尉志武 (YU, Zhiwu)
博士,教授,博导
(Ph.D., Professor of Chemistry)
Tel. (0) 10-62792492
Fax. (0) 10-62771149
Email: yuzhw@tsinghua.edu.cn
学历教育及博士后经历:
学士学位(BSc): 清华大学化学与化学工程系(1979-84);
硕士学位(MSc): 清华大学化学系(1984-87);
博士学位(PhD): 伦敦大学(英国)(King’s College London,1992-95);
博士后(Postdoc): 伊利诺伊大学(美国)(香槟分校 UIUC, 1996-98)
主要学术与社会兼职:
中国化学会化学热力学与热分析专业委员会副主任;
物理化学学报,编委会委员
Biomedical Spectroscopy and Imaging, Regional Editor for Asia.
主要研究兴趣与工作内容:
研究工作主要分为以下几个方面:(一)光谱方法学及其应用:致力于建立和完善分子间相互作用的研究方法,包括超额光谱法、二维相关光谱法、Benesi-Hildebrand法;研究内容包括氢键、卤键的性质,分子识别和分子间选择性相互作用;研究对象涉及生物大分子、离子液体等绿色溶剂和有机小分子。(二)生物物理化学:研究内容包括生物膜相变与稳定性、蛋白质变性、膜与磷脂相互作用、细胞及模型膜的显微方法;研究对象涉及磷脂、糖脂、固醇、蛋白质、核酸;在方法学方面提出了一种鉴别蛋白质变性二态性的“中止-恒温”法。(三)分子自组装:研究内容包括双亲分子自组装体和葫芦脲与小分子配体的组装,提出了双亲分子自组装体相变过程中头、尾部和界面区域可以不协同的思想,在LB膜研究中提出了超额面积的概念,近期关注同步辐射小角散射(SAXS)数据的深度解析。(四)溶液化学与热化学:研究内容包括溶液结构、超额焓、超额体积和分子的溶剂化作用等,对Flory理论进行改进,提出了双参数法。
(一) 光谱方法学及其应用
1. Generalized excess spectroscopy, J. Phys. Chem. A 126: 1775− 1781 (2022) (Wang YQ and Yu ZW*)
2. Excess Spectroscopy and Its Applications in the Study of Solution Chemistry, Pure Appl. Chem. 92(10): 1611-1626 (2020) (Zhang YQ, Wu ZW, Wang YQ, He HY*, and Yu ZW*)
3. Local Acid Strength of Solutions and Its Quantitative Evaluation Using Excess Infrared Nitrile Probes, J. Phys. Chem. Lett. 11: 1007−1012 (2020) (Xu J, Deng G, Wang YT, Guo HY, Kalhor P, and Yu ZW*)
4. Hydroxyl Group as IR Probe to Detect the Structure of Ionic Liquid-Acetonitrile Mixtures, J. Mol. Struct. 1161: 424-432 (2018) (Xu J, Deng G, Zhou Y, Ashraf H, and Yu ZW*)
5. Evidence to Show that Acetonitrile is Sensitive to Different Interactions Sites of Ionic Liquids as Unveiled by Excess Spectroscopy, ChemPhysChem. 18(10): 1370-1375 (2017) (Zhou Y, Zheng YZ, Zhang T, Deng G, and Yu ZW*)
6. 超额光谱及其研究进展,物理化学学报,32(1): 239–248 (2016). (周瑜, 徐静, 王楠楠,尉志武*)
7. Two-State or Non-two States? An Excess Spectroscopy-based Approach to Differentiate the Existing Forms of Molecules in Liquids Mixtures, Scientific Reports. 5, 16379 (2015). (Zhou Y, Zheng YZ, Sun HY, Deng G, and Yu ZW*)
8. A Comparative Study of Halogen-bond and Hydrogen-bond Interactions between Benzene Derivatives and and Dimethyl Sulphoxide, ChemPhysChem 16 (12): 2594-2601 (2015). (Zheng YZ, Deng G, Zhou Y, Sun HY, and Yu ZW*)
9. Hydrogen Bonding Interactions in Ethanol and Acetonitrile Binary System: A Near and Mid-Infrared Spectroscopic Study, J. Mol. Struct.. 1069, 251–257 (2014) (Zhou Y, Zheng YZ, Sun HY, Deng G, and Yu ZW*)
10. Hydrogen-bonding Interactions Between [BMIM][BF4] and Dimethyl Sulfoxide, J. Mol. Struct. 1069, 140–146 (2014) (Zheng YZ, He HY, Zhou Y, and Yu ZW*)
11. Halogen-bond and Hydrogen-bond Interactions between Three Benzene Derivatives and Dimethyl Sulphoxide, Phys. Chem. Chem. Phys. 16 (15): 6946-56 (2014) (Zheng YZ, Wang NN, Zhou Y, and Yu ZW*)
12. Hydrogen- bonding Interactions Between [BMIM][BF4] and Acetonitrile, Phys. Chem. Chem. Phys. 15(41): 18055 -18064 (2013). (Zheng YZ, Wang NN, Luo JJ, Wu FG, Zhou Y, and Yu ZW*)
13. The Hydrogen-Bonding Interactions between 1-Ethyl-3-Methylimidazolium Lactate Ionic Liquid and Methanol, Australian Journal of Chemistry, 66(1):50−59 (2013). (He HY, Chen H, Zheng YZ, Zhang XC, Yao XQ, Yu ZW, Zhang SJ*)
14. Hydrogen Bonding Behaviors of Binary Systems Containing the Ionic Liquid 1-Butyl-3-Methylimidazolium Trifluoroacetate and Water/Methanol, J. Phys. Chem. B, 115(38):11127–11136 (2011). (Zhang QG, Wang NN, Wang SL, and Yu ZW*)
15. Hydrogen Bonding Interactions between a Representative Pyridinium-Based Ionic Liquid [BuPy][BF4] and Water/Dimethyl Sulfoxide, J. Phys. Chem. B, 114(26):8689–8700 (2010). (Wang NN, Zhang QG, Wu FG, Li QZ, and Yu ZW*)
16. Hydrogen Bonding Interactions between the Ionic Liquid 1-Ethyl-3-Methylimidazolium Ethyl Sulfate and Water, J. Phys. Chem. B, 114(14): 4747-4754 (2010). (Zhang QG, Wang NN, and Yu ZW*)
17. Generalized 2D and Time-resolved FTIR Studies of Protein Unfolding Events, J. Mol. Struct., 974(14): 203–209 (2010). (Fabian H*, Yu ZW, Wang YW, and Naumann D)
18. An Insight into the Sequential Order in Two-dimensional Correlation Spectroscopy, Applied Spectroscopy, 63(3): 344-353 (2009). (Jia Q, Wang NN, and Yu ZW*)
19. Hydrogen Bonding Interactions in Three 2-Mercaptoethanol Systems: an Excess Infrared Spectroscopic Study, Applied Spectroscopy, 63(12): 1356–1362 (2009) (Wang NN, Li QZ, and Yu ZW*)
20. Selective Molecular Interactions between Dimethyl Sulfoxide and the Functional Groups of 2-Mercaptoethanol, J. Mol. Struct., 883-884: 55-60 (2008) (Wang NN, Jia Q, Li QZ, and Yu ZW*)
21. A Novel Normalization Method Based on Principal Component Analysis to Reduce the Effect of Peak Overlaps in Two-Dimensional Correlation Spectroscopy, J. Mol. Struct., 883-884: 66-72 (2008) (Wang YW, Gao WY, Wang XG, and Yu ZW*)
22. Point-Point and Point-Line Moving-window Correlation Spectroscopy and Its Applications, J. Mol. Struct., 883-884: 109-115 (2008) (Zhou Q*, Sun SQ, Zhan DQ, and Yu ZW*)
23. Excess Infrared Absorption Spectroscopy and Its Applications in the Studies of Hydrogen Bonds in Alcohol-Containing Binary Mixtures, Applied Spectroscopy, 62(2), 166-170 (2008) (Li QZ, Wang NN, Zhou Q, Sun SQ, and Yu ZW*)
24. Molecular Interactions between Pyrazine and n-Propanol, Chloroform, or Tetrahydrofuran, Spectrochimica Acta Part A, 70(4):793-798 (2008) (Wang R, Li QZ, Wu RG, Wu GS, and Yu ZW*)
25. The Validity and Reliability of Benesi-Hildebrand Method, Acta Phys. Chim. Sin., 23(9), 1353-1359 (2007) (Wang R and Yu ZW*)
26. The Role of Methyl Groups in the Formation of Hydrogen Bonds in DMSO-Methanol Mixtures, J. Am. Chem. Soc. 128 (5), 1438-1439(2006). (Li QZ, Wu GS, and Yu ZW*)
27. A Modified Mean Normalization Method to Reduce the Effect of Peak Overlap in Two-Dimensional Correlation Spectroscopy, J. Mol. Struct., 799 (1-3), 128-133 (2006) (Wang YW, Gao WY, Noda I, and Yu ZW*)
28. Overlap May Cause Misleading Results in Two-dimensional Correlation Spectra. Applied Spectroscopy, 59(3), 388-391 (2005) (Yu ZW*, Wang YW, and Liu J)
29. Selective Molecular Interactions between Dimethyl Sulfoxide and Paraldehyde Studied by Two-dimensional Correlation FT-IR spectroscopy. Vibrational Spectroscopy, 36(2): 203-206 (2004) (Liu J, Feng Y, Chen L, Wu GS, and Yu ZW*)
30. Effect of Noise on the Evaluation of Correlation Coefficients in Two-Dimensional Correlation Spectroscopy. Applied Spectroscopy, 57(12): 1605-1609 (2003) (Yu ZW* , Liu J, and Noda I)
31. On the Normalization Method in 2D-correlation Spectra when Concentration is Used as Perturbation Parameter. Applied Spectroscopy, 57(2): 164-167 (2003) (Yu ZW* and Noda I)
32. Determination of Selective Molecular Interactions Using Two Dimensional Correlation FTIR Spectroscopy. J. Phys. Chem. A, 106(30): 6683-6687 (2002) (Yu ZW*, Chen L, Sun SQ, and Noda I)
(二)生物物理化学
1. Cholesterol Protects the Liquid-ordered Phase of Raft Model Membranes from the Destructive Effect of Ionic Liquids, J. Phys. Chem. Lett. 13: 7386−7391 (2022) (Hao XL, Cao B, Dai D, Wu FG, and Yu ZW*)
2. The distinct effects of two imidazolium-based ionic liquids, [C4mim][OAc] and [C6mim][OAc], on the phase behaviour of DPPC, Phys. Chem. Chem. Phys. 23(33):17888 – 17893 (2021) (Hao XL, Guo HY, Cao BB, Mo G, Li ZH, and Yu ZW*)
3. Fabrication of Asymmetric Phosphatidylserine-Containing Lipid Vesicles, A Study on the Effects of Size, Temperature, and Lipid Composition, Langmuir, 36(42): 12684-12691(2020). (Guo HY, Sun HY, Deng G, Xu J, Wu FG, and Yu ZW*)
4. Enzyme-Mediated Tumor Starvation and Phototherapy Enhance Mild-Temperature Photothermal Therapy, Adv. Funct. Mater. 1909391 (2020) (Gao G, Jiang YW, Guo YX, Jia HR, Cheng XT, Deng Y, Yu XW, Zhu YX, Guo HY, Sun W, Liu XY, Zhao J, Yang SH, Yu ZW, Raya, FMS, Liang GL*, and Wu FG*)
5. Effect of Imidazolium-Based Ionic Liquids on the Structure and Phase Behavior of Palmitoyloleoylphosphatidylethanolamine, J. Phys. Chem. B, 123(26): 5474-5482 (2019) (Guo HY, Cao BB, Deng G, Hao XL, Wu FG, and Yu ZW*)
6. Plasma Membrane Activatable Polymeric Nanotheranostics with Self-Enhanced Light-Triggered Photosensitizer Cellular Influx for Photodynamic Cancer Therapy, Journal of Controlled Release, 255(15): 231-241 (2017) (Jia, HR, Jiang YW, Zhu YX, Li YH, Wang HY, Han XF, Yu ZW, Gu N, Liu PD, Chen Z, and Wu FG*)
7. Controllable Engineering of Asymmetric Phosphatidylserine-Containing Lipid Vesicles by Calcium Cations, Chemical Communications, 53: 12762-12765 (2017) (Sun HY, Deng G, Jiang YW, Zhou Y, Xu J, Wu FG*, and Yu ZW*)
8. Phase Behaviors of a Binary Lipid System Containing Long- and Short-Chain Phosphatidylcholines, RSC Advances, 7(10): 5715–5724 (2017) (Sun HY, Wu FG, Li ZH, Deng G, Zhou Y, and Yu ZW*)
9. Evidences for Cooperative Resonance-Assisted Hydrogen Bonds in Protein Secondary Structure Analogs, Scientific Reports. 6, 36932 (2016) (Zhou Y, Deng G, Zheng YZ, Xu J, Ashraf H, and Yu ZW*)
10. Structural Properties of Paeonol Encapsulated Liposomes at Physiological Temperature: Synchrotron Small-Angle and Wide-Angle X-ray Diffraction Studies, Biomedical Spectroscopy and Imaging, 5(S1): S45–S54(2016) (Wu RG, Sun HY, Zhao BS, Deng G, and Yu ZW*)
11. In-Situ Visualization of Lipid Raft Domains by Fluorescent Glycol Chitosan Derivatives, Langmuir, 32(26): 6739–6745 (2016). (Jiang YW, Guo HY, Chen Z, Yu ZW, Wang ZF, and Wu FG*)
12. 差示扫描微量热法研究蛋白质及其相关体系进展,科学通报,61(28-29): 3091–3099 (2016). (孙海源,邓耿,周瑜,尉志武*)
13. Folding Behaviors of Protein (Lysozyme) Confined in Polyelectrolyte Complex Micelle, Langmuir, 32(15): 3655-3664 (2016). (Wu FG*, Jiang YW, Chen Z, and Yu ZW*)
14. Long-Time Plasma Membrane Imaging Based on a Two-Step Synergistic Cell Surface Modification Strategy, Bioconjugate Chem. 27(3): 782-789 (2016). (Ji HR, Wang HY, Yu ZW, Chen Z, and Wu FG*)
15. Molecular-Level Pictures of the Phase Transitions of Saturated and Unsaturated Phospholipid Binary Mixtures, RSC Advances, 5: 726–733 (2015). (Wu FG, Sun HY, Zhou Y, Deng G, and Yu ZW*)
16. Full Picture of the Thermotropic Phase Behavior of Cardiolipin Bilayer in Water: Identification of a Metastable Subgel Phase, RSC Advances, 4: 51171–51179 (2014). (Wu FG, Sun HY, Zhou Y, Wu RG, and Yu ZW*)
17. The Interaction of Human Synovial Phospholipase A2 with Mixed Lipid Bilayers: A Coarse-Grain and All-Atom Molecular Dynamics Simulation Study, Biochemistry, 52(8):1477−1489 (2013). (Qin SS, Yu YX, Li QK, Yu ZW*)
18. Experimental and Theoretical Investigations on the Direct Interactions between Urea and Phospholipids in Aqueous Solutions Biomedical Spectroscopy and Imaging, 2(3):141−153 (2013). (Ying Feng, Guo-Shi Wu, and Zhi-Wu Yu*)
19. Fibrillar Seeds Alleviate Amyloid-beta Cytotoxicity by Omitting Formation of Higher-Molecular-weight oligomers, Biochem. Biophys. Res. Comm., 439 (3): 321-326 (2013). (Wei-hui Wu, Qian Liu, Xun Sun, Ji-sheng Yu, De-sheng Zhao, Ye-ping Yu, Jun-jie Luo, Jia Hu, Zhi-wu Yu*, Yu-fen Zhao, Yan-Mei Li*)
20. In Situ Unfolded Lysozyme Induces the Lipid Lateral Redistribution of a Mixed Lipid Model Membrane, J. Phys. Chem. B, 116(41):12381−12388 (2012). (Luo JJ, Wu FG, Qin SS, and Yu ZW*)
21. Structural Properties of the Liquid Ordered Phase of Phosphatidylcholine/Stigmasterol Liposomes: a Synchrotron X-Ray Diffraction Study, Acta Phys. Chim. Sin, 28(8), 2008-2014 (2012). (Wu RG, Chen L, Yu ZW*)
22. The Differences in Heparin Binding for the C-terminal Basic-sequence-rich Peptides of HPV-16 and HPV-18 Capsid Protein L1, J. Chem. Thermodynamics, 47: 130–137 (2012). (Sun J, Yu JS, Yu ZW, Zha X, Wu YQ*)
23. Denaturation Behaviors of Two-State and Non-Two-State Proteins Examined by an Interruption–Incubation Protocol, J. Phys. Chem. B, 115(28): 8901-8909 (2011) (Luo JJ, Wu FG, Yu JS, Wang R, and Yu ZW*)
24. Regional Cooperativity in the Phase Transitions of Dipalmitoylphosphatidylcholine Bilayers: The Lipid Tail Triggers the Isothermal Crystallization Process, J. Phys. Chem. B, 115(26): 8559-8568 (2011). (Wu FG, Jia Q, Wu RG, and Yu ZW*)
25. Unfolding and refolding details of lysozyme in the presence of β-casein micelles, Phys. Chem. Chem. Phys., 13: 3429-3436 (2011). (Wu FG, Luo JJ, and Yu ZW*)
26. Structural and Kinetic Properties of a-Tocopherol in Phospholipid Bilayers, a Molecular Dynamics Simulation Study, J. Phys. Chem. B, 113(52): 16537-16546 (2009). (Qin SS, Yu ZW*, Yu, YX)
27. Structural Characterization on the Gel to Liquid-Crystal Phase Transition of Fully Hydrated DSPC and DSPE Bilayers, J. Phys. Chem. B, 113(23): 8114-8123 (2009). (Qin SS, Yu ZW*, Yu, YX)
28. Water Mediates the Metastable Crystal-to-Stable Crystal Phase Transition Process in Phospholipid Aqueous Dispersion, J. Phys. Chem. B, 113(4): 869-872 (2009). (Wu FG, Chen L, and Yu ZW*)
29. The Role of Sterol Rings and Side Chain on the Structure and Phase Behaviour of Sphingomyelin Bilayer, Molecular Membrane Biology 25(6&7): 485-497 (2008). (Gao WY, Quinn PJ, and Yu ZW*)
30. Phase Diagram of Androsterol-dipalmitoylphosphatidylcholine Mixtures Dispersed in Excess Water, J. Phys. Chem. B, 112(28): 8375-8382 (2008). (Gao WY, Chen L, Wu RG, Yu ZW*, and Quinn PJ)
31. Liquid Ordered Phase of Binary Mixtures Containing Dipalmitoylphosphatidylcholine and Sterols, Acta Phys. Chim. Sin., 24(7): 1149-1154 (2008) (Gao WY, Chen L, Wu FG, and Yu ZW*)
32. The Partition of Cholesterol between Ordered and Fluid Bilayers of Phosphatidylcholine: a Synchrotron X-ray Diffraction Study, Biochim. Biophys. Acta – Biomembranes, 1768(11), 2873-2881 (2007). (Chen L, Yu ZW*, and Quinn PJ*)
33. Condensation Effect of Cholesterol, Stigmasterol, and Sitosterol on Dipalmitoylphosphatidylcholine in Molecular Monolayers, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 293(1-3), 123-129 (2007) (Su YL, Li QZ, Chen L, and Yu ZW*)
34. Phase Diagram of Stigmasterol-Dipalmitoylphosphatidylcholine Mixtures Dispersed in Excess Water, Biochim. Biophys. Acta – Biomembranes, 1758 (6), 764-771(2006). (Wu RG, Chen L, Yu ZW*, and Quinn PJ)
35. Characterisation of a Quasi-crystalline Phase in Codispersions of Phosphatidylethanolamine and Glucocerebroside, Biophysical Journal, 86(4): 2208-2217 (2004) (Feng Y, Rainteau D, Chachaty C, Yu ZW*, Wolf C, and Quinn PJ)
36. The Kinetics and Mechanism of the Formation of Crystalline Phase of Dipalmitoylphosphatidylethanolamine Dispersed in Dimethyl Sulfoxide Solutions. Chemistry and Physics of Lipids, 127(2):153-159 (2004) (Chen L, Xie X, Yu ZW*, Quinn PJ)
37. Stable Cubic Phase in the Codispersion of Glucocerebroside and Palmitoyloleoylphosphatidylethanolamine, Chemistry and Physics of Lipids, 126(2):141-148 (2003) (Feng Y, Yu ZW*, and Quinn PJ)
38. Effect of Urea, Dimethylurea, and Tetramethylurea on the Phase Behavior of Dioleoylphosphatidylethanolamine, Chemistry and Physics of Lipids, 114(2):149-157 (2002) (Feng Y, Yu ZW*, and Quinn PJ)
39. 二价金属离子对鲑鱼精DNA热稳定性的影响, 高等学校化学学报,23(12): 2366-2368 (2002). (邬瑞光, 尉志武*, 陈琳, 周蕊)
40. Kinetic Phase Behavior of Distearoylphosphatidylethanolamine Dispersed in Glycerol. Biophysical Chemistry, 89(2-3): 231-238 (2001) (Chen L, Yu ZW*, Quinn PJ)
41. The Effect of Dimethyl Sulphoxide on the Structure and Phase Behaviour of Palmitoleoylphosphatidylethanolamine. Biochim. Biophys. Acta – Biomembranes, 1509(1-2):440-450 (2000) (Yu ZW and Quinn PJ*)
42. The Modulation of Membrane Structure and Stability by Dimethyl Sulphoxide (Review). Molecular Membrane Biology, 15:59-68 (1998) (Yu ZW and Quinn PJ*)
43. Molecular Forces between Membranes Displaying Neutral Glycosphingolipids: Evidence for Carbohydrate Attraction. Biochemistry, 37(6): 1540-1550 (1998). (Yu ZW, Calvet TL, and Leckband D*)
44. Solvation Effects of Dimethyl Sulphoxide on the Structure of Phospholipid Bilayers. Biophysical Chemistry, 70(1): 35-39 (1998). (Yu ZW and Quinn PJ*)
45. Thermotropic Properties of Dioleoylphosphatidylethanolamine in Aqueous Dimethylsulphoxide Solutions. Archives of Biochemistry and Biophysics, 332(1): 187-195 (1996). (Yu ZW, Williams WP, and Quinn PJ*)
46. Phase Stability of Phosphatidylcholines in Dimethylsulphoxide Solutions. Biophysical Journal, 69(4):1456-1463 (1995). (Yu ZW and Quinn PJ*)
47. Phase Behaviour of Distearoylphosphatidylethanolamine in Glycerol - A Thermal and X-ray Diffraction Study. Biochim. Biophys. Acta – Biomembranes, 1237(2): 135-142 (1995)(Yu ZW, Tsvetkova NM, Tsonev LI, and Quinn PJ*)
48. Dimethyl Sulphoxide: a Review of Its Applications in Cell Biology. Bioscience Reports, 14(6): 259-281 (1994). (Yu ZW and Quinn PJ*)
(三)分子自组装
1. Free-Standing Two-Dimensional Crystals Formed from Self-Assembled Ionic Liquids, J. Phys. Chem. Lett. 14: 2744−2749 (2023) (Dai D, Cao B, Hao XL, Li ZH, and Yu ZW*)
2. Transition Mechanism from Nonlamellar to Well-Ordered Lamellar Phases: Is the Lamellar Liquid-Crystal Phase a Must? J. Phys. Chem. Lett. 12: 4484−4489 (2021) (Cao BB, Guo HY, Hao XL, Wu ZH, Wu FG, and Yu ZW*)
3. Supramolecular Chemistry of Cucurbiturils: Tuning Cooperativity with Multiple Noncovalent Interactions from Positive to Negative, Langmuir, 32(47): 12352–12360 (2016) (Huang ZH, Qin K, Deng G, Wu GL, Bai YH, Xu JF, Wang ZQ, Yu ZW, Oren S., and Zhang X*)
4. Complexation of Lysozyme with Sodium Poly(styrenesulfonate) via the Two-State and Non-Two-State Unfoldings of Lysozyme, J. Phys. Chem. B, 119(45): 14382–14392 (2015). (Wu FG, Jiang YW, Sun HY, Luo JJ, and Yu ZW*)
5. Demixing and crystallization of DODAB in DPPC–DODAB binary mixtures, Phys. Chem. Chem. Phys. 16(29): 15307–15318 (2014) (Wu FG, Wu RG, Sun HY, Zheng YZ, and Yu ZW*)
6. Selective-Recognition-Induced Nanostructures in a Cucurbit[7]uril-based Host−Guest System: Micelles, Nanorods and Nanosheets, Phys. Chem. Chem. Phys., 14: 8506-8510 (2012) (Yu JS, Wu FG, Zhou Y, Zheng YZ, and Yu ZW*)
7. Stepwise Ordering of Imidazolium-Based Cationic Surfactants during the Cooling-Induced Crystallization, Langmuir, 28 (19): 7350–7359 (2012) (Wu FG, Yu JS, Sun SF, Sun HY, Luo JJ, and Yu ZW*)
8. Crystallization from the micellar phase of imidazolium-based cationic surfactants, J. Colloid Interface Science, 374(1): 197–205 (2012) (Wu FG, Wang NN, Zhang QG, Sun SF, and Yu ZW*)
9. Comparative Studies on the Crystalline to Fluid Phase Transitions of Two Equimolar Cationic/Anionic Surfactant Mixtures Containing Dodecylsulfonate and Dodecylsulfate, Langmuir, 27 (24): 14740–14747 (2011) (Wu FG, Yu JS, Sun SF, and Yu ZW*)
10. Formation and Transformation of the Subgel Phase in Dioctadecyldimethylammonium Bromide Aqueous Dispersions, Langmuir, 27 (6): 2349–2356 (2011). (Wu FG, Yu ZW*, and Ji, Gang)
11. Mechanism of the Fast Exchange Between Bound and Free Guests in Cucurbit[7]uril–Guest Systems, Phys. Chem. Chem. Phys., 13: 3638-3641 (2011). (Yu JS, Wu FG, Tao LF, Luo JJ, and Yu ZW*)
12. 两亲性分子聚集体的相变及其协同性研究,中国科学 B,40(9):1210–1216 (2010). (尉志武,吴富根)
13. Acetonitrile Induces Nonsynchronous Interdigitation and Dehydration of Dipalmitoylphosphatidylcholine Bilayers, J. Phys. Chem. B, 114(39): 12685-12691 (2010). (Wu FG, Wang NN, Tao LF, and Yu ZW*)
14. Infrared Spectroscopy Reveals the Nonsynchronicity Phenomenon in the Glassy to Fluid Micellar Transition of DSPE-PEG2000 Aqueous Dispersions, Langmuir, 26(15): 12777-12784 (2010). (Wu FG, Luo JJ, and Yu ZW*)
15. Nonsynchronicity Phenomenon Observed during the Lamellar–Micellar Phase Transitions of 1-Stearoyllysophosphatidylcholine Dispersed in Water, J. Phys. Chem. B, 114(6): 2158-2164(2010). (Wu FG, Wang NN, Yu GS, Luo JJ, and Yu ZW*)
16. Non-Synchronous Change in the Head and Tail of DODAB Molecules during the Liquid Crystalline-to-Coagel Phase Transformation Process, Langmuir, 25(23): 13394-13401(2009). (Wu FG, Wang NN, and Yu ZW*)
17. New Features on the Phase Transitions of Behenic Acid Monolayers as Unveiled by 2D-compressibility Coefficient, Chinese Journal of Chemistry, 26(9): 1596-1600 (2008) (Gao WY and Yu ZW*)
18. Characterisation of the Liquid-expanded to Liquid-condensed Phase Transition of Monolayers by Means of Compressibility, Langmuir, 18(11): 4530-4531 (2002) (Yu ZW* Jin J, and Cao Y)
(四)溶液化学与热化学
1. Structural microheterogeneity and hydrogen bonding properties in the mixtures of two ionic liquids with a common imidazolium cation, J. Mol. Liquids, 368: 120594 (2022) (Zhao R, Xu XZ, Wang ZH, Zheng Y, Zhou Y*, Yu ZW*)
2. Abnormalities of the Halogen Bonds in the Complexes between Y2CTe (Y = H, F, CH3) and XF (X = F, Cl, Br, I), Molecules 27(23): 8523 (2022) (Wang YQ, Wang RJ, Li QZ*, and Yu ZW*)
3. Tracking the Micro-heterogeneity and Hydrogen-bonding Interactions in Hydroxyl-functionalized Ionic liquid solutions: A Combined Experimental and Computational Study, ChemPhysChem. 22(18): 1891-1899 (2021) (Zhang YQ Tan X, Ding WL, Wang YL, He HY*, and Yu ZW*)
4. The structural properties of ZnCl2-ethylene glycol binary system and the peculiarities at the eutectic composition, Phys. Chem. Chem. Phys. 23(23):13136 – 13147 (2021) (Kalhor P, Ghandi K, Ashraf H, and Yu ZW*)
5. The Structures of ZnCl2-Ethanol Mixtures, a Spectroscopic and Quantum Chemical Calculation Study, Molecules 26(9): 2498 (2021) (Kalhor P, Wang YQ, and Yu ZW*)
6. Comparative Study of the Hydrogen Bonding Properties between Bis(fluorosulfonyl)imide/Bis(trifluoromethyl)sulfonylimide-based Ether-Functionalized Ionic Liquids and Methanol, J. Mol. Liquids, 322: 115333 (2021) (Chen H, Wang ZH, Xu XZ, Gong SD, Yu ZW, Zhou Y*).
7. The Microscopic Structure of 1-Methoxyethyl-3-methylimidazolium bis(trifluoromethylsulfonyl)imide (EOMIMTFSI) during Dilution with Polar Solvents, J. Mol. Liquids, 322: 114901. (2021) (Chen H, Wang ZH, Xu XZ, Gong SD, Yu ZW, Zhou Y*)
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