidirectional excitation of surface-plasmon-polaritons in plasmonic couplers based on the nanoslit with bump.Optics Communications, 2013, 291: 366-370.

[132]Wang, Hai-Bin*; Tang, Li-Ming; Peng, P.; Tang, Yuan-Hong; Chen, Ke-Qiu.Enhancement of the hole-induced d(0)-ferromagnetism in ZnO through compensated donor-acceptor complexes: a first-principles study.Semiconductor Science and Technology, 2013, 28(3): 035017.

[133]Li, Ming-Jun; Long, Meng-Qiu*; Chen, Ke-Qiu; Xu, Hui.Fluorination effects on the electronic transport properties of dithiophene-tetrathiafulvalene (DT-TTF) molecular junctions.Solid State Communications, 2013, 157: 62-67.

[134]Fan, Zhi-Qiang*; Zhang, Zhen-Hua; Deng, Xiao-Qing; Tang, Gui-Ping; Chen, Ke-Qiu.Controllable low-bias negative differential resistance and rectifying behaviors induced by symmetry breaking.Applied Physics Letters, 2013, 102(2): 023508.

[135]Wei, Dacheng*; Xie, Lanfei; Lee, Kian Keat; Hu, Zhibin; Tan, Shihua; Chen, Wei; Sow, Chorng Haur; Chen, Keqiu; Liu, Yunqi; Wee, Andrew Thye Shen.Controllable unzipping for intramolecular junctions of graphene nanoribbons and single-walled carbon nanotubes.Nature Communications, 2013, 4: 1374.

[136]Wang, Peng; Chen, Li; Wang, Rongyao*; Ji, Yinglu; Zhai, Dawei; Wu, Xiaochun; Liu, Yu; Chen, Keqiu; Xu, Hongxing.Giant optical activity from the radiative electromagnetic interactions in plasmonic nanoantennas.Nanoscale, 2013, 5(9): 3889-3894.

[137]Zeng, Jing; Chen, Ke-Qiu*.Spin filtering, magnetic and electronic switching behaviors in manganese porphyrin-based spintronic devices.Journal of Materials Chemistry C, 2013, 1(25): 4014-4019.

[138]Yi, Guo-Jun*; Xie, Zhong-Xiang; Chen, Ke-Qiu; Tang, Li-Ming; Chen, Xiao-Hua.Ballistic thermal transport contributed by the in-plane waves in a quantum wire modulated with an acoustic nanocavity.Journal of Applied Physics, 2012, 112(12): 124315.

[139]He, Jun; Chen, Ke-Qiu*.Rectifying and perfect spin filtering behavior realized by tailoring graphene nanoribbons.Journal of Applied Physics, 2012, 112(11): 114319.

[140]You, Jun; He, Jun; Yin, Ming-Ming; Tang, Li-Ming; Chen, Ke-Qiu*; Fan, Zhi-Qiang.The E-Z photo-isomerization switching behavior in single molecular device with carbon nanotube electrodes.Computational Materials Science, 2012, 65: 203-206.

[141]Fan, Zhi-Qiang*; Zhang, Zhen-Hua; Deng, Xiao-Qing; Tang, Gui-Ping; Chen, Ke-Qiu.Reversible switching in an N-salicylideneaniline molecular device induced by hydrogen transfer.Organic Electronics, 2012, 13(12): 2954-2958.

[142]Pan, Chang-Ning; Xie, Zhong-Xiang; Tang, Li-Ming; Chen, Ke-Qiu*.Ballistic thermoelectric properties in graphene-nanoribbon-based heterojunctions.Applied Physics Letters, 2012, 101(10): 103115.

[143]Yu, Xia; Chen, Ke-Qiu*; Zhang, Yan.Optical transport through finite superlattice modulated with three-component quasiperiodic defect.Journal of Applied Physics, 2012, 112(4): 043524.

[144]Li, Xiao-Fei*; Wang, Ling-Ling; Chen, Ke-Qiu; Luo, Yi.Strong current polarization and negative differential resistance in chiral graphene nanoribbons with reconstructed (2,1)-edges.Applied Physics Letters, 2012, 101(7): 073101.

[145]Yu, Xia; Chen, Ke-Qiu*; Zhang, Yan.Perfect optical transport and optical band gap in quasiperiodic superlattices.Modern Physics Letters B, 2012, 26(17): 1250110.

[146]Peng, Xiao-Fang*; Wang, Xin-Jun; Chen, Li-Qun; Chen, Ke-Qiu.Heat transport in multilayer abrupt graphene junctions modulated with convexity-shaped quantum structure.EPL, 2012, 98(5): 56001.

[147]Zhang, Hang; Zeng, Jing; Chen, Ke-Qiu*.Rectifying and negative differential resistance behaviors induced by asymmetric electrode coupling in Pyrene-based molecular device.Physica E: Low-Dimensional Systems and Nanostructures , 2012, 44(7-8): 1631-1635.

[148]Xie, Zhong-Xiang; Li, Ke-Min; Tang, Li-Ming; Pan, Chang-Ning; Chen, Ke-Qiu*.Nonlinear phonon transport and ballistic thermal rectification in asymmetric graphene-based three terminal junctions.Applied Physics Letters, 2012, 100(18): 183110.

[149]Li, Ming-Jun; Xu, Hui; Chen, Ke-Qiu; Long, Meng-Qiu*.Electronic transport properties in benzene-based heterostructure: Effects of anchoring groups.Physics Letters A, 2012, 376(20): 1692-1697.

[150]Liao, Wenhu*; Zhao, Heping; Ouyang, Gang; Chen, Ke-Qiu; Zhou, Guanghui.Symmetry of atomistic structure for armchair-edge graphene nanoribbons under uniaxial strain.Applied Physics Letters, 2012, 100(15): 153112.

[151]Li, Xiao-Fei*; Wang, Ling-Ling; Chen, Ke-Qiu; Luo, Yi.Electronic transport through zigzag/armchair graphene nanoribbon heterojunctions.Journal of Physics: Condensed Matter , 2012, 24(9): 095801.

[152]Tang, Zhen-Kun*; Tang, Li-Ming; Wang, Dan; Wang, Ling-Ling; Chen, Ke-Qiu.Shallow donor levels enhanced ferromagnetism in the In2O3: Co nanocrystal.EPL, 2012, 97(5): 57006.

[153]He, Jun; Chen, Ke-Qiu*; Sun, Chang Q..The weak pi-pi interaction originated resonant tunneling and fast switching in the carbon based electronic devices.AIP Advances, 2012, 2(1): 012137.

[154]Xie, Zhong-Xiang; Tang, Li-Ming; Pan, Chang-Ning; Li, Ke-Min; Chen, Ke-Qiu*; Duan, Wenhui.Enhancement of thermoelectric properties in graphene nanoribbons modulated with stub structures.Applied Physics Letters, 2012, 100(7): 073105.

[155]Fan, Zhi-Qiang*; Zhang, Zhen-Hua; Ming, Qiu; Tang, Gui-Ping; Chen, Ke-Qiu.First-principles study of repeated current switching in a bimolecular device.Computational Materials Science, 2012, 53(1): 294-297.

[156]He, Jun; Chen, Ke-Qiu*.Humidity effects on the electronic transport properties in carbon based nanoscale device.Physics Letters A, 2012, 376(6-7): 869-874.

[157]Zeng, Jing; Chen, Ke-Qiu*; Sun, Chang Q.Electronic structures and transport properties of fluorinated boron nitride nanoribbons.Physical Chemistry Chemical Physics, 2012, 14(22): 8032-8037.

[158]Zeng, Jing; Chen, Ke-Qiu*; He, Jun; Zhang, Xiao-Jiao; Sun, Chang Q.Edge Hydrogenation-Induced Spin-Filtering and Rectifying Behaviors in the Graphene Nanoribbon Heterojunctions.Journal of Physical Chemistry C, 2011, 115(50): 25072-25076.

[159]Li, Xiao-Fei*; Wang, Ling-Ling; Chen, Ke-Qiu; Luo, Yi.Tuning the Electronic Transport Properties of Zigzag Graphene Nanoribbons via Hydrogenation Separators.Journal of Physical Chemistry C, 2011, 115(49): 24366-24372.

[160]Xie, Zhong-Xiang; Chen, Ke-Qiu*; Tang, Li-Ming.Ballistic phonon thermal transport in a cylindrical semiconductor nanowire modulated with nanocavity.Journal of Applied Physics, 2011, 110(12): 124321.

[161]Peng, Xiao-Fang*; Wang, Xin-Jun; Gong, Zhi-Qiang; Chen, Ke-Qiu.Ballistic thermal conductance in graphene nanoribbon with double-cavity structure.Applied Physics Letters, 2011, 99(23): 233105.

[162]Fan, Zhi-Qiang; Chen, Ke-Qiu*.Theoretical investigation of gate voltage controllable transport properties in single c-60 molecular device.International Journal of Modern Physics B, 2011, 25(29): 3871-3880.

[163]Yu, Xia*; Chen, Ke-Qiu*; Zhang, Yan.Optimization design of diffractive phase elements for beam shaping.Applied Optics, 2011, 50(31): 5938-5943.

[164]Zeng, Jing; Chen, Ke-Qiu*; He, Jun; Zhang, Xiao-Jiao; Hu, W. P..Rectifying and successive switch behaviors induced by weak intermolecular interaction.Organic Electronics, 2011, 12(10): 1606-1611.

[165]Zhang, Xiao-Jiao; Chen, Ke-Qiu*; Tang, Li-Ming; Long, Meng-Qiu.Electronic transport properties on V-shaped-notched zigzag graphene nanoribbons junctions.Physics Letters A, 2011, 375(37): 3319-3324.

[166]Xie, Zhong-Xiang; Chen, Ke-Qiu*; Duan, Wenhui.Thermal transport by phonons in zigzag graphene nanoribbons with structural defects.Journal of Physics: Condensed Matter , 2011, 23(31): 315302.

[167]Li, Xiao-Fei; Wang, Ling-Ling; Chen, Ke-Qiu; Luo, Yi*.Design of Graphene-Nanoribbon Heterojunctions from First Principles.Journal of Physical Chemistry C, 2011, 115(25): 12616-12624.

[168]Zeng, Jing; Chen, Ke-Qiu*; He, Jun; Fan, Zhi-Qiang; Zhang, Xiao-Jiao.Nitrogen doping-induced rectifying behavior with large rectifying ratio in graphene nanoribbons device.Journal of Applied Physics, 2011, 109(12): 124502.

[169]Fan, Zhi-Qiang; Chen, Ke-Qiu*.Controllable rectifying performance in a C-60 molecular device with asymmetric electrodes.Journal of Applied Physics, 2011, 109(12): 124505.

[170]He, Jun; Chen, Ke-Qiu*; Fan, Zhi-Qiang; Tang, Li-Ming; Hu, W. P..Transition from insulator to metal induced by hybridized connection of graphene and boron nitride nanoribbons.Applied Physics Letters, 2010, 97(19): 193305.

[171]Jiang, Lang; Gao, Jianhua; Fu, Yanyan; Dong, Huanli*; Zhao, Huaping; Li, Hongxiang; Tang, Qingxin; Chen, Keqiu; Hu, Wenping.Tuning intermolecular non-covalent interactions for nanowires of organic semiconductors.Nanoscale, 2010, 2(12): 2652-2656.

[172]Ren, Yun; Chen, Ke-Qiu*; He, Jun; Tang, Li-Ming; Pan, Anlian; Zou, B. S.; Zhang, Yan.Mechanically and electronically controlled molecular switch behavior in a compound molecular device.Applied Physics Letters, 2010, 97(10): 103506.

[173]Ren, Yun; Chen, Ke-Qiu*; Wan, Qing; Pan, Anlian; Hu, W. P..Negative differential resistance in polymer molecular devices modulated with molecular length.Physics Letters A, 2010, 374(37): 3857-3862.

[174]Zhou, B. H.*; Liao, W. H.; Zhou, B. L.; Chen, K. -Q.; Zhou, G. H.Electronic transport for a crossed graphene nanoribbon junction with and without doping.European Physical Journal B, 2010, 76(3): 421-425.

[175]Li, Xiao-Fei; Chen, Ke-Qiu; Wang, Lingling; Luo, Yi*.Effects of Interface Roughness on Electronic Transport Properties of Nanotube-Molecule-Nanotube Junctions.Journal of Physical Chemistry C, 2010, 114(28): 12335-12340.

[176]He, Meng-Dong*; Wang, Ling-Ling; Huang, Wei-Qing; Zou, Bing-Sou; Chen, Ke-Qiu.Localized wannier exciton in defect layer embedded between two semi-infinite superlattices.International Journal of Modern Physics B, 2010, 24(18): 3501-3511.

[177]Fan, Zhi-Qiang; Chen, Ke-Qiu*; Wan, Qing; Zhang, Yan.Electronic transport properties in a bimolecular device modulated with different side groups.Journal of Applied Physics, 2010, 107(11): 113713.

[178]Peng, Xiao-Fang; Chen, Ke-Qiu*; Wan, Qing; Zou, B. S.; Duan, Wenhui.Quantized thermal conductance at low temperatures in quantum wire with catenoidal contacts.Physical Review B, 2010, 81(19): 195317.

[179]Peng, Xiao-Fang; Chen, Ke-Qiu*.Ballistic thermal transport in quantum wire modulated with two coupling quantum dots.Physica E: Low-Dimensional Systems and Nanostructures , 2010, 42(7): 1968-1972.

[180]Xie, Fang; Chen, Ke-Qiu*; Peng, Xiao-Fang; Wang, Y. G.; Zhang, Z. H..Acoustic phonon selective transport and non-integer quantized thermal conductance in a three-dimensional asymmetric quantum structure.Physics Letters A, 2010, 374(19-20): 2062-2068.

[181]Tang, Li-Ming*; Wang, Ling-Ling; Wang, Dan; Liu, Jian-Zhe; Chen, Ke-Qiu.Donor-donor binding in In2O3: Engineering shallow donor levels.Journal of Applied Physics, 2010, 107(8): 083704.

[182]Qiu, M.; Zhang, Z. H.*; Deng, X. Q.; Chen, K. Q.Conduction switching behaviors of a small molecular device.Journal of Applied Physics, 2010, 107(6): 063704.

[183]Fan, Zhi-Qiang; Chen, Ke-Qiu*.First-principles study of side groups effects on the electronic transport in conjugated molecular device.Physica E: Low-Dimensional Systems and Nanostructures , 2010, 42(5): 1492-1496.

[184]Ren, Yun; Chen, Ke-Qiu*.Effects of symmetry and Stone-Wales defect on spin-dependent electronic transport in zigzag graphene nanoribbons.Journal of Applied Physics, 2010, 107(4): 044514.

[185]Fan, Zhi-Qiang; Chen, Ke-Qiu*.Negative differential resistance and rectifying behaviors in phenalenyl molecular device with different contact geometries.Applied Physics Letters, 2010, 96(5): 053509.

[186]Yu, Xiao-Yan; Peng, Xiao-Fang; Chen, Ke-Qiu*.Thermal transport by ballistic phonon in a semiconductor rectangular quantum wire modulated with quantum dot.Modern Physics Letters B, 2009, 23(30): 3597-3607.

[187]Li, Xiao-Fei*; Wang, Lingling; Chen, Ke-Qiu; Luo, Yi.Nanomechanically induced molecular conductance switch.Applied Physics Letters, 2009, 95(23): 232118.

[188]Tang, Gui-Ping; Fan, Zhi-Qiang; Zhang, Xiao-Jiao; Ren, Yun; Chen, Ke-Qiu*.Negative differential resistance behaviour in OPE molecular devices with semiconductor electrodes.Journal of Physics D: Applied Physics , 2009, 42(17): 175104.

[189]Liu, Zong-liang; Yu, Xiao-yan; Chen, Ke-Qiu*.Thermal transport associated with ballistic phonons in asymmetric quantum structures.Frontiers of Physics in China, 2009, 4(3): 420-425.

[190]Zhou, Ling-Ping*; Wang, Ming-Pu; Zhu, Jia-Jun; Peng, Xiao-Fang; Chen, Ke-Qiu*.Effects of dimensionality on the ballistic phonon transport and thermal conductance in nanoscale structures.Journal of Applied Physics, 2009, 105(11): 114318.

[191]Chen, Gui-Lin; Peng, Xiao-Fang; Chen, Ke-Qiu*; Zhang, Yan.The evolution of the localized plasmon modes in a semi-infinite superlattice with cap layer.Physica E: Low-Dimensional Systems and Nanostructures , 2009, 41(7): 1347-1352.

[192]Ren, Yun; Chen, Ke-Qiu*; Wan, Qing; Zou, B. S.; Zhang, Yan.Transitions between semiconductor and metal induced by mixed deformation in carbon nanotube devices.Applied Physics Letters, 2009, 94(18): 183506.

[193]Zhang, Xiao-Jiao; Long, Meng-Qiu; Chen, Ke-Qiu*; Shuai, Z.; Wan, Qing; Zou, B. S.; Zhang, Yan.Electronic transport properties in doped C-60 molecular devices.Applied Physics Letters, 2009, 94(7): 073503.

[194]Xie, Fang; Chen, Ke-Qiu*; Wang, Y. G.; Wan, Qing; Zou, B. S.; Zhang, Yan.Acoustic phonon transport and ballistic thermal conductance through a three-dimensional double-bend quantum structure.Journal of Applied Physics, 2008, 104(5): 054312.

[195]Wang, Xin-Jun*; Gong, Zhi-Qiang; He, Meng-dong; Chen, Ke-Qiu; Wang, Lingling.Effect of structural defect on phonon transmission quantization in low-dimensional superlattices.Physica E: Low-Dimensional Systems and Nanostructures , 2008, 40(9): 3014-3019.

[196]Yao, Ling-Jiang; Wang, Lingling; Peng, Xiao-Fang; Zou, B. S.; Chen, Ke-Qiu*.Thermal conductance in a quantum waveguide modulated with quantum dots.Physica E: Low-Dimensional Systems and Nanostructures , 2008, 40(9): 2862-2868.

[197]Fan, Zhi-Qiang; Chen, Ke-Qiu*; Wan, Qing; Zou, B. S.; Duan, Wenhui; Shuai, Z.Theoretical investigation of the negative differential resistance in squashed C-60 molecular device.Applied Physics Letters, 2008, 92(26): 263304.

[198]Long, Meng-Qiu; Chen, Ke-Qiu*; Wang, Lingling; Qing, Wan; Zou, B. S.; Shuai, Z..Negative differential resistance behaviors in porphyrin molecular junctions modulated with side groups.Applied Physics Letters, 2008, 92(24): 243303.

[199]Xie, Fang; Chen, Ke-Qiu*; Wang, Y. G.; Zhang, Yan.Effect of the evanescent modes on ballistic thermal transport in quantum structures.Journal of Applied Physics, 2008, 103(8): 084501.

[200]Long, Meng-Qiu*; Wang, Lingling; Chen, Ke-Qiu.Effects of structural and central metal ions modification on the electronic transport properties of porphyrin molecular junctions.Modern Physics Letters B, 2008, 22(9): 661-670.

[201]Geng, Hua; Hu, Yibin; Shuai, Zhigang*; Xia, Ke; Gao, Hongjun; Chen, Keqiu.Molecular design of negative differential resistance device through intermolecular interaction.Journal of Physical Chemistry C, 2007, 111(51): 19098-19102.

[202]Long, Meng-Qiu; Chen, Ke-Qiu*; Wang, Lingling; Zou, B. S.; Shuai, Z.Negative differential resistance induced by intermolecular interaction in a bimolecular device.Applied Physics Letters, 2007, 91(23): 233512.

[203]Li, Xiao-Fei; Chen, Ke-Qiu*; Wang, Lingling; Long, Meng-Qiu; Zou, B. S.; Shuai, Z..Effect of length and size of heterojunction on the transport properties of carbon-nanotube devices.Applied Physics Letters, 2007, 91(13): 133511.

[204]Nie, Liu-Ying; Wang, Lingling; Chen, Ke-Qiu; Zou, B. S.; Zhao, L. H.Thermal conductance in quantum wire with two obstacles.Physica E: Low-Dimensional Systems and Nanostructures , 2007, 39(2): 185-190.

[205]Long, Meng-Qiu; Wang, Lingling; Chen, Ke-Qiu*; Li, Xiao-Fei; Zou, B. S.; Shuai, Z.Coupling effect on the electronic transport through dimolecular junctions.Physics Letters A, 2007, 365(5-6): 489-494.

[206]Peng, Xiao-Fang; Chen, Ke-Qiu*; Zou, B. S.; Zhang, Yan.Ballistic thermal conductance in a three-dimensional quantum wire modulated with stub structure.Applied Physics Letters, 2007, 90(19): 193502.

[207]Nie, Liu-Ying; Wang, Lingling*; Zhao, L. H.; Chen, Ke-Qiu*.Acoustic phonon transport and thermal conductance in a multiple channels nanostructure.Physics Letters A, 2007, 364(3-4): 343-347.

[208]Li, Xiao-Fei; Chen, Ke-Qiu*; Wang, Ling-Ling; Long, Meng-Qiu; Zou, B. S.; Shuai, Z.Effect of intertube interaction on the transport properties of a carbon double-nanotube device.Journal of Applied Physics, 2007, 101(6): 064514.

[209]Tang, Li-Ming; Wang, Lingling*; Huang, Wei-Qing; Zou, B. S.; Chen, Ke-Qiu*.Acoustic phonon transport and thermal conductance in a periodically modulated quantum wire.Journal of Physics D-Applied Physics, 2007, 40(5): 1497-1500.

[210]Wang Xin-Jun*; Wang Ling-Ling; Huang Wei-Qing; Tang Li-Ming; Zou Bing-Suo; Chen Ke-Qiu.Influence of ternary mixed crystal defect layer on the localized interface optical-phonon modes in a finite superlattice.Acta Physica Sinica, 2007, 56(1): 429-436.

[211]Nie, Liu-Ying; Wang, Lingling*; Zhao, L. H.; Huang, Wei-Qing; Tang, Li-Ming; Wang, Xin-Jun; Chen, Ke-Qiu*.The influence of boundary conditions on thermal conductance in semiconductor quantum wire with structural defect.Physics Letters A, 2006, 359(3): 234-240.

[212]Li, Wenxia*; Chen, Keqiu.Phonon heat transport through periodically stubbed waveguides.Physics Letters A, 2006, 357(4-5): 378-383.

[213]Wang Xin-Jun*; Wang Ling-Ling; Huang Wei-Qing; Tang Li-Ming; Chen Ke-Qiu.The localized electronic states and transmission spectra in N-layer superlattice with structural defects in finite magnetic fields.Acta Physica Sinica, 2006, 55(7): 3649-3655.

[214]Wang, XJ; Wang, LL; Huang, WQ; Tang, LM; Zou, BS; Chen, KQ *.A surface optical phonon assisted transition in a semi-infinite superlattice with a cap layer.Semiconductor Science and Technology, 2006, 21(6): 751-757.

[215]Tang, LM; Wang, LL; Chen, KQ *; Huang, WQ; Zou, BS.Coupling effect on phonon thermal transport in a double-stub quantum wire.Applied Physics Letters, 2006, 88(16): 163505.

[216]Hu, WP*; Jiang, J; Nakashima, H; Luo, Y; Kashimura, Y; Chen, KQ ; Shuai, Z; Furukawa, K; Lu, W; Liu, YQ; Zhu, DB; Torimitsu, K.Electron transport in self-assembled polymer molecular junctions.Physical Review Letters, 2006, 96(2): 027801.

[217]Tang, QX; Li, HX; He, M; Hu, WP*; Liu, CM; Chen, KQ ; Wang, C; Liu, YQ; Zhu, DB.Low threshold voltage transistors based on individual single-crystalline submicrometer-sized ribbons of copper phthalocyanine.Advanced Materials, 2006, 18(1): 65-68.

[218]Pan, AL; Liu, RB; Yang, Q; Zhu, YC; Yang, GZ; Zou, BS*; Chen, KQ .Stimulated emissions in aligned CdS nanowires at room temperature.Journal of Physical Chemistry B, 2005, 109(51): 24268-24272.

[219]Huang, WQ; Chen, KQ *; Shuai, Z; Wang, LL; Hu, WY; Zou, BS.Acoustic-phonon transmission and thermal conductance in a double-bend quantum waveguide.Journal of Applied Physics, 2005, 98(9): 093524.

[220]Wang, XJ; Wang, LL; Huang, WQ; Chen, KQ *; Shuai, Z; Zou, BS.The evolution of the localized interface optical-phonon modes in a finite superlattice with a structural defect.Semiconductor Science and Technology, 2005, 20(10): 1027-1033.

[221]Huang, WQ; Chen, KQ *; Shuai, Z; Wang, LL; Hu, WY; Zuo, BS。Localized electronic states in N-layer-based superlattices with structural defects.Physica E: Low-Dimensional Systems and Nanostructures , 2005, 28(4): 374-384.

[222]Chen, KQ *; Li, WX; Duan, W; Shuai, Z; Gu, BL.Effect of defects on the thermal conductivity in a nanowire.Physical Review B, 2005, 72(4): 045422.

[223]Huang, WQ*; Chen, KQ *; Shuai, Z; Wang, LL; Hu, WY.Lattice thermal conductivity in a hollow silicon nanowire.International Journal of Modern Physics B, 2005, 19(6): 1017-1027.

[224]Huang, WQ; Chen, KQ *; Shuai, Z*; Wang, LL; Hu, WY.Discontinuity effect on the phonon transmission and thermal conductance in a dielectric quantum waveguide.Physics Letters A, 2005, 336(2-3): 245-252.

[22]5Huang, WQ*; Chen, KQ ; Shuai, ZG; Wang, LL; Hu, WY.Magneto-coupling effect on surface electron states in a semi-infinite superlattice.Acta Physica Sinica, 2004, 53(7): 2330-2335.

[226]Zhang, XL*; Gu, BY; Chen, KQ .Effect of different coupling on localized interface optical-phonon modes in N-constituent superlattices with a defect layer.Physics Letters A, 2003, 316(1-2): 107-117.

[227]Chen, KQ *; Duan, WH; Li, WX; Wu, R; Wang, HY; Gu, BL.Influence of the structural defects on localized interface optical-phonon modes in periodically layered heterostructures.Microelectronic Engineering, 2003, 66(1-4): 26-32.

[228]Chen, KQ *; Duan, WH; Wu, J; Gu, BL; Gu, BY.Localized interface optical phonon modes in a semi-infinite superlattice with a cap layer.Journal of Physics-Condensed Matter, 2002, 14(50): 13761-13775.

[229]Chen, KQ *; Duan, WH; Gu, BL; Gu, BY.Localized interface optical-phonon modes in two coupled semi-infinite superlattices.Physics Letters A, 2002, 299(5-6): 634-643.

[230]Chen, KQ *; Wang, XH; Gu, BY.Effect of structural defects consisting of ternary mixed crystals on localized interface optical modes in superlattices.Physical Review B, 2002, 65(15): 153305.

[231]Chen, KQ *; Wang, XH; Gu, BY.Localized interface optical-phonon modes in superlattices with structural defects.Physical Review B, 2000, 62(15): 9919-9922.

[232]Chen, KQ ; Wang, XH*; Gu, BY.Localized folded acoustic phonon modes in coupled superlattices with structural defects.Physical Review B, 2000, 61(18): 12075-12081.

[233]Zhou, Wu Xing; Cheng, Yuan; Chen, Ke Qiu; Xie, Guofeng*; Wang, Tian*; Zhang, Gang*.Thermal Conductivity of Amorphous Materials.Advanced Functional Materials, 1903829.

[234]Zeng, Yu Jia; Wu, Dan; Cao, Xuan Hao; Zhou, Wu Xing; Tang, Li Ming; Chen, Ke Qiu*.Nanoscale Organic Thermoelectric Materials: Measurement, Theoretical Models, and Optimization Strategies.Advanced Functional Materials, 1903873.

發(fā)表中文期刊論文： 

[1]段志福, 丁長(zhǎng)浩, 丁中科, 肖威華, 謝芳, 羅南南, 曾犟, 唐黎明, 陳克求. GaInX₃（X = S, Se, Te）:Ultra-low thermal conductivity and excellent thermoelectric performance[J]. Chinese Physics B, 2024, 33 (08): 478-484.

[2]吳培成, 陳克求, 陳曙光. 物理專業(yè)本科生科研能力評(píng)價(jià)指標(biāo)體系研究[J]. 高等理科教育, 2021, (04): 90-95.

[3]王新軍,王玲玲,黃維清,唐黎明,鄒炳鎖,陳克求.三元合金缺陷層對(duì)有限超晶格中局域界面光學(xué)聲子模的影響[J].物理學(xué)報(bào),2007(01):429-436.

[4]王新軍,王玲玲,黃維清,唐黎明,陳克求.磁場(chǎng)下含結(jié)構(gòu)缺陷多組分超晶格中的局域電子態(tài)和電子輸運(yùn)[J].物理學(xué)報(bào),2006(07):3649-3655.

[5]黃維清,陳克求,帥志剛,王玲玲,胡望宇.磁耦合效應(yīng)對(duì)半無(wú)限超晶格中表面電子態(tài)的影響[J].物理學(xué)報(bào),2004(07):2330-2335.

[6]陳小華,彭景翠,陳克求,陳宗璋.高壓低溫下固體C₆₀中的取向有序態(tài)及再取向的弛豫行為[J].物理學(xué)報(bào),1998(04):145-150.

發(fā)表會(huì)議論文： 

[1]陳克求. 納米體系熱電轉(zhuǎn)換機(jī)理研究[C]. 中國(guó)化學(xué)會(huì)第30屆學(xué)術(shù)年會(huì)摘要集-論壇二：新型前沿交叉化學(xué)論壇.:16.

[2]曾晶; 周艷紅; 范志強(qiáng); 李柏林; 陳克求. 分子尺度器件電荷傳輸自旋調(diào)控機(jī)理[C]. 中國(guó)化學(xué)會(huì)第30屆學(xué)術(shù)年會(huì)摘要集-第四十分會(huì)：納米體系理論與模擬.2016:12.

[3]陳克求. Negative differential resistance in nanoscale devices[C]. 中國(guó)化學(xué)會(huì)第29屆學(xué)術(shù)年會(huì)摘要集——第36分會(huì)：納米體系理論與模擬.2014:10.

[4]陳克求. 有機(jī)分子器件結(jié)構(gòu)、功能與電荷傳輸機(jī)理[C]. 中國(guó)化學(xué)會(huì)第十二屆全國(guó)量子化學(xué)會(huì)議論文摘要集.2014:961. 

 

榮譽(yù)獎(jiǎng)勵(lì)：

1、2016年度湖南省自然科學(xué)獎(jiǎng)二等獎(jiǎng)1項(xiàng)（排名第一）。

2、獲湖南省教學(xué)成果獎(jiǎng)一等獎(jiǎng)1項(xiàng)（排名第二）。

3、湖南大學(xué)優(yōu)秀教師。

4、湖南大學(xué)科研標(biāo)兵。

5、湖南大學(xué)師德標(biāo)兵。

6、湖南省首屆“優(yōu)秀研究生導(dǎo)師”。

搜狐報(bào)道：

本色如磐 為科教興國(guó)獻(xiàn)終生

記湖南大學(xué)物理與微電子科學(xué)學(xué)院教授 陳克求

2019-09-04 14:21

陳克求，1964年1月生，湖南大學(xué)物理與微電子科學(xué)學(xué)院教授、博士生導(dǎo)師、副院長(zhǎng)、湖南大學(xué)教學(xué)委員會(huì)委員、院教授委員會(huì)副主任委員、湖南省省政協(xié)委員、湖南省物理學(xué)會(huì)常務(wù)理事，擔(dān)任多個(gè)學(xué)術(shù)雜志編委以及Nature Material等10余個(gè)國(guó)際著名學(xué)術(shù)期刊評(píng)審專家。

2001年獲中國(guó)科學(xué)院物理研究所理學(xué)博士學(xué)位；2001-2003年在清華大學(xué)物理系凝聚態(tài)物理研究所從事博士后研究工作；2003年調(diào)入中國(guó)科學(xué)院化學(xué)研究有機(jī)固體重點(diǎn)實(shí)驗(yàn)室，任副研究員；2005年調(diào)入湖南大學(xué)任教授、博士生導(dǎo)師。

自2005年從中科院調(diào)入湖南大學(xué)工作以來(lái)，陳克求先后主持了國(guó)家級(jí)項(xiàng)目10余項(xiàng)、省部級(jí)重點(diǎn)項(xiàng)目多項(xiàng)。近幾年在納米體系的輸運(yùn)理論和納米器件的計(jì)算設(shè)計(jì)方面取得了一系列研究成果，在國(guó)際有影響的SCI源刊上發(fā)表了240余篇學(xué)術(shù)論文，SCI引用近6000次。國(guó)際物理學(xué)頂級(jí)評(píng)論刊Ｒev. Mod. Phys引用了其在輸運(yùn)理論方面的系列工作，他的研究工作受到了國(guó)內(nèi)外同行的關(guān)注和好評(píng)。目前感興趣的研究方向?yàn)椋海ㄒ唬┘{米體系熱輸運(yùn)理論及熱量子器件的計(jì)算設(shè)計(jì)、（二）分子器件電子輸運(yùn)理論及新型功能分子器件的計(jì)算設(shè)計(jì)、（三）新型熱電轉(zhuǎn)換機(jī)理與器件計(jì)算設(shè)計(jì)、（四）熱解氣化裝置傳熱傳質(zhì)機(jī)理研究。

學(xué)物理的陳克求教授愛(ài)好廣泛，自幼就對(duì)傳統(tǒng)文化保持濃厚興趣，熟讀古書，豐富的人文經(jīng)史學(xué)養(yǎng)形成了陳克求教授獨(dú)特的治學(xué)特點(diǎn)和個(gè)人魅力，用《詩(shī)經(jīng)》中“有斐君子，如切如磋，如琢如磨”來(lái)形容陳教授，最是恰當(dāng)：做學(xué)問(wèn)，如加工骨器，不斷切磋；自我修煉，如打磨美玉，反復(fù)琢磨。

“絕知此事需躬行�！标惪饲蠖嗄陙�(lái)一直堅(jiān)持在科研第一線，查閱文獻(xiàn)，驗(yàn)數(shù)據(jù)，推公式，寫文章等等，他從不會(huì)越過(guò)任何一個(gè)科研流程，“自己把握好了前沿的研究方向，才能指導(dǎo)好學(xué)生；自己以身作則了，才能影響好他人�！标惪饲笳f(shuō)，做學(xué)問(wèn)的人不親歷親為，學(xué)問(wèn)既做不成深度也做不成高度，那就更談不上出創(chuàng)新成果了。踏踏實(shí)實(shí)做了，出了成果，感覺(jué)心里才有底氣和成就感，否則心里會(huì)發(fā)虛。

作為教師，陳克求要求自己除了專業(yè)素養(yǎng)過(guò)硬以外，其對(duì)科學(xué)求真求實(shí)的品質(zhì)和責(zé)任心也是激勵(lì)學(xué)生堅(jiān)持和克服困難的關(guān)鍵因素。最重要的是發(fā)現(xiàn)學(xué)生的興趣，點(diǎn)燃學(xué)生的科研熱情，把學(xué)生培養(yǎng)成具有獨(dú)立精神的科研工作者是他在執(zhí)教多年來(lái)培養(yǎng)學(xué)生的原則�！安�學(xué)篤志，切問(wèn)近思，厚積薄發(fā)”是他的研究生、現(xiàn)已成為其同事的物理學(xué)院教授唐黎明對(duì)他的評(píng)價(jià)。2019年獲湖南省首屆“優(yōu)秀研究生導(dǎo)師”。

陳克求用新的目標(biāo)和嘗試來(lái)踐行自己的責(zé)任：做好教學(xué)課程改革，把最新的前沿科研成果及時(shí)地介紹給學(xué)生，這是對(duì)教育的責(zé)任；帶領(lǐng)優(yōu)秀的年輕學(xué)生勇攀科學(xué)高峰，參與并組織國(guó)內(nèi)各類學(xué)術(shù)活動(dòng)，經(jīng)常邀請(qǐng)國(guó)內(nèi)外名家到課題組和物理院講學(xué)和學(xué)術(shù)交流，為保持并發(fā)展物理院物理學(xué)科研究的良好勢(shì)頭盡自己的一份力，這是對(duì)科研的責(zé)任。陳克求自己一直是帶著興趣做科研。

謙遜的他總是不愿過(guò)多的談到自己的成績(jī)。一路的艱辛和收獲已經(jīng)屬于過(guò)去，陳克求的目標(biāo)在更前方。

湖南大學(xué)報(bào)報(bào)道：

靜水流深聞喧享靜

———訪物理與微電子科學(xué)學(xué)院教授陳克求

人物名片：陳克求，湖南大學(xué)物理與微電子科學(xué)學(xué)院教授、博士生導(dǎo)師�，F(xiàn)為物理學(xué)博士點(diǎn)凝聚態(tài)物理方向?qū)W術(shù)帶頭人、湖南省物理學(xué)重點(diǎn)學(xué)科凝聚態(tài)物理方向?qū)W術(shù)帶頭人、湖南省微納結(jié)構(gòu)物理與應(yīng)用技術(shù)重點(diǎn)實(shí)驗(yàn)室學(xué)術(shù)帶頭人之一兼學(xué)術(shù)委員會(huì)委員、應(yīng)用物理系主任。

自2005年從中科院調(diào)入湖南大學(xué)工作以來(lái)，陳克求先后主持了國(guó)家自然科學(xué)基金項(xiàng)目六項(xiàng)、國(guó)家科技部973課題子項(xiàng)目三項(xiàng)、高等學(xué)校博士點(diǎn)基金項(xiàng)目一項(xiàng)、及湖南省自然科學(xué)基金重點(diǎn)項(xiàng)目?jī)身?xiàng)，作為主要人員參與了國(guó)家自然科學(xué)基金重點(diǎn)項(xiàng)目一項(xiàng)。近幾年在納米體系的輸運(yùn)理論和納米器件的計(jì)算設(shè)計(jì)方面取得了一系列研究成果，在國(guó)際有影響的SCI源刊上發(fā)表了110余篇學(xué)術(shù)論文。目前感興趣的研究方向?yàn)椋海ㄒ唬┘{米體系熱輸運(yùn)理論及熱量子器件的計(jì)算設(shè)計(jì)、（二）分子器件中的電子輸運(yùn)理論及新型功能分子器件的計(jì)算設(shè)計(jì)、（三）新型光電、熱電功能器件原理與計(jì)算設(shè)計(jì)。

采訪陳克求教授之前，記者心里很忐忑，一是之前了解到學(xué)問(wèn)做得頂呱呱的陳教授很低調(diào)，不喜歡宣傳自己，從沒(méi)接受過(guò)任何媒體的采訪；二是見(jiàn)到物理數(shù)學(xué)學(xué)得好的人除了由衷佩服外還有些“怯”，在記者看來(lái)，他們的腦子除了太好使外也存在另一種 “刻板”，少了變通。

在與相貌堂堂、儀表莊重的陳教授交流之后，記者感受到的是，陳教授除了儒雅、謙恭有加以外，就是他的博學(xué)、健談與風(fēng)趣，整個(gè)采訪過(guò)程輕松、愉快。學(xué)物理的陳克求教授愛(ài)好廣泛，自幼就對(duì)傳統(tǒng)文化保持濃厚興趣的他，熟讀古書，經(jīng)史子集，無(wú)所不涉。言談中，他引經(jīng)據(jù)典，信手拈來(lái)。豐富的經(jīng)史學(xué)養(yǎng)形成了陳克求教授獨(dú)特的治學(xué)特點(diǎn)和個(gè)人魅力，用《詩(shī)經(jīng)》中“有斐君子，如切如磋，如琢如磨”來(lái)形容陳教授，最是恰當(dāng)：做學(xué)問(wèn)，如加工骨器，不斷切磋；自我修煉，如打磨美玉，反復(fù)琢磨。

做學(xué)問(wèn) 清譽(yù)為重1982年，陳克求被國(guó)防科技大學(xué)應(yīng)用物理系錄取，自此，開(kāi)始了他物理教學(xué)及研究的“修行”之旅。

基礎(chǔ)科學(xué)研究是原始創(chuàng)新的一個(gè)源頭，也是整個(gè)科技工作的基礎(chǔ)，其重要性不言而喻的。但從事基礎(chǔ)科學(xué)研究的確很難像一些顯學(xué)那樣容易成名成家，研究者的成果也很難被更多人理解，而在陳克求看來(lái)這種少了喧囂的寂寞恰恰是他最需要的。他說(shuō)，做學(xué)問(wèn)“清譽(yù)”比“榮譽(yù)”更重要，需要的就是內(nèi)心“干凈”和“清靜”。內(nèi)心干凈，才能夠超越功利和私念，從容而淡泊，才不會(huì)為了表面的榮譽(yù)而自毀學(xué)術(shù)清譽(yù)；內(nèi)心清靜才能坐得住冷板凳，沉下心來(lái)踏踏實(shí)實(shí)做學(xué)問(wèn)。

所謂“內(nèi)行看門道，外行看熱鬧”，在陳克求所從事的研究領(lǐng)域，看熱鬧的人是少之又少，但學(xué)問(wèn)到底做得如何，內(nèi)行人人心里有數(shù)。要做出讓同行們認(rèn)可的成績(jī)，并不是一件輕而易舉的事情，需要長(zhǎng)時(shí)間積累“功力”。多年來(lái)，陳克求憑著自己扎實(shí)的理論功底、對(duì)研究領(lǐng)域發(fā)展方向的準(zhǔn)確把握、持之以恒的科研精神及高尚的學(xué)術(shù)操守，在半導(dǎo)體納米器件電子輸運(yùn)和熱輸運(yùn)機(jī)理研究和計(jì)算設(shè)計(jì)方面的系列性研究工作取得了豐碩成果，在國(guó)際著名學(xué)術(shù)期刊上發(fā)表學(xué)術(shù)論文110余篇（均為SCI源刊），SCI引用1000余次，其中20余篇論文作為納米科學(xué)與技術(shù)的原創(chuàng)性論文收入到美國(guó)的Virtual Journal of Nanoscale Science &Technology），國(guó)際頂級(jí)評(píng)論期刊Rev.ofMod.Phys(影響因子高于51)從正面評(píng)論了其在輸運(yùn)理論方面的系列工作，他的成績(jī)受到了國(guó)內(nèi)外同行的廣泛關(guān)注和好評(píng)。

“有心、問(wèn)路，做高尚人、求真學(xué)問(wèn)�！薄�——這是陳克求的博士生導(dǎo)師、中科院物理所顧本源先生給學(xué)生的寄語(yǔ)，也是先生一生恪守的為人治學(xué)之道。先生的恪言，作為學(xué)生的他踐行了。

求學(xué)問(wèn) 當(dāng)求明師師有名師和明師之分。在陳克求看來(lái)，做學(xué)問(wèn)猶如“修行”，修行者，須遇明師，須得明師指點(diǎn)，乃能成正果。他坦言，當(dāng)今學(xué)術(shù)界浮躁功利之風(fēng)盛行，追“名”師效益來(lái)得更快，但真正有志于做學(xué)問(wèn)，求得那些值得仰視和敬佩、在行業(yè)內(nèi)有口皆碑的“明”師才是最幸運(yùn)的。

陳克求就有了這份幸運(yùn)。作為科研工作者最重要的博士求學(xué)階段，他遇到了對(duì)他學(xué)術(shù)影響最為深刻的明師———顧本源先生。顧本源先生一生淡泊名利，唯以做研究為樂(lè)，治學(xué)嚴(yán)謹(jǐn)，直到去世前三個(gè)月還在查閱文獻(xiàn)，推導(dǎo)公式。先生對(duì)“有心、問(wèn)路”有精彩的釋義：“心術(shù)正，學(xué)問(wèn)盛。有心者，事必成。學(xué)問(wèn)學(xué)問(wèn)，好學(xué)善問(wèn)。敢問(wèn)‘路在何方’？找到好導(dǎo)師，三生有幸，結(jié)伴同行，何懼征途難?‘峰回路轉(zhuǎn)疑無(wú)路，柳暗花明又一村’。絕處逢生，才是精彩人生�；ǚ绷�茂處,撥得開(kāi)才是手段；風(fēng)狂雨急時(shí)，立得定方見(jiàn)腳力。走自己的路，奉獻(xiàn)一生。”先生對(duì)他學(xué)術(shù)道路的指引和學(xué)術(shù)期許，他不會(huì)忘懷！

視顧先生為學(xué)術(shù)榜樣的陳克求已然成了學(xué)生心中的“明師”。

“博學(xué)篤志，切問(wèn)近思，厚積薄發(fā)”是他的研究生、現(xiàn)已成為其同事的物理學(xué)院副院長(zhǎng)唐黎明對(duì)他的評(píng)價(jià)。

“虛空無(wú)處所，仿佛似琉璃�！贝T博連讀的周五星則認(rèn)為這句古詩(shī)最能恰到好處概括他的恩師陳克求。他說(shuō)，除非出差在外，每天早上最早到達(dá)知心樓辦公室的老師中一定有陳老師。作為一名在科研方面取得重大成就的物理學(xué)教授，陳老師不僅具備敏銳的思維、嚴(yán)謹(jǐn)?shù)闹螌W(xué)態(tài)度、淵博的學(xué)識(shí)、果斷干練的作風(fēng)，其誠(chéng)摯謙虛的品格和寬厚善良的處世方式也是學(xué)生們學(xué)習(xí)的榜樣。

“絕知此事需躬行�！标惪饲蠖嗄陙�(lái)一直堅(jiān)持在科研第一線，查閱文獻(xiàn)，驗(yàn)數(shù)據(jù)，推公式，寫文章等等，他從不會(huì)越過(guò)任何一個(gè)科研流程，“自己把握好了前沿的研究方向，才能指導(dǎo)好學(xué)生；自己以身作則了，才能影響好他人�！标惪饲笳f(shuō)，做學(xué)問(wèn)的人不親歷親為，學(xué)問(wèn)既做不成深度也做不成高度，那就更談不上出創(chuàng)新成果了。踏踏實(shí)實(shí)做了，出了成果，感覺(jué)心里才有底氣和成就感，否則心里會(huì)發(fā)虛。

為師者 責(zé)任在首“知之者不如好之者，好之者不如樂(lè)之者�！标惪饲笞约簬е�興趣做科研。發(fā)現(xiàn)學(xué)生的興趣，點(diǎn)燃學(xué)生的科研熱情，把學(xué)生培養(yǎng)成具有獨(dú)立精神的科研工作者是他在執(zhí)教多年來(lái)一以貫之的學(xué)生培養(yǎng)原則。

每年的研究生面試，陳克求都要親自參加，與學(xué)生進(jìn)行面對(duì)面交流，他不唯分?jǐn)?shù)是論。在他看來(lái)，能考上湖大的學(xué)生智商都不存在問(wèn)題，他最看重的是學(xué)生勤奮與踏實(shí)的品質(zhì)，如果能再加上興趣和專注力，就是“可造”之才。他說(shuō)，感興趣的點(diǎn)太多，什么都想做，最終導(dǎo)致什么都做不深，做不透。而教師最重要的品質(zhì)，陳克求認(rèn)為當(dāng)屬責(zé)任感，“有了責(zé)任感自然就會(huì)去研究自己的專業(yè)，鉆研教學(xué)理論，提高講課水平�！�

“做研究和讀書有些不同，記憶力好成績(jī)可能會(huì)好，但做研究必須踏踏實(shí)實(shí)，一步一個(gè)腳印，舍得投入時(shí)間和精力�！标惪饲笳f(shuō)，研究過(guò)程中一定會(huì)遇到困難，此時(shí)教師的作用至關(guān)重要。教師一定要能準(zhǔn)確判斷問(wèn)題出自哪具環(huán)節(jié)，這就要求教師除了專業(yè)素養(yǎng)過(guò)硬以外，其對(duì)科學(xué)求真求實(shí)的品質(zhì)和責(zé)任心也是激勵(lì)學(xué)生堅(jiān)持和克服困難的關(guān)鍵因素。

將自己在科研工作中關(guān)注的問(wèn)題、研究經(jīng)驗(yàn)、創(chuàng)新方法、人生感悟與課堂講授的基礎(chǔ)理論結(jié)合起來(lái)，讓學(xué)生切實(shí)體會(huì)到科研的樂(lè)趣和意義是陳克求教學(xué)的一大特點(diǎn)。陳克求說(shuō)，講課不能天花亂墜，一定要實(shí)實(shí)在在，要講對(duì)學(xué)生有用的東西。無(wú)論是對(duì)孩子還是學(xué)生的教育，陳克求都主張“無(wú)為”而治，倡導(dǎo)一種寬松且嚴(yán)格、自由但不隨性、充滿創(chuàng)意的學(xué)習(xí)和科研氛圍。他充分地相信學(xué)生，給予他們足夠的發(fā)展空間。在他的團(tuán)隊(duì)里，沒(méi)有強(qiáng)制的學(xué)習(xí)工作時(shí)間，但每個(gè)人都能自覺(jué)自愿認(rèn)真地做好自己的工作。良好的科研氛圍給了每個(gè)人潛能最好的發(fā)展空間。

如今，陳克求正在用新的目標(biāo)和嘗試來(lái)踐行自己的責(zé)任：做好教學(xué)課程改革，把最新的前沿科研成果及時(shí)地介紹給學(xué)生，這是對(duì)教育的責(zé)任；帶領(lǐng)優(yōu)秀的年輕學(xué)生勇攀科學(xué)高峰，參與并組織國(guó)內(nèi)各類學(xué)術(shù)活動(dòng)，經(jīng)常邀請(qǐng)國(guó)內(nèi)外名家到課題組和物理院講學(xué)和學(xué)術(shù)交流，為保持并發(fā)展物理院物理學(xué)科研究的良好勢(shì)頭盡自己的一份力，這是對(duì)科研的責(zé)任；作為一名政協(xié)委員，就相關(guān)問(wèn)題為決策部門提供咨詢意見(jiàn)，這是對(duì)社會(huì)的責(zé)任。 鄭梅珍

原文鏈接： http://hudabao.cuepa.cn/show_more.php?doc_id=707753