缃戠珯棣栭〉
闄㈢郴淇℃伅
璐拱鎸囧崡
鑰冪爺鍟嗗煄鍞竴鏉冨▉鐨勬箹鍗椾綋褰╃綉绔欎负澶у鎻愪緵锛婀栧崡浣撳僵缃戝ぇ瀛﹁倴鏉版暀鎺锛屾湰绔欑敱婀栧崡浣撳僵缃戝ぇ瀛︾爺绌剁敓鍒涘姙锛屾洿澶氳嫃澶ц冪爺璧勮璇峰叧娉ㄦ垜浠綉绔欑殑鏇存柊锛佹暚璇锋敹钘忔湰绔欍
add 鑻忓ぇ鐮旂┒鐢熷井淇
涓轰綘鍏嶈垂绛旂枒
鍏嶈垂棰嗙湡棰橈紝鎵捐緟瀵
婀栧崡浣撳僵缃戝ぇ瀛﹁倴鏉版暀鎺堬紝鐢凤紝鐜颁换婀栧崡浣撳僵缃戝ぇ瀛﹀寲瀛﹀伐绋嬩笌宸ヨ壓鐮旂┒鎵鏁欐巿锛屽崥澹敓瀵煎笀銆涓轰綘鍏嶈垂绛旂枒
鍏嶈垂棰嗙湡棰橈紝鎵捐緟瀵
2001骞6鏈堟瘯涓氫簬娴欐睙澶у鎺у埗绉戝涓庡伐绋嬪绯伙紝鑾峰緱宸ヤ笟鑷姩鍖栦笓涓氬澹浣嶃2004骞3鏈堜簬娴欏ぇ鑾峰緱鎺у埗绉戝涓庡伐绋嬪纭曞+瀛︿綅銆傚悓骞磋荡缇庯紝鍦ㄩ煢鎭╁窞绔嬪ぇ瀛﹀垎鍒簬2006骞8鏈堬紝2009骞5鏈堬紝鍜2010骞5鏈堣幏寰楀寲宸ョ澹紝鏉愭枡瀛︾澹紝鍜屽寲宸ュ崥澹浣嶃 2010骞3鏈堣嚦2012骞3鏈堬紝鍦ㄥ崕鐩涢】宸炵珛澶у搴旂敤绉戝瀹為獙瀹や粠浜嬪崥澹悗鐮旂┒銆 2012骞4鏈堣捣浠绘箹鍗椾綋褰╃綉澶у鏉愬寲閮ㄧ壒鑱樻暀鎺堛傛浘浣滀负鐮旂┒楠ㄥ共锛屾垚鍔熷畬鎴愪簡澶氶」鐢辩編鍥藉浗瀹惰嚜鐒剁瀛﹀熀閲戯紙NSF锛夛紝缇庡浗鍥藉鐜淇濇姢灞锛圗PA锛夛紝缇庡浗闄嗗啗鐮旂┒瀹為獙瀹わ紙ARL锛夛紝缇庡浗閫氱敤姹借溅鍏徃锛圙M锛夛紝绂忕壒姹借溅鍏徃锛團ord锛夛紝鏉滈偊鍏徃锛圖uPont锛夛紝娉㈤煶鍏徃锛圔oeing锛夎祫鍔╃殑椤圭洰銆傚湪鍖栧伐椤剁骇鏉傚織锛圓IChE J., Chem. Eng. Sci., Ind. Eng. Chem. Res.绛夛級涓婂彂琛ㄤ簡20澶氱瘒瀛︽湳璁烘枃锛 鍙楅個涓绘寔杩囩編鍥藉寲瀛﹀伐绋嬪笀鍗忎細骞翠細(AIChE Annual Meeting)鐨勪袱涓垎浼氾紝骞跺湪澶氫釜鍥介檯浼氳涓仛杩30浣欏満鎶ュ憡锛屽彂琛8绡囦細璁鏂囥傛浘鑾峰緱缇庡浗鍥藉琛ㄩ潰娑傚眰鍗忎細鐨勫瀛﹂噾锛屼互鍙婄編鍥藉寲瀛﹀伐绋嬪笀鍗忎細杩囩▼寮鍙戝垎閮紙AIChE Process Development Division锛夌殑鏈浣宠鏂囧銆 鍙楅個璇勫Elsevier Ltd.鍑虹増鐨勪笓钁楋紝骞舵媴浠籄IChE J., Comput. Chem. Eng., I&EC Research绛変富瑕佸寲宸ユ湡鍒婄殑瀹$ǹ浜恒傚簲閭鍙傚姞浜員au Beta Pi鍜孲igma Xi绉戝鑽h獕瀛︿細锛岀幇涓虹編鍥紸IChE, ACS, TMS, AESF绛夊浼氱殑浼氬憳銆
鐮旂┒鏂瑰悜
搴旂敤
· 宸ヤ笟鐢熶骇杩囩▼鐨勫彲鎸佺画鍙戝睍
· 澶氬姛鑳界撼绫虫秱灞傝璁
· 鐢靛寲瀛﹁兘婧愮郴缁熻璁
鐞嗚
· 澶氬昂搴﹀鏉傜郴缁熺悊璁
· 澶氬姛鑳芥潗鏂欑殑澶氬昂搴﹁璁′笌鍒堕犳柟娉
涓昏璁烘枃
1.XiaoJ, Chaudhuri S. Design of Anti-Icing Coatings Using Supercooled Droplets as Nano-to-Micoscale Probes.Langmuir.2012; 28: 4434-4446.
2.Xiao J, Chaudhuri S. Predictive modeling of localized corrosion: An application to aluminum alloys.Electrochimica Acta.2011; 56: 5630-5641.
3.Xiao J, Huang YL, Manke C. Design of sustainable multifunctional nanocoatings: A goal-driven multiscale systems approach.Chinese Journal of Chemical Engineering.2011; 19: 666-673.
4.Xiao J, Huang YL, Manke C. Computational design of thermoset nanocomposite coatings: Methodological study on coating development and testing.Chem. Eng. Sci.2010; 65: 753-771.
5.Xiao J,Huang YL, Manke C. Computational design of polymer nanocomposite coatings: A multiscale hierarchical approach for barrier property prediction.Ind. Eng. Chem. Res.2010; 49: 7718-7727.
6.Xiao J,Huang YL. Microstructure-property-quality-correlated paint design: an LMC-based approach.AIChE J.2009; 55: 132-149.
7.Xiao J, Huang YL. Computational design of nanopaint: An integrated, multiscale process and product modeling and simulation approach. Chapter 87, in: El-Halwagi M, Linninger A.Design for Energy and the Environment.NW: Taylor & Francis Group, 2009: 897-905.
8.Xiao J, Li J, Piluso C, Huang YL. Multiscale characterization of automotive surface coating formation for sustainable manufacturing.Chinese Journal of Chemical Engineering.2008; 16: 416-423.
9.Xiao J, Huang YL, Lou HH. A probability distribution estimation based method for dynamic optimization.AIChE J.2007; 53: 1805-1816.
10.Xiao J, Huang YL, Qian Y, Lou HH. Integrated product and process control of single-input-single-output systems.AIChE J.2007; 53: 891-901.
11.XiaoJ, Li J, Lou HH, Xu Q, Huang YL. ACS-based dynamic optimization for curing of polymeric coating.AIChE J.2006; 52: 1410-1422.
12.Xiao J, Li J, Lou HH, Huang YL. Cure-window-based proactive quality control in topcoat curing.Ind. Eng. Chem. Res.2006; 45: 2351-2360.
婀栧崡浣撳僵缃戝ぇ瀛
鎺ㄨ崘闃呰锛
鎹笓涓氳冩箹鍗椾綋褰╃綉澶у鐮旂┒鐢熼毦涓嶉毦锛
婀栧崡浣撳僵缃戝ぇ瀛﹁冪爺涔嬬鐞嗗鎬庝箞澶嶄範
婀栧崡浣撳僵缃戝ぇ瀛︽帓鍚2010骞
婀栧崡浣撳僵缃戝ぇ瀛﹁冪爺鎬庢牱鎵嶈兘鍑忓皯澶辫触椋庨櫓锛
鑻忓ぇ鐮旂┒鐢熷ソ鑰冨悧锛
鑰冩箹鍗椾綋褰╃綉澶у鐨勮祫鏂欎功搴旇濡備綍閫夎喘
婀栧崡浣撳僵缃戝ぇ瀛﹁冪爺鏁板鍐插埡瑕佺偣
婀栧崡浣撳僵缃戝ぇ瀛︽庝箞鏍
婀栧崡浣撳僵缃戝ぇ瀛︾嫭澧呮箹鏍″尯缃戝潃
婀栧崡浣撳僵缃戝ぇ瀛 鐮旂┒鐢熶笓涓
婀栧崡浣撳僵缃戝ぇ瀛﹁倴鏉版暀鎺