Evidence of two distinct local structures of water from ambient to supercooled conditions. - Wikidata - awgldk - TriplyDB

Evidence of two distinct local structures of water from ambient to supercooled conditions.

Evidence of two distinct local structures of water from ambient to supercooled conditions.

http://www.wikidata.org/entity/Q44518819

about

The structural origin of anomalous properties of liquid water The glassy state of crambin and the THz time scale protein-solvent fluctuations possibly related to protein function.Comparison of x-ray absorption spectra between water and ice: new ice data with low pre-edge absorption cross-section.Optical Kerr effect of liquid and supercooled water: the experimental and data analysis perspective.Water: A Tale of Two Liquids.Transduction of DNA information through water and electromagnetic waves.2D-Raman-THz spectroscopy: a sensitive test of polarizable water models.Experimentally probing the libration of interfacial water: the rotational potential of water is stiffer at the air/water interface than in bulk liquid.Viscosity of deeply supercooled water and its coupling to molecular diffusion Two-dimensional Raman-terahertz spectroscopy of water.Critical behavior of a water monolayer under hydrophobic confinement.Electromagnetic information transfer through aqueous system.Pressure dependence of viscosity in supercooled water and a unified approach for thermodynamic and dynamic anomalies of water.Molecular properties of aqueous solutions: a focus on the collective dynamics of hydration water.The trail from quantum electro dynamics to informative medicine.Electromagnetic homeostasis and the role of low-amplitude electromagnetic fields on life organization.Two-structure thermodynamics for the TIP4P/2005 model of water covering supercooled and deeply stretched regions.Exposure to extremely low-frequency magnetic field affects biofilm formation by cystic fibrosis pathogens.Perspective: Echoes in 2D-Raman-THz spectroscopy.THz frequency spectrum of protein-solvent interaction energy using a recurrence plot-based Wiener-Khinchin method.Macro and nano scale modelling of water-water interactions at ambient and low temperature: relaxation and residence times.Femtosecond optical Kerr effect setup with signal "live view" for measurements in the solid, liquid, and gas phases.Notes on simulating two-dimensional Raman and terahertz-Raman signals with a full molecular dynamics simulation approach.Erasing no-man's land by thermodynamically stabilizing the liquid-liquid transition in tetrahedral particles A comparative study on bulk and nanoconfined water by time-resolved optical Kerr effect spectroscopy.Temperature dependence of the Landau-Placzek ratio in liquid water.Electromagnetic-radiation absorption by water.Supercooled and glassy water: Metastable liquid(s), amorphous solid(s), and a no-man's land.Microscopic origin of the fragile to strong crossover in supercooled water: The role of activated processes.Biophysical approach to low back pain: a pilot report.Two-state thermodynamics of the ST2 model for supercooled water.Two-state thermodynamics and the possibility of a liquid-liquid phase transition in supercooled TIP4P/2005 water.Intramolecular structure and energetics in supercooled water down to 255 K.Behavior of supercooled aqueous solutions stemming from hidden liquid-liquid transition in water.Lorentz force in water: evidence that hydronium cyclotron resonance enhances polymorphism.A comprehensive scenario of the thermodynamic anomalies of water using the TIP4P/2005 model.Coherent X-rays reveal the influence of cage effects on ultrafast water dynamics.Molecular polarizability anisotropy of liquid water revealed by terahertz-induced transient orientation.Structure and OH-stretch spectroscopy of low- and high-density amorphous ices Hydration and rotational diffusion of levoglucosan in aqueous solutions

P2860

Q26773884-13A4CDAD-C3AA-4766-A97C-916F47F5282C Q30366377-DBACBD07-FC02-46C9-BF4B-E94B53840CFC Q30838076-FF0AC330-487C-41CD-A135-AF092FFDA5D3 Q30846625-5C3E6825-2BC1-42C8-9E67-CB1C83D48F2F Q33656156-F08073EA-DB5A-4DB0-952B-20FE79573DD8 Q34481767-6F3AA872-3D87-4BC5-BE42-1CBA11239813 Q35422701-925C6A5D-2B41-402C-9691-7632B1EE73AB Q36060673-60D2F5A2-2255-40C6-A21F-5DFB60E528A2 Q36120411-8AD882DC-EA6E-4662-9DC0-7920F9D4FCF7 Q37409413-E1D8F5C7-D440-4B3B-BA98-FB92DAEEBCCA Q38611033-D60A1A92-31A3-49EF-A0F5-A304ACBE6FAD Q38681040-86D77439-BF84-4092-B3D4-917E4C6AF5D2 Q38839472-80BC9D10-8ACC-4670-8FB8-9E3B16BFC003 Q38859840-195F5F33-BB44-4DAA-AF42-758AB407EED8 Q38861281-6374C61F-7CDB-401E-B3E6-F18B8AC51993 Q38892194-C6BA38AE-4413-4DFB-95D4-0EF18F3D5C91 Q39008470-CA64ED5C-3979-4474-A7C2-346BA43CB03D Q39074001-4FE8FFED-0A26-4161-88D8-1C8670CF539A Q39228282-51327A10-E0BC-4FC3-8D48-853C77DA9A80 Q39644236-049BD371-7C12-450C-8677-B7B990769054 Q40092105-E5E8C9B9-D30C-4C26-BEF9-70ABA02D5ABE Q40370556-43582343-6C7A-410B-9325-F0332D260D9A Q41904849-6484BFD9-FBD0-43E2-9C25-4792E5056A93 Q41911482-7D27B132-FD6D-4314-A745-30A311106DCC Q44033454-B1026A17-E8FE-4A21-BEDE-F3B268B434A3 Q47711069-E410AAD8-52A2-4453-AF02-136C1D06AD11 Q47711159-3A93BCDC-65E4-4B21-A3E1-D7A45AD6F784 Q47798841-A3083B7F-7DE7-4C29-9972-94F77CCCF125 Q48178322-B863142F-171F-4BDB-91DB-988222C3B00F Q50961142-DCFA6134-D685-4EAB-B9AA-EF4D35BDECC2 Q51102095-45BD0AC3-28F3-4DA4-A170-9CA664A1F788 Q51369814-BF9BB37E-032C-44DC-97ED-386160290FB2 Q53251966-D3C3A66C-9DD1-44C8-9D27-29552194FF5D Q53263528-693875A0-EAD1-4EDF-9DAD-145DCDCFA95F Q53502800-92B11EEE-5D90-4572-9401-FBB4058B95A4 Q54187741-D5EB1B04-B0B5-4C95-B137-51AF6FB3FDD2 Q55058932-609B3D76-E3A3-4243-936D-0FCCEB158B06 Q55278919-882F2656-A1FB-4465-9A40-C24DAAB91220 Q57164342-CE111A63-EDB6-4193-8185-07612029D942 Q59065084-B8ABA46E-B5B8-43C1-8698-01F55AB2A5B8

P2860

Evidence of two distinct local structures of water from ambient to supercooled conditions.

http://www.wikidata.org/entity/Q44518819

description

2013 nî lūn-bûn

@nan

2013年の論文

@ja

2013年学术文章

@wuu

2013年学术文章

@zh

2013年学术文章

@zh-cn

2013年学术文章

@zh-hans

2013年学术文章

@zh-my

2013年学术文章

@zh-sg

2013年學術文章

@yue

2013年學術文章

@zh-hant

name

Evidence of two distinct local ...... ent to supercooled conditions.

@en

Evidence of two distinct local ...... ent to supercooled conditions.

@nl

type

label

Evidence of two distinct local ...... ent to supercooled conditions.

@en

Evidence of two distinct local ...... ent to supercooled conditions.

@nl

prefLabel

Evidence of two distinct local ...... ent to supercooled conditions.

@en

Evidence of two distinct local ...... ent to supercooled conditions.

@nl

P1433

Q44518819-6B9E6B4D-8FB3-4991-930F-9CF763349EF6

P1476

Q44518819-5ACD2C76-007C-44F7-AFF7-1807E1D7937C

P2093

Q44518819-1662DE4A-0359-4198-806F-8FE17EF2C484

Q44518819-55B15536-8309-48CF-8142-D319D5B263AC

Q44518819-715317FA-6B7B-4924-BB06-540540AC4A10

P2860

Q44518819-1AD2D1AE-C509-4AD5-AFD4-4266CE6E5C50

Q44518819-1FB18412-5C42-4FEA-8FCF-1B44B8DE6CCB

Q44518819-3036EDC9-65F3-4A49-8B87-E3DFD7970F61

Q44518819-4586F57E-B1FA-4E09-BA72-C28956B1A0CA

Q44518819-45AF6851-4687-4715-A20F-B5ACCA937B0F

Q44518819-47C2F791-980A-4369-9358-1B82B1028F93

Q44518819-48C9B6B6-1546-4F60-BA7D-0D7E81EB450B

Q44518819-49E36F26-CF22-452B-A192-617231EFE013

Q44518819-549725CC-0FC6-43F2-938E-EE78D0219AAB

Q44518819-70208CD8-15ED-4631-BB06-6866C916F1E5

P2888

Q44518819-14A15379-155E-4FFD-8CB2-42F2023862B2

P304

Q44518819-7D6D47D3-24D8-4D1F-A762-5B51334BB59C

P31

Q44518819-7CCEF8B7-09B5-4DDA-82C1-6BFA9E45F5B8

P356

Q44518819-4075E424-8ABB-4DD1-B017-75ACD8CC3978

P407

Q44518819-A2DDC201-B221-4D46-A678-A687D914A35C

P478

Q44518819-8F812DB7-6AF0-4AF6-95BF-A5858560470C

P50

Q44518819-6C69FC59-9600-4627-BFED-B273C27D0E0B

Q44518819-B93D4718-6812-4C1D-B878-A596AC060088

P577

Q44518819-CD042D86-AFBD-4290-97F4-920484621E4B

P5875

Q44518819-B9D80955-9573-4FC3-A89C-3A365B1A6763

P698

Q44518819-2A73AA8B-2C8F-4E4C-A10E-01579B214549

P818

Q44518819-DFC4E557-C8B4-4CE5-B569-60FC65725E67

P356

P1433

Nature Communications

P1476

Evidence of two distinct local structures of water from ambient to supercooled conditions

@en

P2093

P Bartolini

http://www.w3.org/2001/XMLSchema#string

R Eramo

http://www.w3.org/2001/XMLSchema#string

R Righini

http://www.w3.org/2001/XMLSchema#string

P2860

Supercooled water relaxation dynamics probed with heterodyne transient grating experiments.

Ultrafast dynamics in complex fluids observed through the ultrafast optically-heterodyne-detected optical-Kerr-effect (OHD-OKE).

Ultrafast optical kerr effect in liquids and solids.

Structural transformation in supercooled water controls the crystallization rate of ice.

Increasing correlation length in bulk supercooled H2O, D2O, and NaCl solution determined from small angle x-ray scattering.

Evidence of the existence of the low-density liquid phase in supercooled, confined water.

Growing correlation length in supercooled water.

Insights into phases of liquid water from study of its unusual glass-forming properties.

Nanoscale dynamics of phase flipping in water near its hypothesized liquid-liquid critical point.

Relaxation processes in an epoxy resin studied by time-resolved optical Kerr effect.

P2888

P304

2401

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P356

10.1038/NCOMMS3401

http://www.w3.org/2001/XMLSchema#string

P407

P478

4

http://www.w3.org/2001/XMLSchema#string

P50

P577

2013-01-01T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P5875

256540722

http://www.w3.org/2001/XMLSchema#string

P698

24029922

http://www.w3.org/2001/XMLSchema#string

P818

1304.2877

http://www.w3.org/2001/XMLSchema#string