Pressure-driven phase transition mechanisms revealed by quantum chemistry: l-serine polymorphs

The present study delivers a computational approach for the understanding of the mechanism of phase transitions between polymorphs of small organic molecules. By using state of the art periodic DFT calculations augmented with dispersion corrections and an external stress tensor together with gas-pha...

Full description

Saved in:
Bibliographic Details
Published in:Physical chemistry chemical physics : PCCP 2017-03, Vol.19 (9), p.6671-6676
Main Authors: Rychkov, Denis A, Stare, Jernej, Boldyreva, Elena V
Format: Article
Language:English
Subjects:
Atomic force microscopy
Chemical bonds
Crystals
Enthalpy
Mathematical models
Organic chemistry
Phase transformations
Quantum chemistry
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The present study delivers a computational approach for the understanding of the mechanism of phase transitions between polymorphs of small organic molecules. By using state of the art periodic DFT calculations augmented with dispersion corrections and an external stress tensor together with gas-phase cluster calculations, we thoroughly explained the reversible phase transitions of three polymorphs of the model system, namely crystalline l-serine in the pressure range up to 8 GPa. This study has shown that at the macroscopic level the main driving force of the phase transitions is the decrease in the volume of the crystal unit cell, which contributes to the enthalpy difference between the two forms, but not to the difference in their internal crystal energies. At the microscopic level we suggest that hydrogen bond overstrain leads to a martensitic-like, cooperative, displacive phase transition with substantial experimental hysteresis, while no such overstrain was found for the "normal type", atom per atom, reconstructive phase transition. The predicted pressures for the phase transitions deducted by the minimum enthalpy criterion are in reasonable agreement with the observed ones. By delivering unambiguous explanations not provided by previous studies and probably not accessible to experiment, this work demonstrates the predictive and explanatory power of quantum chemistry, confirming its indispensable role in structural studies.
ISSN:1463-9076
1463-9084
DOI:10.1039/c6cp07721h