陈浩导师

发布者:刘翩发布时间:2018-04-02浏览次数:2037

姓名:

陈浩

性别:

出生年月:

19765

学历:

博士研究生

职务:

江苏师范大学技术转移中心副主任

职称:

教授

Email

Chenhao@jsnu.edu.cn

联系电话:


专业与主要研究方向:

1.固体激光器、光纤激光器及其在医学与工业领域的应用装备研究;

2.白光LED/激光照明技术及其产业化应用研究

教授课程:

1.光纤通信原理

2.光子学基础

研究生培养基础要求:

欢迎具有光学、光电子学及无机材料学知识基础,积极、热情、富有团队协作精神的同学。

个人教育简历:

1994.08-1998.06 江苏师范大学本科生

2001.09-2004.06 华东师范大学硕士生

2010.09-2013.06 复旦大学博士生

个人工作简历:

1998.08-2014.01 江苏师范大学历任助教、实验师、讲师、副教授、教授

2014.01-2016.12 江苏师范大学江苏省先进激光材料与器件重点实验室副主任

2017.01-至今江苏师范大学技术转移中心副主任

其中,2016.05-2016.10 台湾交通大学访问

近期主要主持的项目:

1.国家自然科学基金面上项目:Ho:YAG 透明陶瓷中“晶界”对激光振荡的调控机理研究(11274144)2012.01-2016.12;项目经费:86万;项目负责人。

2.国家自然科学基金面上项目:钬激光器双波长同带泵浦及双增益光谱平坦技术研究 (61775088)2018.01-2018.12;项目经费:16万;项目负责人。

3.徐州市工业重点研发项目:远程激发微晶白光LED关键技术及产业化研究(KC16GZ014);2016.10-2018.09;项目经费:50万;项目负责人。

4.其他在研项目2项,项目经费110万。

代表性论文:

1.Zhang Le, Zhou Tianyuan, Selim Farida A., Chen Hao.   Single CaO accelerated densification and microstructure control of highly   transparent YAG ceramic [J]. Journal of the American Ceramic Society, 2018,   101(2): 703-712.

2.Zhang Le, Jiang Zhigang, Yao Qing, Wang Zhongying,   Zhang Yikun, Wei Shuai, Zhou Tianyuan, Ben Yue, Sun Rong, Chen Hao. Stirring   speed assisted homogenization of precipitation reaction for enhanced optical   performance of Y2O3 transparent ceramics [J]. Ceramics International, 2018.

3.Yao Qing, Zhang Le, Jiang Zhigang, Huang Guocan, Zhou   Tianyuan, Ben Yue, Wei Shuai, Sun Rong, Chen Hao, Wang Yun. Isobam assisted   slurry optimization and gelcasting of transparent YAG ceramics [J]. Ceramics   International, 2018, 44(2): 1699-1704.

4.张乐周天元陈浩杨浩张其土宋波汪正平. Nd:YAG激光透明陶瓷的研究进展 [J]. 材料导报, 2017, 31(13): 41-50.

5.王骋魏帅甄方正周天元杨浩张乐陈浩化学沉淀法制备YAG透明陶瓷粉体研究进展 [J]. 材料导报, 2017, 31(Z2): 77-83.

6.Zhou Tianyuan, Zhang Le, Wei Shuai, Wang Lixi, Yang   Hao, Fu Zhenxiao, Chen Hao, Selim Farida A., Zhang Qitu. MgO assisted   densification of highly transparent YAG ceramics and their microstructural   evolution [J]. Journal of the European Ceramic Society, 2017, 38(2): 687-693.

7.Zhou Tianyuan, Zhang Le, Selim Farida A, Yang Hao,   Zhang Qitu, Sun Rong, Wong Chingping, Chen Hao. Annealing induced   discoloration of transparent YAG ceramics using divalent additives in   solid-state reaction sintering [J]. Journal of the European Ceramic Society,   2017, 37: 4123-4128.

8.Zhou Tianyuan, Zhang Le, Li Zheng, Wei Shuai, Wu   Jiadong, Wang Lixi, Yang Hao, Fu Zhenxiao, Chen Hao, Wong Chingping, Zhang   Qitu. Enhanced conversion efficiency of Cr4+ ion in Cr: YAG transparent   ceramic by optimizing the annealing process and doping concentration [J].   Journal of Alloys and Compounds, 2017, 703: 34-39.

9.Zhou Tianyuan, Zhang Le, Li Zheng, Wei Shuai, Wu   Jiadong, Wang Lixi, Yang Hao, Fu Zhenxiao, Chen Hao, Tang Dingyuan, Wong   Chingping, Zhang Qitu. Toward vacuum sintering of YAG transparent ceramic   using divalent dopant as sintering aids: Investigation of microstructural   evolution and optical property [J]. Ceramics International, 2017, 43(3):   3140-3146.

10.Zhang Le, Li Zheng,   Zhen Fangzheng, Wang Lixi, Zhang Qitu, Sun Rong, Selim Farida A., Wong   Chingping, Chen Hao. High sinterability nano-Y2O3 powders prepared via   decomposition of hydroxyl-carbonate precursors for transparent ceramics [J].   Journal of Materials Science, 2017, 52(14): 8556-8567.

11.Zhang Le, Ben Yue,   Wu Jiadong, Yang Hao, Wong Chingping, Zhang Qitu, Chen Hao. Alumina assisted   grain refinement and physical performance enhancement of yttria transparent   ceramics by two-step sintering [J]. Materials Science and Engineering: A,   2017, 684: 466–469.

12.Zhang Le, Ben Yue,   Chen Hao, Tang Dingyuan, Fu Xianzhu, Sun Rong, Song Bo, Wong Chingping. Low   temperature-sintering and microstructure of highly transparent yttria   ceramics [J]. Journal of Alloys and Compounds, 2017, 695: 2580-2586.

13.Wu Jiadong, Zhang   Le, Ben Yue, Chen Hao, Fu Xianzhu, Wong Chingping. Improved full-color   emission and switched luminescence in single Ca3(PO4)2: Dy3+, Eu3+ phosphors   for white LEDs [J]. Journal of Alloys and Compounds, 2017, 697: 215-221.

14.Wu Jiadong, Zhang   Chunxiang, Liu Jun, Zhao Ting, Yao Weichao, Tang Pinghua, Zhang Le, Chen Hao.   Over 19 W Single-Mode 1545 nm Er,Yb Codoped All-Fiber Laser, [J]. Advances in   Condensed Matter Physics, 2017, 2017(Article ID 7408565): 1-5.

15.Wei Shuai, Zhang   Le, Yang Hao, Zhou Tianyuan, Wong Chingping, Zhang Qitu, Chen Hao.   Preliminary study of 3D ball-milled powder processing and SPS-accelerated   densification of ZnSe ceramics [J]. Optical Materials Express, 2017, 7(4):   1131-1140.

16.Wei Shuai, Zhang   Le, Ben Yue, Zhou Tianyuan, Li Zheng, Yang Hao, Selim Farida A., Wong   Chingping, Chen Hao. High dispersibility of α-Al2O3 powders from   coprecipitation method by step-by-step horizontal ball-milling [J]. Journal   of Materials Science: Materials in Electronics, 2017, 28(21): 16254-16261.

17.Jiang Zhigang,   Zhang Le, Yao Qing, Wei Shuai, Zhou Tianyuan, Ben Yue, Sun Rong, Huang   Guocan, Chen Hao, Wang Yun. Agitator dependent homogeneity enhancement of   co-precipitation reaction for improving the dispersibility of precursors and   Y2O3 powders [J]. Ceramics International, 2017, 43(18): 16121-16127.

18.Ben Yue, Zhang Le,   Wei Shuai, Zhou Tianyuan, Li Zheng, Yang Hao, Wong Chingping, Chen Hao.   Improved forming performance of β-TCP powders by doping silica for 3D ceramic   printing [J]. Journal of Materials Science: Materials in Electronics, 2017,   28(7): 5391-5397.

19.Ben Yue, Zhang Le,   Wei Shuai, Zhou Tianyuan, Li Zheng, Yang Hao, Wang Yun, Selim Farida A., Wong   Chingping, Chen Hao. PVB modified spherical granules of β-TCP by spray drying   for 3D ceramic printing [J]. Journal of Alloys and   Compounds, 2017, 721: 312-319..

20.L. Wang, H. Huang,   D. Shen, J. Zhang, H. Chen, and D. Tang, “Diode-pumped high power 2.7μm   Er:Y2O3 ceramic laser at room temperature,” Opt. Mater. (Amst)., pp. 12–15,   2016.

21.W. Yao, F. Wu, Y.   Zhao, H. Chen, X. Xu, and D. Shen, “Highly efficient Tm:CaYAlO4 laser in-band   pumped by a Raman fiber laser at 1.7 μm,” Appl. Opt., vol. 55, no. 14, pp.   3730–3733, 2016.

22.J. Zhang, Q. Liu,   D. Shen, J. Zhang, D. Tang, and H. Chen, “Short pulse-width gain-switched   Ho:YAG ceramic laser at 2.09 μm,” Appl. Opt., vol. 55, no. 8, p.   1890, 2016.

23.J. Zhang, D. Shen,   X. Xu, and H. Chen, “Widely tunable, narrow line-width Ho : CaYAlO4 laser   with a volume Bragg grating,” vol. 6, no. 6, pp. 1768–1773, 2016.

24.J. Zhang, D. Shen,   J. Zhang, D. Tang, and H. Chen, “Gain-switched Ho:YAG ceramic laser with an   acousto-optic modulator,” Opt. Eng., vol. 55, no. 4, p. 46115, 2016.

25.W. Yao, B. Chen, J.   Zhang, Y. Zhao, H. Chen, and D. Shen, “High-average-power operation of a   pulsed Raman fiber amplifier at 1686 nm,” Opt. Express, vol. 23, no. 9, p.   11007, 2015.

26.L. Wang, H. Huang,   D. Shen, J. Zhang, H. Chen, Y. Wang, X. Liu, and D. Tang, “Room temperature   continuous-wave laser performance of LD pumped Er:Lu2O3 and Er:Y2O3 ceramic   at 27 μm,” Opt. Express, vol. 22, no. 16, p. 19495, 2014.

27.T. Zhao, Y. Wang,   H. Chen, and D. Shen, “Graphene passively Q-switched Ho:YAG ceramic laser,”   Appl. Phys. B Lasers Opt., vol. 116, no. 4, pp. 947–950, 2014.

28.T. Zhao, Y. Wang,   D. Shen, J. Zhang, D. Tang, and H. Chen, “Continuous-wave and Q-switched   operation of a resonantly pumped polycrystalline ceramic Ho:LuAG laser,” Opt.   Express, vol. 22, no. 16, p. 19014, 2014.

29.X. Qin, H. Yang, D.   Shen, H. Chen, G. Zhou, D. Luo, J. Zhang, S. Wang, J. Ma, and D. Tang,   “Fabrication and optical properties of highly transparent Er:YAG   polycrystalline ceramics for eye-safe solid-state lasers,” Int. J. Appl.   Ceram. Technol., vol. 10, no. 1, pp. 123–128, 2013.

30.Y. Wang, H. Chen,   D. Shen, J. Zhang, and D. Tang, “High power continuous-wave and graphene   Q-switched operation of Er:YAG ceramic lasers at ~1.6 μm,” J. Opt. Soc.   Korea, vol. 17, no. 1, pp. 5–9, 2013.

31.H. Yang, J. Zhang,   D. Luo, H. Lin, H. Chen, D. Shen, and D. Tang, “Optical properties and laser   performance of Ho:LuAG ceramics,” Phys. Status Solidi, vol. 10, no. 6, pp.   903–906, 2013.

32.H. Chen, D. Y.   Shen, X. D. Xu, T. Zhao, X. F. Yang, D. H. Zhou, and J. Xu, “High-power   2.1 μm Ho: Lu1.5Y1.5Al5O12 laser in-band pumped by a Tm fiber laser,” Laser   Phys. Lett., vol. 9, no. 1, pp. 26–29, 2012.

33.H. Yang, J. Zhang,   X. Qin, D. Luo, J. Ma, D. Tang, H. Chen, D. Shen, and Q. Zhang,   “Polycrystalline Ho:YAG transparent ceramics for eye-safe solid state laser   applications,” J. Am. Ceram. Soc., vol. 95, no. 1, pp. 52–55, 2012.

34.H. Chen, D. Shen,   J. Zhang, H. Yang, D. Tang, T. Zhao, and X. Yang, “In-band pumped highly   efficient Ho:YAG ceramic laser with 21 W output power at 2097 nm.,” Opt.   Lett., vol. 36, no. 9, pp. 1575–7, May 2011.

35.D. Shen, H. Chen,   X. Qin, J. Zhang, D. Tang, X. Yang, and T. Zhao, “Polycrystalline ceramic Er:YAG   laser in-band pumped by a high-power Er,Yb fiber laser at 1532nm,” Appl.   Phys. Express, vol. 4, no. 5, 2011.

36.F. Wang, D. Shen,   H. Chen, D. Fan, and Q. Lu, “Modeling and optimization of stable   gain-switched Tm-doped fiber lasers,” Opt. Rev., vol. 18, no. 4, pp. 360–364,   2011.

37.Y. Wang, D. Shen,   H. Chen, J. Zhang, X. Qin, D. Tang, X. Yang, and T. Zhao, “Highly efficient   Tm:YAG ceramic laser resonantly pumped at 1617 nm.,” Opt. Lett., vol. 36, no.   23, pp. 4485–7, 2011.

38.D. Shen, H. Chen,   and F. Wang, “Wavelength control and spectral narrowing of high power fiber   lasers using volume Bragg gratings,” 9th Int. Conf. Opt. Commun. Networks   (ICOCN2010)Nanjing, China, 24-27, October, 2010, pp. 318–320, 2010.

39.E. Wu, H. Chen, Z.   Sun, and H. Zeng, “A novel broadband saturable absorber in the near infrared   spectral region with cobalt-doped tellurite glasses,” vol. 341, no. 1995, p.   2600, 2006.

40.H. Chen, E. Wu, and   H. Zeng, “Comparison between a-cut and off-axially cut Nd:YVO4 lasers   passively Q-switched with a Cr4+:YAG crystal,” Opt. Commun., vol. 230, no.   1–3, pp. 175–180, 2004.

41.E. Wu, H. Chen, Z.   Sun, and H. Zeng, “Broadband saturable absorber with cobalt-doped tellurite   glasses.,” Opt. Lett., vol. 28, no. 18, pp. 1692–1694, 2003.

专利:

1.波长连续可调谐激光装置       CN201410018814    2014.01.15

2.高功率窄线宽可调谐激光器    CN201410018597    2014.01.15

3.一种使用二次曲面镜的高功率窄线宽可调谐激光器    CN201410017838        2014.01.15

4.一种基于激光介质中心零增益结构的涡旋激光器       CN201510596176        2015.09.17

5.用于提升~1.5μm激光效率的Er,Yb共掺光纤     CN201510592197    2015.09.17

6.一种氧化钇基透明陶瓷的制备方法       CN201510982574    2015.12.23

7.Y2O3基透明陶瓷粉体的喷射共沉淀制备方法     CN201510993485    2015.12.25

8.一种He-Ne精校准方法   CN201510986253  2016.04.29

9.一种透明陶瓷荧光管内壁封装蓝光芯片的白光LED光源  CN201610128380      2016.03.07

10.一种磁光氧化铽透明陶瓷的制备方法    CN201610104880    2016.02.25

11.一种基于透明陶瓷荧光管的高功率白光LED光源      CN201610128427        2016.03.07

12.一种喷枪喷涂制备YAG基复合结构透明陶瓷的方法  CN201610219256      2016.04.08

13.一种基于透明陶瓷荧光体的直管型白光LED光源      CN201620173151        2016.03.07

14.成像用双波段发光Nd:Y2O3纳米荧光粉体及其制备方法  CN201610824631      2016.09.14

15.一种基于远程激发技术的大功率白光LED路灯光源  CN201610939107      2016.10.25

16.一种基于荧光透明陶瓷材料的LED远程发光器件      CN201610952808        2016.10.25

17.一种白光LED用复合钙钛矿红色荧光粉及其制备方法      CN201611128472        2016.12.09

18.一种白光LED用三方双钙钛矿红色荧光粉及其制备方法  CN201611128190        2016.12.09

19.一种超薄透明陶瓷流延素坯的烧结防变形方法    CN201611128298  2016.12.09

20.喷射共沉淀制备高分散性纳米氧化物粉体的连续方法       CN201710098090      2017.02.22

21.一种高导热低膨胀W Cu封装材料的制备方法    CN201710229045    2017.04.10

22.一种快速低耗高效制备YAG粉体的方法     CN201710274664    2017.04.25

23.一种提高化学沉淀法制备氧化物粉体分散性的方法    CN201710280364      2017.04.25

24.一种Li+共掺提高硅酸盐荧光粉长余辉特性的方法     CN201710231586        2017.04.10

25.一种Mg助剂体系YAG基透明陶瓷的制备方法  CN201710428544  2017.06.08

26.一种氧化钇纳米粉体及纳米结构的制备方法       CN201710059321    2017.01.24

27.一种Ca助剂体系YAG基透明陶瓷的制备方法   CN201710427573  2017.06.08

28.一种非硅助剂下真空烧结YAG基透明陶瓷的制备方法     CN201710803357        2017.09.08

29.一种用四斜叶搅拌器共沉淀制备氧化钇纳米晶粉体的方法      CN201710727344  2017.08.22

获奖情况:

1.2012年,徐州市科技进步奖二等奖(排名第2

2.2012年,淮海科技进步奖二等奖(排名第2

3.2014年,中国精品科技期刊顶尖学术论文领跑者5000(排名第1

4.2015年,江苏省科学技术奖(排名第2

5.2015年,江苏省研究生培养模式改革成果奖(排名第2

6.2015年,校先进工作者

7.2015年,校2013-2015年岗位聘期考核优秀

8.2017年,“挑战杯”全国竞赛江苏省选拔赛三等奖指导教师