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完整後設資料紀錄
DC 欄位 | 值 | 語言 |
---|---|---|
dc.contributor.advisor | 張嘉升(Chia-Seng Chang) | |
dc.contributor.author | Yi-Hsien Lu | en |
dc.contributor.author | 呂奕賢 | zh_TW |
dc.date.accessioned | 2021-06-16T05:40:48Z | - |
dc.date.available | 2015-02-01 | |
dc.date.copyright | 2014-08-21 | |
dc.date.issued | 2014 | |
dc.date.submitted | 2014-08-12 | |
dc.identifier.citation | 1. Ishida, N., et al., Nano bubbles on a hydrophobic surface in water observed by tapping-mode atomic force microscopy. Langmuir, 2000. 166377-6380.
2. Lou, S.T., et al., Nanobubbles on solid surface imaged by atomic force microscopy. Journal of Vacuum Science & Technology B, 2000. 18(5): p. 2573-2575. 3. Tyrrell, J.W.G. and P. Attard, Images of nanobubbles on hydrophobic surfaces and their interactions. Physical Review Letters, 2001. 87(17). 4. Tyrrell, J.W.G. and P. Attard, Atomic force microscope images of nanobubbles on a hydrophobic surface and corresponding force-separation data. Langmuir, 2002. 18(1): p. 160-167. 5. Holmberg, M., et al., Nanobubble trouble on gold surfaces. Langmuir, 2003. 19(25): p. 10510-10513. 6. Steitz, R., et al., Nanobubbles and their precursor layer at the interface of water against a hydrophobic substrate. Langmuir, 2003. 19(6): p. 2409-2418. 7. Yang, J.W., et al., Very small bubble formation at the solid-water interface. Journal of Physical Chemistry B, 2003. 107(25): p. 6139-6147. 8. Evans, D.R., V.S.J. Craig, and T.J. Senden, The hydrophobic force: nanobubbles or polymeric contaminant? Physica a-Statistical Mechanics and Its Applications, 2004. 339(1-2): p. 101-105. 9. Simonsen, A.C., P.L. Hansen, and B. Klosgen, Nanobubbles give evidence of incomplete wetting at a hydrophobic interface. Journal of Colloid and Interface Science, 2004. 273(1): p. 291-299. 10. Zhang, X.H., et al., Degassing and temperature effects on the formation of nanobubbles at the mica/water interface. Langmuir, 2004. 20(9): p. 3813-3815. 11. Zhang, L.J., et al., Electrochemically controlled formation and growth of hydrogen nanobubbles. Langmuir, 2006. 22(19): p. 8109-8113. 12. Zhang, X.H., et al., Removal of induced nanobubbles from water/graphite interfaces by partial degassing. Langmuir, 2006. 22(22): p. 9238-9243. 13. Zhang, X.H., N. Maeda, and V.S.J. Craig, Physical properties of nanobubbles on hydrophobic surfaces in water and aqueous solutions. Langmuir, 2006. 22(11): p. 5025-5035. 14. Borkent, B.M., et al., Superstability of surface nanobubbles. Physical Review Letters, 2007. 98(20). 15. Yang, J., et al., Kinetics of CO2 nanobubble formation at the solid/water interface. Physical Chemistry Chemical Physics, 2007. 9(48): p. 6327-6332. 16. Yang, S.J., et al., Characterization of nanobubbles on hydrophobic surfaces in water. Langmuir, 2007. 23(13): p. 7072-7077. 17. Zhang, X.H., A. Khan, and W.A. Ducker, A nanoscale gas state. Physical Review Letters, 2007. 98(13). 18. Bhushan, B., Y. Wang, and A. Maali, Coalescence and movement of nanobubbles studied with tapping mode AFM and tip-bubble interaction analysis. Journal of Physics-Condensed Matter, 2008. 20(48). 19. Zhang, X.H., A. Quinn, and W.A. Ducker, Nanobubbles at the interface between water and a hydrophobic solid. Langmuir, 2008. 24(9): p. 4756-4764. 20. Borkent, B.M., et al., Preferred sizes and ordering in surface nanobubble populations. Physical Review E, 2009. 80(3). 21. Ducker, W.A., Contact Angle and Stability of Interfacial Nanobubbles. Langmuir, 2009. 25(16): p. 8907-8910. 22. Wang, Y.L., B. Bhushan, and X.Z. Zhao, Improved Nanobubble Immobility Induced by Surface Structures on Hydrophobic Surfaces. Langmuir, 2009. 25(16): p. 9328-9336. 23. Yang, S.J., et al., Electrolytically Generated Nanobubbles on Highly Orientated Pyrolytic Graphite Surfaces. Langmuir, 2009. 25(3): p. 1466-1474. 24. Borkent, B.M., et al., On the Shape of Surface Nanobubbles. Langmuir, 2010. 26(1): p. 260-268. 25. Wang, Y.L. and B. Bhushan, Boundary slip and nanobubble study in micro/nanofluidics using atomic force microscopy. Soft Matter, 2010. 6(1): p. 29-66. 26. Craig, V.S.J., Very small bubbles at surfaces-the nanobubble puzzle. Soft Matter, 2011. 7(1): p. 40-48. 27. Zhang, L.J., et al., The length scales for stable gas nanobubbles at liquid/solid surfaces. Soft Matter, 2010. 6(18): p. 4515-4519. 28. Mazumder, M. and B. Bhushan, Propensity and geometrical distribution of surface nanobubbles: effect of electrolyte, roughness, pH, and substrate bias. Soft Matter, 2011. 7(19): p. 9184-9196. 29. Seddon, J.R.T. and D. Lohse, Nanobubbles and micropancakes: gaseous domains on immersed substrates. Journal of Physics-Condensed Matter, 2011. 23(13). 30. van Limbeek, M.A.J. and J.R.T. Seddon, Surface Nanobubbles as a Function of Gas Type. Langmuir, 2011. 27(14): p. 8694-8699. 31. Berkelaar, R.P., et al., Temperature Dependence of Surface Nanobubbles. Chemphyschem, 2012. 13(8): p. 2213-2217. 32. Seddon, J.R.T., et al., Surface Bubble Nucleation Stability. Physical Review Letters, 2011. 106(5). 33. Guan, M., et al., Investigation on the Temperature Difference Method for Producing Nanobubbles and Their Physical Properties. Chemphyschem, 2012. 13(8): p. 2115-2118. 34. Zhang, X.H., et al., Effects of Surfactants on the Formation and the Stability of Interfacial Nanobubbles. Langmuir, 2012. 28(28): p. 10471-10477. 35. Peng, H., M.A. Hampton, and A.V. Nguyen, Nanobubbles Do Not Sit Alone at the Solid-iquid Interface. Langmuir, 2013. 29(20): p. 6123-6130. 36. Walczyk, W., P.M. Schon, and H. Schonherr, The effect of PeakForce tapping mode AFM imaging on the apparent shape of surface nanobubbles. Journal of Physics-Condensed Matter, 2013. 25(18). 37. Walczyk, W. and H. Schonherr, Closer Look at the Effect of AFM Imaging Conditions on the Apparent Dimensions of Surface Nanobubbles. Langmuir, 2013. 29(2): p. 620-632. 38. Wang, S., M.H. Liu, and Y.M. Dong, Understanding the stability of surface nanobubbles. Journal of Physics-Condensed Matter, 2013. 25(18). 39. Zhang, X.H., et al., Stability of Interfacial Nanobubbles. Langmuir, 2013. 29(4): p. 1017-1023. 40. Zhao, B.Y., et al., Mechanical mapping of nanobubbles by PeakForce atomic force microscopy. Soft Matter, 2013. 9(37): p. 8837-8843. 41. Song, Y., et al., The Origin of the 'Snap-In' in the Force Curve between AFM Probe and the Water/Gas Interface of Nanobubbles. Chemphyschem, 2014. 15(3): p. 492-499. 42. Zhang, X.H., et al., Detection of novel gaseous states at the highly oriented pyrolytic graphite-water interface. Langmuir, 2007. 23(4): p. 1778-1783. 43. Zhang, X.H., N. Maeda, and J. Hu, Thermodynamic Stability of Interfacial Gaseous States. Journal of Physical Chemistry B, 2008. 112(44): p. 13671-13675. 44. Zhang, L.J., et al., Nanoscale Multiple Gaseous Layers on a Hydrophobic Surface. Langmuir, 2009. 25(16): p. 8860-8864. 45. Hampton, M.A. and A.V. Nguyen, Nanobubbles and the nanobubble bridging capillary force. Advances in Colloid and Interface Science, 2010. 154(1-2): p. 30-55. 46. Zhang, X.H. and N. Maeda, Interfacial Gaseous States on Crystalline Surfaces. Journal of Physical Chemistry C, 2011. 115(3): p. 736-743. 47. Zhang, L.J., et al., The Morphology and Stability of Nanoscopic Gas States at Water/Solid Interfaces. Chemphyschem, 2012. 13(8): p. 2188-2195. 48. Karpitschka, S., et al., Nonintrusive Optical Visualization of Surface Nanobubbles. Physical Review Letters, 2012. 109(6). 49. Chan, C.U. and C.D. Ohl, Total-Internal-Reflection-Fluorescence Microscopy for the Study of Nanobubble Dynamics. Physical Review Letters, 2012. 109(17). 50. Dietrich, E., et al., Particle tracking around surface nanobubbles. Journal of Physics-Condensed Matter, 2013. 25(18). 51. Huang, T.W., et al., Dynamics of hydrogen nanobubbles in KLH protein solution studied with in situ wet-TEM. Soft Matter, 2013. 9(37): p. 8856-8861. 52. Brenner, M.P. and D. Lohse, Dynamic Equilibrium Mechanism for Surface Nanobubble Stabilization. Physical Review Letters, 2008. 101(21). 53. Das, S., J.H. Snoeijer, and D. Lohse, Effect of impurities in description of surface nanobubbles. Physical Review E, 2010. 82(5). 54. Das, S., Effect of impurities in the description of surface nanobubbles: Role of nonidealities in the surface layer. Physical Review E, 2011. 83(6). 55. Seddon, J.R.T., H.J.W. Zandvliet, and D. Lohse, Knudsen Gas Provides Nanobubble Stability. Physical Review Letters, 2011. 107(11). 56. Liu, Y.W. and X.R. Zhang, Nanobubble stability induced by contact line pinning. Journal of Chemical Physics, 2013. 138(1). 57. Weijs, J.H. and D. Lohse, Why Surface Nanobubbles Live for Hours. Physical Review Letters, 2013. 110(5). 58. Takahashi, M., K. Chiba, and P. Li, Free-radical generation from collapsing microbubbles in the absence of a dynamic stimulus. Journal of Physical Chemistry B, 2007. 111(6): p. 1343-1347. 59. Ohgaki, K., et al., Physicochemical approach to nanobubble solutions. Chemical Engineering Science, 2010. 65(3): p. 1296-1300. 60. Ushikubo, F.Y., et al., Evidence of the existence and the stability of nano-bubbles in water. Colloids and Surfaces a-Physicochemical and Engineering Aspects, 2010. 361(1-3): p. 31-37. 61. Agarwal, A., W.J. Ng, and Y. Liu, Principle and applications of microbubble and nanobubble technology for water treatment. Chemosphere, 2011. 84(9): p. 1175-1180. 62. Wu, C.D., et al., Generation and characterization of submicron size bubbles. Advances in Colloid and Interface Science, 2012. 179: p. 123-132. 63. Johnson, P.B. and D.J. Mazey, Helium Gas Bubble Lattices in Face-Centerd-Cubic Metals. Nature, 1978. 276(5688): p. 595-596. 64. Johnson, P.B. and D.J. Mazey, Helium Gas Bubble Super-Lattice in Copper and Nickel. Nature, 1979. 281(5730): p. 359-360. 65. Evans, J.H., A. Vanveen, and L.M. Caspers, Formation of Helium Platelets in Molybdenum. Nature, 1981. 291(5813): p. 310-312. 66. Jager, W., et al., The Density and Pressure of Helium in Bubbles in Metals. Radiation Effects and Defects in Solids, 1983. 78(1-4): p. 315-325. 67. Felde, A.V., et al., Pressure of Neon, Argon, and Xenon Bubbles in Aluminum. Physical Review Letters, 1984. 53(9): p. 922-925. 68. Donnelly, S.E. and C.J. Rossouw, Lattice Images of Solid Xenon Precipitates in Aluminum at Room-Temperature. Science, 1985. 230(4731): p. 1272-1273. 69. Evans, J.H. and D.J. Mazey, Evidence for Solid Krypton Bubbles in Copper, Nickel and Gold at 293-K. Journal of Physics F-Metal Physics, 1985. 15(1): p. L1-L6. 70. Rossouw, C.J. and S.E. Donnelly, Superheating of Small Solid-Argon Bubbles in Aluminum. Physical Review Letters, 1985. 55(27): p. 2960-2963. 71. Templier, C., R.J. Gaboriaud, and H. Garem, Precipitation of Implanted Xenon in Aluminum. Materials Science and Engineering, 1985. 69(1): p. 63-66. 72. Templier, C., et al., Solid and Fluid Xenon in Xe Implanted Aluminum. Nuclear Instruments & Methods in Physics Research Section B-Beam Interactions with Materials and Atoms, 1986. 18(1): p. 24-33. 73. Johnson, P.B., R.W. Thomson, and D.J. Mazey, Large Bubble-Like Features Ordered on a Macrolattice in Helium-Implanted Gold. Nature, 1990. 347(6290): p. 265-267. 74. Donnelly, S.E., J.H. Evans, and North Atlantic Treaty Organization. Scientific Affairs Division., Fundamental aspects of inert gases in solids. NATO ASI series Series B, Physics. 1991, New York: Plenum Press. x, 473 p. 75. Birtcher, R.C., et al., Behavior of crystalline Xe nanoprecipitates during coalescence. Physical Review Letters, 1999. 83(8): p. 1617-1620. 76. Chen, J., P. Jung, and H. Trinkaus, Evolution of helium platelets and associated dislocation loops in alpha-SiC. Physical Review Letters, 1999. 82(13): p. 2709-2712. 77. Donnelly, S.E., et al., Ordering in a fluid inert gas confined by flat surfaces. Science, 2002. 296(5567): p. 507-510. 78. Song, M., et al., Structure of nanometre-sized Xe particles embedded in Al crystals. Journal of Microscopy-Oxford, 2004. 215: p. 224-229. 79. Song, M., et al., Structure variation of nanometer-sized Xe particles embedded in Al crystals. Applied Surface Science, 2005. 241(1-2): p. 96-101. 80. Iakoubovskii, K., K. Mitsuishi, and K. Furuya, Structure and pressure inside Xe nanoparticles embedded in Al. Physical Review B, 2008. 78(6). 81. CRC handbook of chemistry and physics, 1999, Chapman and Hall/CRCnetBASE,: Boca Raton, FL. p. CD-ROMs. 82. Craig, V.S.J., B.W. Ninham, and R.M. Pashley, Direct measurement of hydrophobic forces: A study of dissolved gas, approach rate, and neutron irradiation. Langmuir, 1999. 15(4): p. 1562-1569. 83. Meyer, E.E., Q. Lin, and J.N. Israelachvili, Effects of dissolved gas on the hydrophobic attraction between surfactant-coated surfaces. Langmuir, 2005. 21(1): p. 256-259. 84. Stevens, H., et al., Effects of degassing on the long-range attractive force between hydrophobic surfaces in water. Langmuir, 2005. 21(14): p. 6399-6405. 85. Meyer, E.E., K.J. Rosenberg, and J. Israelachvili, Recent progress in understanding hydrophobic interactions. Proceedings of the National Academy of Sciences of the United States of America, 2006. 103(43): p. 15739-15746. 86. Pashley, R.M., Effect of degassing on the formation and stability of surfactant-free emulsions and fine teflon dispersions. Journal of Physical Chemistry B, 2003. 107(7): p. 1714-1720. 87. Maeda, N., et al., Further studies on the effect of degassing on the dispersion and stability of surfactant-free emulsions. Langmuir, 2004. 20(8): p. 3129-3137. 88. Pashley, R.M., et al., De-gassed water is a better cleaning agent. Journal of Physical Chemistry B, 2005. 109(3): p. 1231-1238. 89. Snoswell, D.R.E., et al., Colloid stability and the influence of dissolved gas. Journal of Physical Chemistry B, 2003. 107(13): p. 2986-2994. 90. Dai, Z.F., D. Fornasiero, and J. Ralston, Influence of dissolved gas on bubble-particle heterocoagulation. Journal of the Chemical Society-Faraday Transactions, 1998. 94(14): p. 1983-1987. 91. Granick, S., Y.X. Zhu, and H. Lee, Slippery questions about complex fluids flowing past solids. Nature Materials, 2003. 2(4): p. 221-227. 92. Cottin-Bizonne, C., et al., Boundary slip on smooth hydrophobic surfaces: Intrinsic effects and possible artifacts. Physical Review Letters, 2005. 94(5). 93. Arieli, R. and A. Marmur, Decompression sickness bubbles: Are gas micronuclei formed on a flat hydrophobic surface? Respiratory Physiology & Neurobiology, 2011. 177(1): p. 19-23. 94. Arieli, R. and A. Marmur, Dynamics of gas micronuclei formed on a flat hydrophobic surface, the predecessors of decompression bubbles. Respiratory Physiology & Neurobiology, 2013. 185(3): p. 647-652. 95. Miller, K.W., Inert-Gas Narcosis, High-Pressure Neurological Syndrome, and Critical Volume Hypothesis. Science, 1974. 185(4154): p. 867-869. 96. Fowler, B., K.N. Ackles, and G. Porlier, Effects of Inert-Gas Narcosis on Behavior - a Critical-Review. Undersea Biomedical Research, 1985. 12(4): p. 369-402. 97. Lynch, C., J. Baum, and R. Tenbrinck, Xenon anesthesia. Anesthesiology, 2000. 92(3): p. 865-868. 98. Harris, P.D. and R. Barnes, The uses of helium and xenon in current clinical practice. Anaesthesia, 2008. 63(3): p. 284-293. 99. Fukuma, T., Water distribution at solid/liquid interfaces visualized by frequency modulation atomic force microscopy. Science and Technology of Advanced Materials, 2010. 11(3). 100. Zaera, F., Probing Liquid/Solid Interfaces at the Molecular Level. Chemical Reviews, 2012. 112(5): p. 2920-2986. 101. Seddon, J.R.T., et al., Dynamic Dewetting through Micropancake Growth. Langmuir, 2010. 26(12): p. 9640-9644. 102. Mezger, M., et al., High-resolution in situ x-ray study of the hydrophobic gap at the water-octadecyl-trichlorosilane interface. Proceedings of the National Academy of Sciences of the United States of America, 2006. 103(49): p. 18401-18404. 103. Poynor, A., et al., How water meets a hydrophobic surface. Physical Review Letters, 2006. 97(26). 104. Doshi, D.A., et al., Reduced water density at hydrophobic surfaces: Effect of dissolved gases. Proceedings of the National Academy of Sciences of the United States of America, 2005. 102(27): p. 9458-9462. 105. Tian, C.S. and Y.R. Shen, Structure and charging of hydrophobic material/water interfaces studied by phase-sensitive sum-frequency vibrational spectroscopy. Proceedings of the National Academy of Sciences of the United States of America, 2009. 106(36): p. 15148-15153. 106. Ljunggren, S. and J.C. Eriksson, The lifetime of a colloid-sized gas bubble in water and the cause of the hydrophobic attraction. Colloids and Surfaces a-Physicochemical and Engineering Aspects, 1997. 129: p. 151-155. 107. Khasnavis, S., et al., Suppression of Nuclear Factor-kappa B Activation and Inflammation in Microglia by Physically Modified Saline. Journal of Biological Chemistry, 2012. 287(35): p. 29529-29542. 108. Mondal, S., et al., Protection of Tregs, Suppression of Th1 and Th17 Cells, and Amelioration of Experimental Allergic Encephalomyelitis by a Physically-Modified Saline. Plos One, 2012. 7(12). 109. Borsa, P.A., K.L. Kaiser, and J.S. Martin, Oral consumption of electrokinetically modified water attenuates muscle damage and improves postexercise recovery. Journal of Applied Physiology, 2013. 114(12): p. 1736-1742. 110. Choi, S., et al., Enhanced Synaptic Transmission at the Squid Giant Synapse by Artificial Seawater Based on Physically Modified Saline. Frontiers in Synaptic Neuroscience, 2014. 6. 111. Khasnavis, S., et al., Protection of Dopaminergic Neurons in a Mouse Model of Parkinson's Disease by a Physically-Modified Saline Containing Charge-Stabilized Nanobubbles. Journal of Neuroimmune Pharmacology, 2014. 9(2): p. 218-232. 112. Ebina, K., et al., Oxygen and Air Nanobubble Water Solution Promote the Growth of Plants, Fishes, and Mice. Plos One, 2013. 8(6). 113. Pan, G., et al., In-lake algal bloom removal and submerged vegetation restoration using modified local soils. Ecological Engineering, 2011. 37(2): p. 302-308. 114. Dammer, S.M. and D. Lohse, Gas enrichment at liquid-wall interfaces. Physical Review Letters, 2006. 96(20). 115. Bratko, D. and A. Luzar, Attractive surface force in the presence of dissolved gas: A molecular approach. Langmuir, 2008. 24(4): p. 1247-1253. 116. Wang, C.L., et al., High density gas state at water/graphite interface studied by molecular dynamics simulation. Chinese Physics B, 2008. 17(7): p. 2646-2654. 117. Lee, J. and N.R. Aluru, Mechanistic Analysis of Gas Enrichment in Gas-Water Mixtures near Extended Surfaces. Journal of Physical Chemistry C, 2011. 115(35): p. 17495-17502. 118. Peng, H., G.R. Birkett, and A.V. Nguyen, Origin of Interfacial Nanoscopic Gaseous Domains and Formation of Dense Gas Layer at Hydrophobic Solid-Water Interface. Langmuir, 2013. 29(49): p. 15266-15274. 119. Israelachvili, J. and R. Pashley, The Hydrophobic Interaction Is Long-Range, Decaying Exponentially with Distance. Nature, 1982. 300(5890): p. 341-342. 120. Israelachvili, J.N., Intermolecular and surface forces. 3rd ed. 2011, Burlington, MA: Academic Press. xxx, 674 p. 121. Parker, J.L., P.M. Claesson, and P. Attard, Bubbles, Cavities, and the Long-Ranged Attraction between Hydrophobic Surfaces. Journal of Physical Chemistry, 1994. 98(34): p. 8468-8480. 122. Butt, H.-J.r., K. Graf, and M. Kappl, Physics and chemistry of interfaces. 2nd., rev. and enl. ed. Physics textbook. 2006, Weinheim: Wiley-VCH. x, 386 p. 123. Binnig, G., C.F. Quate, and C. Gerber, Atomic Force Microscope. Physical Review Letters, 1986. 56(9): p. 930-933. 124. Cappella, B. and G. Dietler, Force-distance curves by atomic force microscopy. Surface Science Reports, 1999. 34(1-3): p. 1-+. 125. Butt, H.J., B. Cappella, and M. Kappl, Force measurements with the atomic force microscope: Technique, interpretation and applications. Surface Science Reports, 2005. 59(1-6): p. 1-152. 126. Hutter, J.L. and J. Bechhoefer, Calibration of Atomic-Force Microscope Tips. Review of Scientific Instruments, 1993. 64(7): p. 1868-1873. 127. Ducker, W.A., Z.G. Xu, and J.N. Israelachvili, Measurements of Hydrophobic and Dlvo Forces in Bubble-Surface Interactions in Aqueous-Solutions. Langmuir, 1994. 10(9): p. 3279-3289. 128. Fielden, M.L., R.A. Hayes, and J. Ralston, Surface and capillary forces affecting air bubble-particle interactions in aqueous electrolyte. Langmuir, 1996. 12(15): p. 3721-3727. 129. Snyder, B.A., D.E. Aston, and J.C. Berg, Particle-drop interactions examined with an atomic force microscope. Langmuir, 1997. 13(3): p. 590-593. 130. Preuss, M. and H.J. Butt, Measuring the contact angle of individual colloidal particles. Journal of Colloid and Interface Science, 1998. 208(2): p. 468-477. 131. Preuss, M. and H.J. Butt, Direct measurement of particle-bubble interactions in aqueous electrolyte: Dependence on surfactant. Langmuir, 1998. 14(12): p. 3164-3174. 132. Preuss, M. and H.J. Butt, Direct measurement of forces between particles and bubbles. International Journal of Mineral Processing, 1999. 56(1-4): p. 99-115. 133. Yakubov, G.E., O.I. Vinogradova, and H.J. Butt, Contact angles on hydrophobic microparticles at water-air and water-hexadecane interfaces. Journal of Adhesion Science and Technology, 2000. 14(14): p. 1783-1799. 134. Nespolo, S.A., et al., Forces between a rigid probe particle and a liquid interface: Comparison between experiment and theory. Langmuir, 2003. 19(6): p. 2124-2133. 135. Nguyen, A.V., J. Nalaskowski, and J.D. Miller, A study of bubble-particle interaction using atomic force microscopy. Minerals Engineering, 2003. 16(11): p. 1173-1181. 136. Gillies, G., M. Kappl, and H.J. Butt, Direct measurements of particle-bubble interactions. Advances in Colloid and Interface Science, 2005. 114: p. 165-172. 137. Johnson, D.J., N.J. Miles, and N. Hilal, Quantification of particle-bubble interactions using atomic force microscopy: A review. Advances in Colloid and Interface Science, 2006. 127(2): p. 67-81. 138. Ishida, N., Direct measurement of hydrophobic particle-bubble interactions in aqueous solutions by atomic force microscopy: Effect of particle hydrophobicity. Colloids and Surfaces a-Physicochemical and Engineering Aspects, 2007. 300(3): p. 293-299. 139. Assemi, S., A.V. Nguyen, and J.D. Miller, Direct measurement of particle-bubble interaction forces using atomic force microscopy. International Journal of Mineral Processing, 2008. 89(1-4): p. 65-70. 140. Ally, J., et al., Detachment Force of Particles from Air-Liquid Interfaces of Films and Bubbles. Langmuir, 2010. 26(23): p. 18135-18143. 141. Ally, J., et al., Interaction of a Microsphere with a Solid-Supported Liquid Film. Langmuir, 2010. 26(14): p. 11797-11803. 142. Attard, P. and S.J. Miklavcic, Effective spring constant of bubbles and droplets. Langmuir, 2001. 17(26): p. 8217-8223. 143. Rapacchietta, A.V. and A.W. Neumann, Force and Free-Energy Analyses of Small Particles at Fluid Interfaces .2. Spheres. Journal of Colloid and Interface Science, 1977. 59(3): p. 555-567. 144. Scheludko, A., B.V. Toshev, and D.T. Bojadjiev, Attachment of Particles to a Liquid Surface (Capillary Theory of Flotation). Journal of the Chemical Society-Faraday Transactions I, 1976. 72: p. 2815-2828. 145. Baró, A.M. and R.G. Reifenberger, Atomic force microscopy in liquid : biological applications. 2012, Weinheim: Wiley-VCH. xix, 362 p. 146. Garcia, R. and R. Perez, Dynamic atomic force microscopy methods. Surface Science Reports, 2002. 47(6-8): p. 197-301. 147. Giessibl, F.J., Forces and frequency shifts in atomic-resolution dynamic-force microscopy. Physical Review B, 1997. 56(24): p. 16010-16015. 148. Martin, Y., C.C. Williams, and H.K. Wickramasinghe, Atomic Force Microscope Force Mapping and Profiling on a Sub 100-a Scale. Journal of Applied Physics, 1987. 61(10): p. 4723-4729. 149. Albrecht, T.R., et al., Frequency-Modulation Detection Using High-Q Cantilevers for Enhanced Force Microscope Sensitivity. Journal of Applied Physics, 1991. 69(2): p. 668-673. 150. Putman, C.A.J., et al., Tapping Mode Atomic-Force Microscopy in Liquid. Applied Physics Letters, 1994. 64(18): p. 2454-2456. 151. Schaffer, T.E., et al., Studies of vibrating atomic force microscope cantilevers in liquid. Journal of Applied Physics, 1996. 80(7): p. 3622-3627. 152. Garcia, R., R. Magerle, and R. Perez, Nanoscale compositional mapping with gentle forces. Nature Materials, 2007. 6(6): p. 405-411. 153. Cleveland, J.P., et al., Energy dissipation in tapping-mode atomic force microscopy. Applied Physics Letters, 1998. 72(20): p. 2613-2615. 154. Sader, J.E. and S.P. Jarvis, Accurate formulas for interaction force and energy in frequency modulation force spectroscopy. Applied Physics Letters, 2004. 84(10): p. 1801-1803. 155. Katan, A.J., M.H. van Es, and T.H. Oosterkamp, Quantitative force versus distance measurements in amplitude modulation AFM: a novel force inversion technique. Nanotechnology, 2009. 20(16). 156. Giessibl, F.J., Atomic-Resolution of the Silicon (111)-(7x7) Surface by Atomic-Force Microscopy. Science, 1995. 267(5194): p. 68-71. 157. Fukuma, T., et al., True atomic resolution in liquid by frequency-modulation atomic force microscopy. Applied Physics Letters, 2005. 87(3). 158. Yang, C.W., et al., Imaging of soft matter with tapping-mode atomic force microscopy and non-contact-mode atomic force microscopy. Nanotechnology, 2007. 18(8). 159. Fukuma, T., M.J. Higgins, and S.P. Jarvis, Direct imaging of lipid-ion network formation under physiological conditions by frequency modulation atomic force microscopy. Physical Review Letters, 2007. 98(10). 160. Leung, C., et al., Atomic Force Microscopy with Nanoscale Cantilevers Resolves Different Structural Conformations of the DNA Double Helix. Nano Letters, 2012. 12(7): p. 3846-3850. 161. Ido, S., et al., Beyond the Helix Pitch: Direct Visualization of Native DNA in Aqueous Solution. Acs Nano, 2013. 7(2): p. 1817-1822. 162. Giessibl, F.J., Advances in atomic force microscopy. Reviews of Modern Physics, 2003. 75(3): p. 949-983. 163. Jaafar, M., et al., Drive-amplitude-modulation atomic force microscopy: From vacuum to liquids. Beilstein Journal of Nanotechnology, 2012. 3: p. 336-344. 164. Yang, C.W. and I.S. Hwang, Soft-contact imaging in liquid with frequency-modulation torsion resonance mode atomic force microscopy. Nanotechnology, 2010. 21(6). 165. Radmacher, M., et al., Mapping Interaction Forces with the Atomic-Force Microscope. Biophysical Journal, 1994. 66(6): p. 2159-2165. 166. Adamcik, J., A. Berquand, and R. Mezzenga, Single-step direct measurement of amyloid fibrils stiffness by peak force quantitative nanomechanical atomic force microscopy. Applied Physics Letters, 2011. 98(19). 167. Pletikapic, G., et al., Quantitative Nanomechanical Mapping of Marine Diatom in Seawater Using Peak Force Tapping Atomic Force Microscopy. Journal of Phycology, 2012. 48(1): p. 174-185. 168. Derjaguin, B.V., V.M. Muller, and Y.P. Toporov, Effect of Contact Deformations on Adhesion of Particles. Journal of Colloid and Interface Science, 1975. 53(2): p. 314-326. 169. Li, Z.T., et al., Effect of airborne contaminants on the wettability of supported graphene and graphite. Nature Materials, 2013. 12(10): p. 925-931. 170. Vazquez-Campos, S., et al., Self-organization of gold-containing hydrogen-bonded rosette assemblies on graphite surface. Langmuir, 2007. 23(20): p. 10294-10298. 171. Chun, J., et al., Anisotropic adsorption of molecular assemblies on crystalline surfaces. Journal of Physical Chemistry B, 2006. 110(33): p. 16624-16632. 172. Aksay, I.A., et al., Biomimetic pathways for assembling inorganic thin films. Science, 1996. 273(5277): p. 892-898. 173. Svaldo-Lanero, T., et al., Nanopatterning by protein unfolding. Soft Matter, 2008. 4(5): p. 965-967. 174. Wastl, D.S., et al., Observation of 4 nm Pitch Stripe Domains Formed by Exposing Graphene to Ambient Air. Acs Nano, 2013. 7(11): p. 10032-10037. 175. Wastl, D.S., A.J. Weymouth, and F.J. Giessibl, Atomically Resolved Graphitic Surfaces in Air by Atomic Force Microscopy. ACS nano, 2014. 176. Zhang, X.H. and W. Ducker, Formation of interfacial nanodroplets through changes in solvent quality. Langmuir, 2007. 23(25): p. 12478-12480. 177. Zhang, X.H. and W. Ducker, Interfacial oil droplets. Langmuir, 2008. 24(1): p. 110-115. 178. Chandler, D., Interfaces and the driving force of hydrophobic assembly. Nature, 2005. 437(7059): p. 640-647. 179. Raschke, T.M., J. Tsai, and M. Levitt, Quantification of the hydrophobic interaction by simulations of the aggregation of small hydrophobic solutes in water. Proceedings of the National Academy of Sciences of the United States of America, 2001. 98(11): p. 5965-5969. 180. Hirschfelder, J.O., et al., Molecular theory of gases and liquids. Corrected printing with notes added. ed. 1965, New York: Wiley. xxvi, 1249 p. 181. Venables, J., Introduction to surface and thin film processes. 2000, Cambrige, UK ; New York: Cambridge University Press. xvi, 372 p. 182. Vidali, G., et al., Potentials of Physical Adsorption. Surface Science Reports, 1991. 12(4): p. 133-181. 183. Da Silva, J.L.F., C. Stampfl, and M. Scheffler, Adsorption of Xe atoms on metal surfaces: New insights from first-principles calculations. Physical Review Letters, 2003. 90(6). 184. Marx, D. and H. Wiechert, Ordering and phase transitions in adsorbed monolayers of diatomic molecules. Advances in Chemical Physics, Vol 95 - Surface Properties, 1996. 95: p. 213-394. 185. Marx, R., Calorimetric Studies of Phase-Transitions in Two-Dimensional Physisorbed Films. Physics Reports-Review Section of Physics Letters, 1985. 125(1): p. 1-67. | |
dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/56664 | - |
dc.description.abstract | 氣體的熱力學性質一般主要透由氣體的體相相圖來理解。然而,侷限在奈米空間中的氣體結構觀察卻難以由古典熱力學原理來瞭解。在本篇論文中,我們採用先進的原子力顯微鏡技術研究水和水和疏水性固體界面(高定向裂解石墨)的氣體結構。當水中氣體含量低於飽和溶解度時,在石墨和水的界面我們可觀測到由條狀結構構成的規則層狀結構的成核成長。當水中氣體含量超過飽和溶解度時,我們發現了有序的磊晶層狀結構、無序的薄餅層狀結構和帽型奈米結構;它們的存在以及細微的結構和水中氣體濃度以及氣體種類相關。我們比較了不同成像模式對這些氣體結構的觀察,包含頻率調制、振幅調制和峰值力輕敲模式。頻率調制可獲得最正確的表面形貌訊息,而峰值力輕敲模式可探測較底層的結構。我們也探討這些界面結構的力學特性和它們的物理本質。從這些觀察中,我們認為疏水性固體表面對水中溶解的氣體分子提供了一個低化學勢能的吸附位置;而這些界面氣體結構可藉由界面水進一步穩定。在室溫的環境下,當氣體分子被限縮在一個足夠小的空間中,它們可以聚集成為凝態結構;而在這樣的狀況下,氣體的熱力學性質主要是根據界面的交互作用所決定的。在結晶性的固體表面,這樣的氣體甚至可能成為固態結構。 | zh_TW |
dc.description.abstract | The thermodynamic properties of gases have generally been understood primarily thorough phase diagrams of bulk gases. However, observations of gases confined in a nanometer space have posed a great challenge to understand using classical thermodynamics. In this thesis, we investigated interfacial gas structures between water and a hydrophobic solid surface, highly ordered pyrolitic graphite, by using advanced atomic force microscopy techniques. Nucleation and growth of bright patches at the graphite-water interface was observed when the gas concentration was below the saturation level. The bright patches, suspected to be caused by adsorption of N2 molecules at the graphite-water interface, were composed of domains of an ordered row-like structure. When the gas concentration was above the saturation level, ordered epitaxial layer(s), disordered pancake-shaped layers and cap-shaped nanostructures were observed; their existence and detailed structures could be dependent on the concentration and type of gas in water. Comparison of different imaging modes, including the frequency-modulation, the amplitude-modulation, and the PeakForce tapping techniques, on the interfacial gas structures were performed. We demonstrate that the frequency-modulation mode can yield the most accurate topographic information while the Peak-Force tapping mode are able to determine the underlying structures. Mechanical properties and physical essences of these interfacial structures are also discussed. We propose that hydrophobic solid surfaces provide low-chemical-potentials sites at which gas molecules dissolved in water can be adsorbed. The structures are probably further stabilized by interfacial water. Gas molecules can agglomerate into a condensed form when confined in a sufficiently small space under ambient conditions. The ordering and thermodynamics properties of the confined gases are determined primarily according to interfacial interactions. The crystalline solid surface may even induce a solid-gas state. | en |
dc.description.provenance | Made available in DSpace on 2021-06-16T05:40:48Z (GMT). No. of bitstreams: 1 ntu-103-D96222026-1.pdf: 17299644 bytes, checksum: 7e042067cf35144caa9cbc52a4131955 (MD5) Previous issue date: 2014 | en |
dc.description.tableofcontents | 口試委員會審定書 i
Acknowlegement ii 中文摘要 iii ABSTRACT iv CONTENTS vi LIST OF FIGURES x LIST OF TABLES xvi Chapter 1 Introduction 1 1.1 Interface 1 1.2 Mystery of Nanoscopic Gas Structures at the Interface 1 1.2.1 Nanoscopic gas structures at water/solid interfaces 2 1.2.2 Nanoscopic gas structures in solids 5 1.3 Motivation of Our Work 6 1.4 Overview of the Thesis 8 Chapter 2 Nanoscopic Gas Structures 10 2.1 Discovery of Surface Nanobubbles 10 2.2 Physical Properties of Surface Nanobubbles 13 2.2.1 Mechanical properties 13 2.2.2 Stability 15 2.2.3 Coalescence and movement 16 2.2.4 Contact angle 19 2.3 Review of Existing Models Explaining Surface Nanobubbles 20 2.3.1 Interfacial layer of contamination 21 2.3.2 Dynamic Equilibrium 22 2.3.3 Contact line pinning 23 2.3.4 High density gas states 24 2.4 Micropancakes 25 2.5 Nanoprecipitates of Noble Gases in Solids 28 Chapter 3 Atomic Force Microscopy 32 3.1 Basic Principles 32 3.2 Force Curve Measurement 35 3.2.1 Force curves in the static mode 36 3.2.2 Calibration of the force curves 38 3.3 Force Measurement at the Fluid Interface 39 3.3.1 Interactions between a particle and a fluid interface 40 3.3.2 Measurement at the nanobubble/water interface 44 3.4 Contact Mode AFM 46 3.5 Dynamic Mode AFM 47 3.5.1 Amplitude Modulation AFM (AM-AFM) 48 3.5.2 Frequency Modulation AFM (FM-AFM) 52 3.5.3 Height correction 56 3.5 PeakForce Tapping AFM (PF-AFM) 57 Chapter 4 Experimental Setup 61 4.1 Preparation of the Water 61 4.1.1 Degassed water preparation 61 4.1.2 Preparation of water supersaturated with gases 62 4.2 HOPG Sample 63 4.3.1 Agilent 5500 AFM 63 4.3.2 Multimode Nanoscope V 65 Chapter 5 Ordered Epitaxial Layered and Disordered Pancake-shaped Gas Domains at HOPG/water Interfaces 68 5.1 An Ordered Epitaxial Layer of Gas domains 68 5.2 Origin of the Molecular Layer 74 5.3 Self-assembly of N2 molecules at HOPG/water Interfaces 77 5.4 Model of N2 Self-assembly at HOPG/water Interfaces 84 5.5 Multilayer of Ordered and Disordered Structures at HOPG/water Interfaces 87 5.6 Physics on Epitaxial Growth of Dissolved Gas Molecules 94 5.7 Concern about the Contamination 95 Chapter 6 Cap-shaped Gas Nanostructures (Nanobubbles) at HOPG/water Interfaces 98 6.1 Measurement Accuracy 98 6.1.1 Imaging nanobubbles with different AFM modes 98 6.1.2 Imaging nanobubbles under different load 100 6.2 Static Mode Force Curve Measurements on Nanobubbles 102 6.2.1 Force-separation curve on the nanobubble 102 6.2.2 Analysis of the capillary force 104 6.2.4 Effect of the line tension 108 6.3 Concept of AFM Imaging on Nanobubbles 109 6.4 Laplace Pressure inside the Nanobubble 110 6.5 Dynamic Mode Force Curve Measurements on Nanobubbles 112 Chapter 7 Various Gas Nanostructures at HOPG/water Interfaces 117 7.1 Coexistence of Ordered, 2D disordered, and Cap-shaped Nanostructures 117 7.2 Interfacial Structures of N2 at HOPG/water Interfaces 125 7.3 Interfacial Structures of O2 at HOPG/water Interfaces 131 7.4 Schematics of Interfacial N2/O2 Gas Structures 147 7.5 The Role of the Interfacial Water 151 Chapter 8 Condensation of Gas Molecules at the Interface 153 8.1 The Thermodynamic Background 153 8.2 Solution to the Stability of Gas Structures at Solid/Water Interfaces 157 8.3 Relevance to Nanoprecipitates of Noble Gases in Solids 160 8.4 General Concept on the Interface-Induced Condensation of Gas Molecules 163 Chapter 9 Conclusion and Outlook 164 9.1 Conclusion 164 9.2 Future Work 166 REFERENCE 169 | |
dc.language.iso | en | |
dc.title | 利用原子力顯微術觀察水和疏水石墨界面的氣體結構 | zh_TW |
dc.title | Gas Structures at the Interface between Water and Hydrophobic Graphite Observed by Atomic Force Microscopy | en |
dc.type | Thesis | |
dc.date.schoolyear | 102-2 | |
dc.description.degree | 博士 | |
dc.contributor.coadvisor | 黃英碩(Ing-Shouh Hwang) | |
dc.contributor.oralexamcommittee | 周家復(Chia-Fu Chou),陳彥龍(Yeng-Long Chen),江宏仁(Hong-Ren Jiang),黃仲仁(Jung-Ren Huang),陳祺(Chi Chen) | |
dc.subject.keyword | 原子力顯微術,疏水,石墨,氣體結構,奈米氣泡,頻率調制模式,峰值輕敲力模式, | zh_TW |
dc.subject.keyword | Atomic Force Microscopy,Hydrophobic,Graphite,Gas Structures,Nanobubbles,Frequency-Modulation Mode,Peak-Force Tapping Mode, | en |
dc.relation.page | 187 | |
dc.rights.note | 有償授權 | |
dc.date.accepted | 2014-08-12 | |
dc.contributor.author-college | 理學院 | zh_TW |
dc.contributor.author-dept | 物理研究所 | zh_TW |
顯示於系所單位: | 物理學系 |
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