南京大学现代工程与应用科学学院导师教师师资介绍简介-姜校顺

删除或更新信息，请邮件至freekaoyan#163.com(#换成@)

本站小编 Free考研考试/2021-02-16

闂傚倷鑳剁划顖炲礉濡ゅ懎绠犻柟鎹愵嚙閸氳銇勯弬鍨挃闁告宀搁幃妤呮晲鎼存繄鐩庣紓浣风贰閸ｏ綁寮婚悢鐓庣闁兼祴鏅濋悡鍌炴⒑缁嬭法鐒块柟鍑ゆ嫹2婵犵數鍋為崹鍫曞箰缁嬫５娲Ω閳哄绋忛梺鍦劋椤ㄥ棝宕甸埀顒勬⒑閸涘﹤濮﹀ù婊呭仱瀹曟椽鏁撻悩宕囧幗闂侀潧绻堥崐鏍р槈瑜旈弻锝夊焺閸愵亝鍣伴梺璇″暙閸パ囧敹闂佹寧绻傚ú銏ゅ磻閹烘鈷戦柛婵嗗閳ь剙缍婇幃閿嬫綇閳哄偆娼熼梺璺ㄥ櫐閹凤拷
婵犵數濮伴崹褰掓偉閵忋倕鐐婄憸宥嗘叏閵堝鈷戦柛娑橈工缁楁帗淇婇锝囨创妞ゃ垺妫冩慨鈧柕鍫濇－濡嫰鏌ｆ惔顖滅У闁哥姵鐗犲畷銏ゅ箻椤旂晫鍘搁梺鍛婃礋濞佳囨倶閿濆棎浜滈柟瀛樼箖婢跺嫮绱掔€ｎ亶妯€闁糕斁鍋撳銈嗗坊閸嬫捇鏌嶇拠鏌ュ弰婵￠箖浜堕弻宥堫檨闁告挻鐟╁畷顖涘鐎涙ê浜┑鐐叉▕娴滄繈寮查鍕€堕柣鎰暩閹藉倿鏌涢妶鍥㈤棁澶嬬節婵犲倸鏆ｆい搴㈩殕閵囧嫰鍩為鐐差仾濠殿垱鎸抽弻锟犲炊閳轰焦鐏侀梺鍛婄憿閸嬫捇姊绘担鍝ョШ婵炰匠鍡愪汗闁绘劗鏁哥粻鏃堟煙閹屽殶闁崇粯姊归幈銊ノ熺拠鎻掝潽闂佹悶鍊х粻鎾诲蓟閻旇櫣鐭欓柟绋垮閹瑩姊烘导娆戠М缂佺姵鐗曢锝夘敃閳垛晜鐎婚梺褰掑亰閸樺墽绮欓崟顖涒拺闁圭ǹ娴烽埥澶愭煛閸偄澧寸€规洖缍婃俊姝岊槼濠殿垰銈搁弻娑樷槈濮楀牊鏁剧紓浣哄У鐢偤鍩€椤掆偓閻忔艾顭垮鈧幃褔宕卞ù鏉挎喘瀹曠ǹ螖娴ｉ晲鐥梻浣侯攰閹活亪姊介崟顖涙櫖闁哄稁鍘介悡蹇涙煕閳╁啯绀€妞わ絺鏆渆e婵犵數濮伴崹鍦礊婵犲洤鐒垫い鎺嶈兌閳洟鏌曢崱妤€鏆ｉ柡灞剧洴楠炴帡骞嬮悜鍡橆棧婵＄偑鍊栫敮鐐哄窗閹邦喚鐭欏┑鐘叉处閸嬫劙鏌ｉ姀銏℃毄閺佸牓姊绘担绋挎倯婵犮垺锕㈠畷顖涘鐎涙ê浜梺鍛婄箓婵鲸鎯旈姀锛勭Ф濡炪倖鍔楅崰搴㈢妤ｅ啯鐓涢柛銉ｅ妽閻ㄦ垿鏌ｉ悢鍙夋珔闁宠棄顦甸獮妯肩礄閻樺崬顒㈡俊鐐€栧ú婵嗏枍閺囩偍缂氶煫鍥ㄧ☉瀹告繃銇勯幘妤€鍟锟�20濠德板€楁慨鐑藉磻閻樿绠垫い蹇撴椤洘绻濋棃娑卞剰缂佺姵鍨块弻銈嗘叏閹邦兘鍋撳Δ鈧埢鏃堝閻樺棛鎳撻オ浼村礃閳哄﹥锛呯紓鍌欑椤︻垶顢氶銏犵劦妞ゆ巻鍋撴繝鈧柆宥呯；闁绘梻鍘ч弸渚€鏌曢崼婵愭Ч闁稿骸绉归弻娑㈠即閵娿儱顫╅梺浼欑畱缂嶅﹪骞冨Δ鍐╁枂闁告洦鍙庨弳锟犳⒑閸濆嫭顥戦柛瀣崌濮婃椽宕崟鍨ч梺鍛婃⒐閻楃娀骞冮敓鐘虫櫖闁告洦鍓欓悵浼存⒑闂堟稓绠氶柛鎾寸箞閹€斥枎閹邦喚顔曟繝銏ｆ硾椤戝棛绮堥埀顒勬倵濞堝灝娅嶉柡鈧崡鐑嗗殫闁告洦鍋掗崥瀣煕閺囥劌骞樻俊鍙夊灴濮婃椽宕崟顐熷亾娴犲缍栧璺烘湰閸忔粓鏌涢锝嗙闁哄拋鍓熼幃姗€鎮欓棃娑楀缂備胶濮电敮鈥愁潖婵犳艾鐐婇柨婵嗘噸婢规洟姊洪懡銈呮瀾婵炲弶鍨块幊妤冩崉鐞涒剝鐏侀梺纭呮彧闂勫嫰宕曢幋锔藉€甸柨婵嗛楠炴ḿ绱掗悩宕囧⒌闁哄备鍓濆鍕槈濞嗗浚浼�

姜校顺

教授

Email： jxs@nju.edu.cn

个人主页：http://optics.nju.edu.cn/memberdetail.aspx?i=5
实验室主页： http://optics.nju.edu.cn/

研究方向：

片上高品质因子光学微腔及应用/集成光子学/非线性光学/腔光力学/纳米加工
开设课程：
《微纳光子学》，《光学专业基础实验》

个人简介：

2010年获浙江大学博士学位，2007-2009年在美国加州理工学院进行博士联合培养。主要从事片上高品质因子光学微腔的制备及其在集成光子学器件、光力学、宇称-时间对称光子学、非线性光学等方面的应用研究。2014年获得浙江省自然科学一等奖（排名第三）。2015年获得江苏省****基金支持。2017年入选南京大学“登峰人才支持计划”B 层次。已在Nat. Photon.、Nat. Commun.、Phys. Rev. Lett.、Appl. Phys. Lett.、Opt. Express.、Opt. Lett.等国际学术期刊上发表学术论文30余篇，被引用1300余次（Google Scholar）。

科研成果
代表性论文：
[1] S. Hua, J. Wen, X. Jiang*,Q. Hua, L. Jiang, and M. Xiao, “Demonstration of a Chip-based Optical Isolator with Parametric Amplification,” Nature Communications 7, 13657 (2016).
[2] L. Chang, X. Jiang*, S. Hua, C. Yang, J. Wen, L. Jiang, G. Li, G. Wang and M. Xiao, “Parity-time symmetry and variable optical isolation in active-passive-coupled microresonators,” Nature Photonics 8524 (2014).
[3] C. Yang, X. Jiang*, Q. Hua, S. Hua, Y. Chen, J. Ma, and M. Xiao, “Realization of controllable photonic molecule based on three ultrahigh-Q microtoroid cavities,” Laser Photonics Rev. 11, ** (2017). (Front Cover)
[4] C. Yang,Y. Hu, X. Jiang*, and M. Xiao, “Analysis of a triple-cavity photonic molecule based on coupled-mode theory,” Phys. Rev. A 95, 033847 (2017).
[5] G. Wang, M. Zhao, Y. Qin, Z. Yin, X. Jiang*, and M. Xiao, “Demonstration of an ultra-low-threshold phonon laser with coupled microtoroid resonators in vacuum,” Photon. Res. 5, 73 (2017). (Cover)
[6] G. Li, X. Jiang*, S. Hua, Y. Qin, and M. Xiao, “Optomechanically tuned electromagnetically induced transparency-like effect in coupled optical microcavities,” Appl. Phys. Lett. 109, 261106 (2016).
[7] X. Jiang*, C. Yang, H. Wu, S. Hua, L. Chang, Y. Ding, Q. Hua, and M. Xiao, “On-chip optical nonreciprocity using an active microcavity,” Sci. Rep. 6, 38972 (2016).
[8] G. Li, P. Liu, X. Jiang*, C. Yang, J. Ma, H. Wu, and M. Xiao, “High-Q silica microdisk optical resonators with large wedge angles on a silicon chip,” Photon. Res. 3, 279 (2015).
[9] H. Fan, X. Jiang*, Y. Ding, and M. Xiao, “Demonstration of ultralow-threshold 2 micrometer microlasers on chip,” Sci. China-Phys. Mech. Astron. 58, 114204 (2015). (Special Issue on Microcavity Photonics). (Cover)
[10]B. Zheng, M. Zhao, Q. Guo, Y. Yu, S. Lu, X. Jiang*, and S. Zhou, “A chip-based microcavity derived from multi-component tellurite glass,” J. Mater. Chem. C3, 5141 (2015).
[11]G. Wang, M. Zhao, J. Ma, G. Li, Y. Chen, X. Jiang*, M. Xiao, “Radiation-pressure-driven mechanical oscillations in silica microdisk resonators on chip,” Sci. China-Phys. Mech. Astron. 58, 050307 (2015). (Special Issue on Optomechanics).
[12]H. Fan, S. Hua, X. Jiang*, and Min Xiao, “Demonstration of an erbium-doped microsphere laser on a silicon chip,” Laser Phys. Lett. 10, 105809 (2013).
[13]G. Wang, X. Jiang*, M. Zhao, Y. Ma, H. Fan, Q. Yang, L. Tong, and M. Xiao, “Microlaser based on a hybrid structure of a semiconductor and a silica microdisk cavity,” Opt. Express 20, 29472 (2012).
[14]C. Zheng, X. Jiang*, S. Hua, L. Chang, G. Li, H. Fan, and M. Xiao, “Controllable optical analog to electromagnetically induced transparency in coupled high-Q microtoroid cavities,” Opt. Express 20, 18319 (2012).
[15]X. Jiang, Q. Lin, J. Rosenberg, K. J. Vahala, and O. Painter, “High-Q double-disk microcavities for cavity optomechanics,” Opt. Express 17, 20911(2009).
[16]Q. Lin, J. Rosenberg, X. Jiang, K. J. Vahala, and O. Painter, “Mechanical osciallation and cooling actuated by the optical gradient force,” Phys. Rev. Lett. 103, 103601 (2009).
[17]X. Jiang, Y. Chen, G. Vienne, and L. Tong, “All-fiber add-drop filters based on microfiber knot resonators,” Opt. Lett.32, 1710 (2007).
[18]X. Jiang, Q. Song, L. Xu, J. Fu, and L. Tong, “Microfiber knot dye laser based on the evanescent-wave-coupled gain,” Appl. Phys. Lett.90, 233501 (2007).
[19]X. Jiang, Q. Yang, G. Vienne, Y. Li, L. Tong, J. Zhang, L. Hu, “Demonstration of microfiber knot laser,” Appl. Phys. Lett. 89, 143513 (2006).
[20]X. Jiang, L. Tong, G. Vienne, X. Guo, Q. Yang, A. Tsao, and D. Yang, “Demonstration of optical microfiber knot resonators,” Appl. Phys. Lett. 88, 223501 (2006).