Water site headerMasthead Island, Great Barrier Reef Print-me keygo to Water Visitor Book contributions
 Go to my page Water Structure and Science

Water Structure and Science, References 2901 - 3000


  1. J. Jia, Y. Liang, T. Tsuji, Murata and T. Matsuoka, Elasticity and stability of clathrate hydrate: Role of guest molecule motions, Science Reports, 7 (2017) 1290. [Back]
  2. A. M. Rice, M. K. Rosen, ATP controls the crowd, Science, 356 (2017) 701-702; A. Patel, L. Malinovska, S. Saha, J. Wang, S. Alberti, Y. Krishnan, A. A. Hyman, ATP as a biological hydrotrope, Science, 356 (2017) 753-756. [Back]
  3. E. Leontidis, Chaotropic salts interacting with soft matter: Beyond the lyotropic series, Current Opinion in Colloid & Interface Science, 23 (2016) 100-109; E. Leontidis, Investigations of the Hofmeister series and other specific ion effects using lipid model systems, Advances in Colloid and Interface Science, 243 (2017) 8-22.. [Back]
  4. A. Gurung, O. Dahl and K. Jansson, The fundamental phenomena of nanobubbles and their behavior in wastewater treatment technologies, Geosystem Engineering, 19 (2016) 133-142. [Back]
  5. M. Ghasemi, M. Tsianou and P. Alexandridis, Assessment of solvents for cellulose dissolution, Bioresource Technology, 228 (2017) 330–338; O. A. El Seoud, M. Kostag, K. Jedvert and N. I. Malek, Cellulose regeneration and chemical recycling: Closing the “Cellulose Gap” using environmentally benign solvents, Macromolecular Materials and Engineering, (2020) 1900832. [Back]
  6. V. V. da Cruz, E. Ertan, R. C. Couto, S. Eckert,M. Fondell, M.Dantz, B. Kennedy, T. Schmitt, A. Pietzsch, F. F. Guimarães, H. Ågren, F. Gel’mukhanov, M. Odelius, A. Föhlisch and Victor Kimberg, A study of the water molecule using frequency control over nuclear dynamics in resonant X-ray scattering, Physical Chemistry Chemical Physics, 19 (2017) 19573-19589. [Back]
  7. J. Chen, G. Schusteritsch, C. J. Pickard, C. G. Salzmann and A. Michaelides, Double-layer ice from first principles, Phyical Review B, 95 (2017) 094121. [Back]
  8. Y. Qin, L. Zhang, L. Wang and D. Zhong, Observation of the global dynamic collectivity of a hydration shell
    around apomyoglobin, Journal of Physical Chemistry Letters, 8 (2017) 1124-1131. [Back]
  9. M. J. Nine, M. A. Cole, L. Johnson, D. N. H. Tran and D. Losic, Robust superhydrophobic graphene-based composite coatings with self-cleaning and corrosion barrier properties, ACS Applied Materials & Interfaces, 7 (2015) 28482-28493. [Back]
  10. P. Fibert, C. Relton, M. Heirs and D. Bowden, A comparative consecutive case series of 20 children with a diagnosis of ADHD receiving homeopathic treatment, compared with 10 children receiving usual care, Homeopathy, 105 (2016) 194-201. [Back]
  11. S. J. Cartwright, Solvatochromic dyes detect the presence of homeopathic potencies, Homeopathy, 105 (2016) 55-65; S. J. Cartwright, Homeopathic potencies may possess an electric field(-like) component: Evidence from the use of encapsulated solvatochromic dyes, Homeopathy, 109 (2020) 14-22. [Back]
  12. M. Kulkarni and A. Mukherjee, Understanding B-DNA to A-DNA transition in the right-handed DNA helix: Perspective from a local to global transition, Progress in Biophysics & Molecular Biology, 128 (2017) 63-73. [Back]
  13. L. Noirez and P. Baroni, Identification of a low-frequency elastic behaviour in liquid water, Journal of Physics: Condensed Matter, 24 (2012) 372101; P. Baroni, P.Bouchet and L. Noirez, Highlighting a cooling regime in liquids under submillimeter flows, Journal of Physical Chemistry Letters, 4 (2013) 2026-2029. [Back, 2]
  14. K. Akoa, Influence of osmotic and weight pressure on water release frompolysaccharide ionic gels, Carbohydrate Polymers, 169 (2017) 376-384. [Back]
  15. M. L. Liriano, C. Gattinoni, E. A. Lewis, C. J. Murphy, E. C. H. Sykes and A. Michaelides, Water−ice analogues of polycyclic aromatic hydrocarbons: Water nanoclusters on Cu(111), Journal of the American Chemical Society, 139 (2017) 6403-6410. [Back]
  16. M. L. McDermott, H. Vanselous, S. A. Corcelli and P. B. Petersen, DNA's chiral spine of hydration, ACS Centr. Science, 3 (2017) 708-714; E. A. Perets and E. C. Y. Yan, The H2O helix: The chiral water superstructure surrounding DNA, ACS Central Science, 3 (2017) 683-685; P. Ball, DNA helix has chiral water ‘spine’, Chemistry World, 14(7) (2017) 43. [Back]
  17. A. Hospital, M. Candotti, J. L. Gelpí and M. Orozco, The multiple roles of waters in protein solvation, Journal of Physical Chemistry B, 121 (2017) 3636-3643. [Back]
  18. J. M. M. de Oca, J. A. R. Fris, S. R. Accordino, D. C. Malaspina and G. A. Appignanesi, Structure and dynamics of high- and low-density water molecules in the liquid and supercooled regimes, Eur. Phys. J. E 39 (2016) 124. [Back]
  19. C. R. C. Buhariwalla, R. K. Bowles, I. Saika-Voivod, F. Sciortino and P. H. Poole, Free energy of formation of small ice nuclei near the Widom line in simulations of supercooled water, Eur. Phys. J. E 38 (2015) 39. [Back]
  20. M. Allan and L. J. Mauer, Dataset of water activity measurements of alcohol:watersolutions using a Tunable Diode Laser, Data in Brief 12 (2017) 364-369. [Back]
  21. P. L. Privalov and C. Crane‑Robinson, Role of water in the formation of macromolecular structures, Eur. Biophysical Journal, 46 (2017) 203-224. [Back, 2, 3]
  22. A. Fernández and L. R. Scott, Opinion: Advanced modeling reconciles counterintuitive decisions in lead optimization, Trends Biotechnol. 35 (2017) 490-497. [Back]
  23. V. N. Syryamina and S. A. Dzuba, Dynamical transitions at low temperatures in the nearest hydration
    shell of phospholipid bilayers, Journal of Physical Chemistry B 121 (2017) 1026-1032. [Back]
  24. H. I. Okur, J. Hladílková, K. B. Rembert, Y. Cho, J. Heyda, J. Dzubiella, P.S. Cremer and P.Jungwirth, Beyond the Hofmeister series: Ion specific effects on proteins and their biological functions, Journal of Physical Chemistry B, 121 (2017) 1997-2014. [Back]
  25. K. Nomura, T. Kaneko, J. Baid, J. S. Francisco, K. Yasuoka and X. C. Zeng, Evidence of low-density and high-density liquid phases and isochore end point for water confined to carbon nanotube, Proceedings of the National Academy of Sciences, 114 (2017) 4066-4071. [Back, 2] [Back to Top to top of page]
  26. K. Garajová, A. Balogová, E. Duseková, D. Sedláková, E. Sedlák and R. Varhaĉ, Correlation of lysozyme activity and stability in the presence of Hofmeister series anions, Biochimica Biophysica Acta - Proteins and Proteomics 1865 (2017) 281-288. [Back]
  27. Y. E. Altabet, A. Haji-Akbari and P. G. Debenedetti, Effect of material flexibility on the thermodynamics and kinetics of hydrophobically induced evaporation of water, Proceedings of the National Academy of Sciences,   114 (2017) E2548-E2555. [Back]
  28. (a) A. V. Anikeenko, E. D. Kadtsyn and N. N. Medvedev, Statistical geometry characterization of global structure of TMAO and TBA aqueous solutions, Journal of Molecular Liquids, 245 (2017) 35-41; (b) E. D. Kadtsyn, A. V. Anikeenko and N. N. Medvedev, Statistical geometry characterization of local structure of TMAO, TBA and urea aqueous solutions, Journal of Molecular Liquids, 286 (2019) 110870. [Back]
  29. Yu. D. Fomin, E. N. Tsiok, V. N. Ryzhov and V. V. Brazhkin, A novel anomalous region of water
    arXiv:1706.02923v1 [cond-mat.soft] 9 Jun 2017. [Back, 2
  30. F. Perakis, K. Amann-Winkel, F. Lehmkühler, M. Sprung, D. Mariedahl, J. A. Sellberg, H. Pathak, A. Späh, F. Cavalca, D. Schlesinger, A. Ricci, A. Jain, B. Massani, F. Aubree, C. J. Benmore, T. Loerting, G. Grübel, L. G. M. Pettersson and A. Nilsson, Diffusive dynamics during the high-to-low-density transition in amorphous ice, Proceedings of the National Academy of Sciences, 114 (2017) 8193-8198; F. Sciortino, Which way to low-density liquid water? Proceedings of the National Academy of Sciences, 114 (2017) 8141-8143. [Back, 2
  31. R. C. Remsing and J. D. Weeks, Dissecting hydrophobic hydration and association, Journal of Physical Chemistry B. 117 ( 2013) 15479-15491. [Back]
  32. H. Ren, S. R. German, M. A. Edwards, Q. Chen and H. S. White, Electrochemical generation of individual O2 nanobubbles via H2O2 oxidation, Journal of Physical Chemistry Letters, 8 (2017) 2450-2454. [Back]
  33. B. H. Tan, H. An and C.-D. Ohl, Resolving the pinning force of nanobubbles with optical microscopy, Physical Review Letters 118 (2017) 054501. [Back]
  34. Y. Liu, M. A. Edwards, S. R. German, Q. Chen and H. S. White, The dynamic steady state of an electrochemically generated nanobubble, Langmuir, 33 (2017) 1845-1853. [Back]
  35. S. Singla, E. Anim-Danso, A. E Islam, Y. Ngo, S. S Kim, R. R. Naik and A. Dhinojwala, Insight on structure of water and ice next to graphene using surface-sensitive spectroscopy, ACS Nano 11 (2017) 4899-4906. [Back]
  36. K. Umemoto and R. M. Wentzcovitch, First principles study of volume isotope effects in ices VIII and X, Jap. J. Appl. Phys. 56 (2017) 05FA03. [Back]
  37. T. Temesgen, T. T. Bui, M. Han, T. Kim and H. Park, Micro and nanobubble technologies as a new horizon for water treatment techniques: A review, Advances in Colloid & Interface Science, 246 (2017) 40-51. [Back]
  38. H. Peng, G. Dai, S. Wang and H. Xu, The evolution behavior and dissolution mechanism of cellulose in aqueous solvent, Journal of Molecular Liquids, 241 (2017) 959-966. [Back]
  39. A. Seyfi, R. Afzalzadeh and A.Hajnorouzi, Increase in water evaporation rate with increase in static magnetic field perpendicular to water-air interface, Chemical Engineering and Processing: Process Intensification, 120 (2017) 195-200. [Back]
  40. A. E. Sitnitsky, Exactly solvable Schrödinger equation with double-well potential for hydrogen bond, Chemical Physics Letters, 676 (2017) 169-173. [Back]
  41. N. Bidin, S. R. Azni, S. Islam, M. Abdullah, M. F. S. Ahmad, G. Krishnan, A. R. Johari, M. Aizat A. Bakar, N. S. Sahidan, N. Musa, M. F. Salebi, N. Razali and M. M. Sanagi, The effect of magnetic and optic field in water electrolysis, International Journal of Hydrogen Energy, 42 (2017) 16325 -16332. [Back]
  42. H. Wada, J. Koido, S. Miyazawa, T. Mochizuki, K. Masuda, J. Unga, Y. Oda, R. Suzuki and K. Maruyama, Experimental analysis of behavior in nanobubbles using echograms under ultrasound exposure, Jap. Journal of Appl. Phys. 55 (2016) 07KF06. [Back]
  43. F. Nimmo, What is the Young's modulus of ice? Europa's Icy Shell,.The Workshop on Europa's icy shell: past, present and future, Houston (2004); M. P. Langleben, Young's modulus for sea ice, Can. Journal of Phys. 40 (1962) 1-8. [Back]
  44. J. M. J. van Leeuwen, Skating on slippery ice, arXiv:1706.08278v1 [cond-mat.other] 26 Jun 2017. [Back]
  45. Y. Fu, G. Wang, T. Mei, J. Li, J. Wang, and X. Wang, Accessible graphene aerogel for efficient harvesting solar energy, ACS Sustainable Chemical Engineering, 5 (2017) 4665-4671; K. Krämer, Floating graphene uses sunlight to cook up clean water, Chemistry World, 14(7) (2017) 41. [Back]
  46. C. Efthymiou, M. A. K. Williams and K. M. McGrath, Revealing the structure of high-water content biopolymer networks: Diminishing freezing artefacts in cryo-SEM images, Food Hydrocolloids, 73 (2017) 203-212 [Back]
  47. F. Smallenburg, L. Filion and F. Sciortino, Erasing no-man’s land by thermodynamically stabilizing the liquid–liquid transition in tetrahedral particles, Nature, Physics, 10 (2014) 653-657; F. Mallamace, P. Baglioni, C.Corsaro, J. Spooren, H. E. Stanley and S.-H. Chen, Transport properties of supercooled confined water, Rivesta del Nuova Cimento, 34 (2011) 253-388. [Back]
  48. R. Etchepare, H. Oliveira, M. Nicknig, A. Azevedo and J. Rubio, Nanobubbles: Generation using a multiphase pump, properties and features in flotation, Minerals Engineering, 112 (2017) 19-26. [Back]
  49. J. H. Ortony, B. Qiao, C. J. Newcomb, T. J. Keller, L. C. Palmer, E. Deiss-Yehiely, M. O. de la Cruz, S. Han and S. I. Stupp, Water dynamics from the surface to the interior of a supramolecular nanostructure, Journal of the American Chemical Society, 139 (2017) 8915-8921. [Back]
  50. S. Immel and F. W. Lichtenthaler, The hydrophobic topographies of amylose and its blue iodine complex, Starch/Stärke 52 (2000) 1-8. [Back] [Back to Top to top of page]
  51. R. D. Hancock and B. J. Tarbet, The other double helix—The fascinating chemistry of starch, Journal of Chemical Education, 77 (2000) 988-992. [Back]
  52. P. Bampoulis, V. J. Teernstra, D. Lohse, H. J. W. Zandvliet and B. Poelsema, Hydrophobic ice confined between graphene and MoS2, Journal of Physical Chemistry C, 120 (2016) 27079-27084; arXiv:1706.00675v1 [physics.chem-ph] 2 Jun 2017. [Back]
  53. K. A. Rubinson, Practical corrections for p(H,D) measurements in mixed H2O/D2O biological buffers, Analytical Methods, 9 (2017) 2744-2750. [Back]
  54. N. Ishida, T. Inoue, M. Miyahara and K. Higashitani, Nano bubbles on a hydrophobic surface in water observed by tapping-mode atomic force microscopy. Langmuir, 16 (2000) 6377-6380. [Back]
  55. N. Smolentsev, W.J. Smit, H. J. Bakker and S. Roke, The interfacial structure of water droplets in a hydrophobic liquid, Nature Communications, 8 (2017) 15548. [Back]
  56. M. Henry, The hydrogen bond, Inference: International Review of Science, 1(2) (2015). [Back]
  57. P. L. Silvestrelli, hydrogen-bonding characterization in water and small molecules, Journal of Chemical Physics, 146 (2017) 244315; arXiv:1703.08542v1 [physics.chem-ph] 24 Mar 2017. [Back]
  58. S.An, B. N. Joshi, J.-G. Lee, M. W. Lee, Y. I. Kim, M.. Kim, H. S. Jo and S. S. Yoon, A comprehensive review on wettability, desalination, and purification using graphene-based materials at water interfaces, Catalysis Today, 295 (2017)14-25. [Back, 2, 3
  59. S. H. Oh and J.-M. Kim, Generation and stability of bulk nanobubbles, Langmuir, 33 (2017) 3818-3823. [Back]
  60. P. Kundu, S.-Y.Liu, F.-R. Chen and F.-G. Tseng, In-situ generation of highly stable, sub 10-nm oxygen nanobubbles in liquid environmental TEM, IEEE 29th International Conference on Micro Electro Mechanical Systems (MEMS) (2016) DOI: 10.1109/MEMSYS.2016.7421576. [Back]
  61. I. J. Tyrovolas, Explanation for the Mpemba effect, Journal of Modern Physics, 8 (2017) 2013-2020; I. Tyrovolas, New explanation for the mpemba effect, Proceedings MDPI, 46 (2020) 2; doi:10.3390/ecea-5-06658; Preprints.org, (2019) 2019010118 DOI: 10.20944/preprints201901.0118.v3. [Back]
  62. N. Smolentsev, C. Lütgebaucks, H. I. Okur, A. G. F. de Beer and S. Roke, Intermolecular headgroup interaction and hydration as driving forces for lipid transmembrane asymmetry, Journal of the American Chemical Society, 138 (2016) 4053-4060. [Back]
  63. F. Martelli, H.-Y. Ko, C. C. Borallo and G. Franzese, Structural properties of water confined by phospholipid membranes, Frontiers of Physics, 13 (2018) 136801; arXiv:1703.07835v1 [cond-mat.soft] 22 Mar 2017; S. Samatas, C. Calero, F. Martelli and G. Franzese, Water between membranes: Structure and Dynamics.
    arXiv:1811.01911v2 [cond-mat.soft] 7 Nov 2018; F. Martelli, J. Crain and G. Franzese. Network topology in water nanoconfined between phospholipid membranes, ACS Nano14 (2020) 8616-8623; F. Martelli, C. Calero and G. Franzese, Re-defining the concept of hydration water in water under soft confinement, arXiv:2101.06136v1 [cond-mat.soft] 15 Jan 2021; F. Martelli, C. Calero and G. Franzese, Redefining the concept of hydration water near soft interfaces, Biointerphases, 16 (2021) 020801. [Back]
  64. M. Dinpajooh, D. R. Martin and D. V. Matyushov, Polarizability of the active site of cytochrome c reduces the activation barrier for electron transfer, Science Reports 6 (2016) 28152. [Back]
  65. T. P. Silverstein and S T. Heller, pKa values in the undergraduate curriculum: What Is the real pKa of water? Journal of Chemical Education, 94 (2017) 690-695. [Back, 2, 3
  66. R. Starkey, J. Norman and M. Hime, Who knows the Ka values of water and the hydronium ion? Journal of Chemical Education, 63 (1986), 473-474. [Back]
  67. E. C. Meister, M. Willeke, W. Angst, A. Tognia and P. Walde, Confusing quantitative descriptions of BrønstedLowry acidbase equilibria in chemistry textbooks – A critical review and clarifications for chemical educators, Helvetica Chim. Acta 97 (2014) 1-31. [Back, 2]
  68. S. Lemke, P. H. Handle, L. J. Plaga, J. N. Stern, M. Seidl, V. Fuentes-Landete, K. Amann-Winkel, K. W. Köster, C. Gainaru, T. Loerting and R. Böhmer, Relaxation dynamics and transformation kinetics of deeply supercooled water: Temperature, pressure, doping and proton/deuteron isotope effects, Journal of Chemical Physics,147 (2017) 034506. [Back]
  69. A. Hudait, M. T. Allen and V. Molinero, Sink or swim: ions and organics at the ice-air interface, Journal of the American Chemical Society, 139 (2017) 10095-10103. [Back]
  70. R. Böhmer, K. L. Ngai, C. A. Angell and D. J. Plazek, Nonexponential relaxations in strong and fragile glass formers, Journal of Chemical Physics,99 (1993) 4201-4209. [Back]
  71. A. L. Agapov, A. I. Kolesnikov, V. N. Novikov, R. Richert and A. P. Sokolov, Quantum effects in the dynamics of deeply supercooled water, Physical Review, E 91 (2015) 0223. [Back]
  72. J.-J. Max, P. Larouche and C. Chapados, Orthogonalyzed H2O and D2O species obtained from infrared spectra of liquid water at several temperatures, Journal of Molecular Structure, 1149 (2017) 457-472. [Back, 2]
  73. J. M. D. Coey, M. Möbius, A. J. Gillen and S. Sen, Generation and stability of freestanding aqueous microbubbles
    Electrochemistry Communications, 76 (2017) 38-41. [Back]
  74. V. Bianco, G. Franzese, C. Dellago and I. Coluzza, Role of water in the selection of stable proteins at ambient and extreme thermodynamic conditions, Physical Review, X 7 (2017) 021047. [Back]
  75. A. Pica and G. Graziano, Shedding light on the extra thermal stability of thermophilic proteins, Biopolymers 105 (2016) 856-863. [Back] [Back to Top to top of page]
  76. A. E. Gleason, C. A. Bolme, E. Galtier, H. J. Lee, E. Granados, D. H. Dolan, C. T. Seagle, T. Ao, S. Ali, A. Lazicki, D. Swift, P. Celliers and W. L. Mao, Compression freezing kinetics of water to ice VII, Physical Review Letters 119 (2017) 025701; J. Wenz, Hot ice could have seeded life on Earth, New Scientist 22 July (2017) 9. [Back]
  77. C. Fang and R. Qiao, Surface hydration drives rapid water imbibition into strongly hydrophilic nanopores. Physical Chemistry Chemical Physics, 19 (2017) 20506-20512. [Back]
  78. R. Guerrero-Avilés and W Orellana, Energetics and diffusion of liquid water and hydrated ions through nanopores in graphene: ab initio molecular dynamics simulation, Physical Chemistry Chemical Physics, 19 (2017) 20551-20558. [Back, 2]
  79. N. Sakashita, H. C. Watanabe, T. Ikeda, K. Saito and H. Ishikita, Origins of water molecules in the photosystem II crystal structure, Biochemistry56 (2017) 3049-3057. [Back]
  80. J. Li, A. D. Celiz, J. Yang, Q. Yang, I. Wamala, W. Whyte, B. R. Seo, N. V. Vasilyev, J. J. Vlassak, Z. Suo, Tough adhesives for diverse wet surfaces, Science, 357 (2017) 378-381. [Back]
  81. P. Zhang, J. Li, L. Lv, Y. Zhao and Liangti Qu, Vertically aligned graphene sheets membrane for highly efficient solar thermal generation of clean water, ACS Nano, 11 (2017) 5087-5093; G. Prando, A steam nanogenerator, Nature, Nanotechn. 12 (2017) 506. [Back]
  82. C. Pérez, A. L. Steber, A. M. Rijs, B. Temelso, G. C. Shields, J. C. Lopez, Z. Kisiel and M. Schnell, Corannulene and its complex with water: a tiny cup of water, Physical Chemistry Chemical Physics, 19 (2017) 14214-14223. [Back]
  83. L. Betti, G. Trebbi, M. O. Kokornaczyk, D. Nani, M. Peruzzi, G. Dinelli, P. Bellavite and M. Brizzi, Number of succussion strokes affects effectiveness of ultra-high-diluted arsenic on in vitro wheat germination and polycrystalline structures obtained by droplet evaporation method, Homeopathy, 106 (2017) 47-54. [Back]
  84. Y. Tao, W. Zou and E. Kraka, Strengthening of hydrogen bonding with the push-pull effect, Chemical Physics Letters, 685 (2017) 251-258. [Back]
  85. S. Indra and S. Daschakraborty, Mechanism of translational jump of a hydrophobic solute in supercooled water: Importance of presolvation, Chemical Physics Letters, 685 (2017) 322-327. [Back]
  86. R. Govindarajan, K. Chatterjee, L. Gatlin, R. Suryanarayanan and E. V. Shalaev, Impact of freeze-drying on ionization of sulfonephthalein probe molecules in trehalose-citrate systems, J. Pharmaceutical Sciences, 95 (2006) 1498-1510. [Back]
  87. L. Vetráková, V. Vykoukal and D. Heger, Comparing the acidities of aqueous frozen, and freeze-dried phosphate
    buffers: Is there a “pH Memory” effect?. International Journal of Pharmaceutics, 530 (2017) 316-325. [Back]
  88. H. Jia, China opens up new energy front as it succeeds in tapping gas hydrates, Chemistry World, 14(8) (2017) 12. [Back]
  89. F. Dahms, B. P. Fingerhut, E. T. J. Nibbering, E. Pines and T. Elsaesser, Large-amplitude transfer motion of hydrated excess protons mapped by ultrafast 2D IR spectroscopy, Science, 357 (2017) 491-495; F. Dahms, R. Costard, E. Pines, B. P. Fingerhut, E. T. J. Nibbering and T. Elsaesser, The hydrated excess proton in the Zundel cation H5O2+: The role of ultrafast solvent fluctuations, Angewandte Chemie International Edition, 55 (2016) 10600-10605. [Back]
  90. J. A. Flores-Livas, A. Sanna, M. Graužinytė, A. Davydov, S. Goedecker and M. A. L. Marques, Emergence of superconductivity in doped H2O ice at high pressure, Science Reports, 7 (2016) 6825; arXiv:1610.04110 [cond-mat.supr-con] (2017). [Back]
  91. B. Lian, S. De Luca, Y. You, S. Alwarappan, M. Yoshimura, V. Sahajwalla, S.C. Smith, G. Leslie and R.K. Joshi, Extraordinary water adsorption characteristics of graphene oxide, arXiv:1707.09502v1 [cond-mat.mtrl-sci] (2017). [Back]
  92. N. Giovambattista, F. W. Starr and P. H. Poole, Infuence of sample preparation on the transformation of low-density to high-density amorphous ice: An explanation based on the Potential Energy Landscape, arXiv:1707.09947v1 [cond-mat.stat-mech] 31 Jul 2017. [Back]
  93. V. Holten, C. Qiu, E. Guillerm, M. Wilke, J. Ricka, M. Frenz and F. Caupin, Compressibility anomalies in stretched water and their interplay with density anomalies, Journal of Physical Chemistry Letters, 8 (2017) 5519-5522; arXiv:1708.00063v1 [physics.chem-ph] 31 Jul 2017. [Back, 2]
  94. I. Bakó, A. Lábas, K. Hermansson, Á. Bencsura and J. Oláh, How can we detect hydrogen bond local cooperativity in liquid water: A simulation study, Journal of Molecular Liquids, 245 (2017) 140-146. [Back]
  95. R. J. Speedy, Limiting forms of the thermodynamic divergences at the conjectured stability limits in superheated and supercooled water. Journal of Physical Chemistry, 86 (1982) 3002-3005. [Back]
  96. S. Sastry, P. G. Debenedetti, F. Sciortino and H. E. Stanley, Singularity-free interpretation of the thermodynamics of supercooled water. Physical Review, E. 53 (1996):6144-6154. [Back]
  97. R. Kumar, J. R. Schmidt and J. L. Skinner, hydrogen bonding definitions and dynamics in liquid water, Journal of Chemical Physics, 126 (2007) 204107. [Back]
  98. E. Lang and H. D. Lüdemann, Pressure and temperature dependence of the longitudinal proton relaxation times in supercooled water to −87°C and 2500 bar, Journal of Chemical Physics, 67 (1977) 718-723. [Back]
  99. Y. Tao, W.Zou, J. Jia, W.Li and D. Cremer, The different ways of hydrogen bonding in water - Why does warm water freeze faster than cold water? Journal of Chemical Theory and Computation, 13 (2017) 55-76. [Back, 2]
  100. Y. Ono, R. Futamura, Y. Hattori, T. Sakai and K. Kaneko, Adsorption-desorption mediated separation of low concentrated D2O from water with hydrophobic activated carbon fiber, Journal of Colloid and Interface Science, 508 (2017) 14-17. [Back]  [Back to Top to top of page]



Home | Site Index | Site Map | Search | LSBU | Top


This page was established in 2017 and last updated by Martin Chaplin on 15 September, 2021

Creative Commons License
This work is licensed under a Creative Commons Attribution
-Noncommercial-No Derivative Works 2.0 UK: England & Wales License