Enhancement and maximum in the isobaric specific-heat capacity measurements of deeply supercooled water using ultrafast calorimetry
Fysikalisk kemi
0303 health sciences
Supercooled water
ICE
ENTROPY
liquid-liquid critical point
REGIONS
Physical Chemistry
7. Clean energy
COMPRESSIBILITY
03 medical and health sciences
TEMPERATURE-DEPENDENCE
Specific-heat capacity
Fragile-to-strong transition
Liquid-liquid critical point
13. Climate action
fragile-to-strong transition
Physical Sciences
specific-heat capacity
LIQUID TRANSITION
BEHAVIOR
supercooled water
DOI:
10.1073/pnas.2018379118
Publication Date:
2021-02-01T23:36:58Z
AUTHORS (19)
ABSTRACT
Significance
The importance of molecular understanding of the structure, dynamics. and properties of liquid water is recognized in many scientific disciplines. Here, we study experimentally the structure and thermodynamics of bulk liquid water as it is supercooled by evaporation down to ∼228 K. The unique aspect of this work is the use of ultrafast calorimetry that enables us to determine the specific-heat capacity of water to unprecedentedly low temperatures. The observed maximum of about 218 J/mol/K at 229 K is consistent with the liquid–liquid critical point model and supports a proposed fragile-to-strong transition at ∼220 K to explain the steep decrease in the estimated self-diffusion coefficient below 235 K.
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CITATIONS (49)
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