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Molecular Rotations, Multiscale Order, Hyperuniformity, and Signatures of Metastability during the Compression/Decompression Cycles of Amorphous Ices.
Formanek, Maud; Torquato, Salvatore; Car, Roberto; Martelli, Fausto.
Affiliation
  • Formanek M; IBM Research Europe, Hartree Centre, WA4 4AD Daresbury, United Kingdom.
  • Torquato S; Department of Chemistry, Princeton University, Princeton, New Jersey 08544, United States.
  • Car R; Department of Physics, Princeton University, Princeton, New Jersey 08544, United States.
  • Martelli F; Department of Chemistry, Princeton University, Princeton, New Jersey 08544, United States.
J Phys Chem B ; 127(17): 3946-3957, 2023 May 04.
Article in En | MEDLINE | ID: mdl-37039650
We model, via large-scale molecular dynamics simulations, the isothermal compression of low-density amorphous ice (LDA) to generate high-density amorphous ice (HDA) and the corresponding decompression extending to negative pressures to recover the low-density amorphous phase (LDAHDA). Both LDA and HDA are nearly hyperuniform and are characterized by a dynamical HBN, showing that amorphous ices are nonstatic materials and implying that nearly hyperuniformity can be accommodated in dynamical networks. In correspondence with both the LDA-to-HDA and the HDA-to-LDAHDA phase transitions, the (partial) activation of rotational degrees of freedom activates a cascade effect that induces a drastic change in the connectivity and a pervasive reorganization of the HBN topology which, ultimately, break the samples' hyperuniform character. Key to this effect is the rapid rate at which changes occur, and not their magnitude. The inspection of structural properties from the short- to the long-range shows that signatures of metastability are present at all length-scales, hence providing further solid evidence in support of the liquid-liquid critical point scenario. LDA and LDAHDA differ in terms of HBN and structural properties, implying that they are distinct low-density glasses. Our work unveils the role of molecular rotations in the phase transitions between amorphous ices and shows how the unfreezing of rotational degrees of freedom generates a cascade effect that propagates over multiple length-scales. Our findings greatly improve our basic understanding of water and amorphous ices and can potentially impact the field of molecular network-forming materials at large.

Full text: 1 Collection: 01-internacional Database: MEDLINE Type of study: Prognostic_studies Language: En Journal: J Phys Chem B Journal subject: QUIMICA Year: 2023 Document type: Article Affiliation country: United kingdom Country of publication: United States

Full text: 1 Collection: 01-internacional Database: MEDLINE Type of study: Prognostic_studies Language: En Journal: J Phys Chem B Journal subject: QUIMICA Year: 2023 Document type: Article Affiliation country: United kingdom Country of publication: United States