Enregistré dans:
Détails bibliographiques
Auteurs principaux: Noor, Mohamed Yaseen, Yedigaryan, Aram, Calderon, Gabriel, Tsaturyan, Arshak, Kanchan, Elena, Hwang, Jinwoo, Menoni, Carmen S., Colombier, Jean-Philippe, Chowdhury, Enam
Format: Preprint
Publié: 2026
Sujets:
Accès en ligne:https://arxiv.org/abs/2602.22460
Tags: Ajouter un tag
Pas de tags, Soyez le premier à ajouter un tag!
_version_ 1866908853268905984
author Noor, Mohamed Yaseen
Yedigaryan, Aram
Calderon, Gabriel
Tsaturyan, Arshak
Kanchan, Elena
Hwang, Jinwoo
Menoni, Carmen S.
Colombier, Jean-Philippe
Chowdhury, Enam
author_facet Noor, Mohamed Yaseen
Yedigaryan, Aram
Calderon, Gabriel
Tsaturyan, Arshak
Kanchan, Elena
Hwang, Jinwoo
Menoni, Carmen S.
Colombier, Jean-Philippe
Chowdhury, Enam
contents Ultrafast lasers create extreme, non-equilibrium thermodynamic conditions that can transiently reach pressures and temperatures comparable to interior core of the earth. Here we show that femtosecond excitation of amorphous silica-hafnia multilayer dielectrics drives the formation of high-pressure crystalline phases of silica including stishovite, seifertite, and the pyrite-type high density structure, within confined subsurface regions.Using TEM, SAED, and 4D-STEM, we directly map nanoscale phase evolution and identify crystalline motifs embedded inside laser generated blisters.Complementary molecular dynamics simualtions reveal the thermodynamic pathway underlying these transformations, where rapid electronic pressure initiates densification and octahedral coordination, followed by temperature driven crystallization and displacive transitions during ultrafast quenching. The resulting polymorphs reflects a dual-stage pathway inaccessible under equilibrium processing. Our results establish femtosecond laser excitation as a viable route to synthesize and stabilize ultrahigh-density high pressure silica phases under ambient conditions, without a diamond anvil cell, with implications for laser-damage mechanisms, high-energy-density materials, and planetary physics.
format Preprint
id arxiv_https___arxiv_org_abs_2602_22460
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Mimicking the earth core conditions with ultrafast laser materials interaction
Noor, Mohamed Yaseen
Yedigaryan, Aram
Calderon, Gabriel
Tsaturyan, Arshak
Kanchan, Elena
Hwang, Jinwoo
Menoni, Carmen S.
Colombier, Jean-Philippe
Chowdhury, Enam
Materials Science
Geophysics
Optics
Ultrafast lasers create extreme, non-equilibrium thermodynamic conditions that can transiently reach pressures and temperatures comparable to interior core of the earth. Here we show that femtosecond excitation of amorphous silica-hafnia multilayer dielectrics drives the formation of high-pressure crystalline phases of silica including stishovite, seifertite, and the pyrite-type high density structure, within confined subsurface regions.Using TEM, SAED, and 4D-STEM, we directly map nanoscale phase evolution and identify crystalline motifs embedded inside laser generated blisters.Complementary molecular dynamics simualtions reveal the thermodynamic pathway underlying these transformations, where rapid electronic pressure initiates densification and octahedral coordination, followed by temperature driven crystallization and displacive transitions during ultrafast quenching. The resulting polymorphs reflects a dual-stage pathway inaccessible under equilibrium processing. Our results establish femtosecond laser excitation as a viable route to synthesize and stabilize ultrahigh-density high pressure silica phases under ambient conditions, without a diamond anvil cell, with implications for laser-damage mechanisms, high-energy-density materials, and planetary physics.
title Mimicking the earth core conditions with ultrafast laser materials interaction
topic Materials Science
Geophysics
Optics
url https://arxiv.org/abs/2602.22460