Alanine at 13.6 GPa and its pressure-induced amorphisation at 15 GPa

Nicholas P. Funnell; William G. Marshall; Simon Parsons

doi:10.1039/c1ce05487b

Alanine at 13.6 GPa and its pressure-induced amorphisation at 15 GPa

Nicholas P. Funnell, William G. Marshall, Simon Parsons

Research output: Contribution to journal › Article › peer-review

Abstract

L-Alanine is the smallest chiral amino acid, crystallising in the space group P2(1)2(1)2(1). By comparison with other amino acids its crystal structure is extremely resilient to pressure, the ambient-pressure crystalline phase persisting until 13.6 GPa. At 15.46 GPa, L-alanine undergoes a reversible transformation to an amorphous phase. Hirshfeld fingerprint analysis and PIXEL calculations show that there is no development of destabilising contacts as pressure increases, so minimisation of volume is the likely driving force for this transition. Void-space analysis suggests that interstitial voids are all but absent in alanine at 13.6 GPa, and further compression is only possible with a change of phase. With the exception of benzene, 15.46 GPa is the highest pressure for which crystal structure data have been obtained for an organic system.

Original language	English
Pages (from-to)	5841-5848
Number of pages	8
Journal	CrystEngComm
Volume	13
Issue number	19
DOIs	https://doi.org/10.1039/c1ce05487b
Publication status	Published - 2011

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abstract = "L-Alanine is the smallest chiral amino acid, crystallising in the space group P2(1)2(1)2(1). By comparison with other amino acids its crystal structure is extremely resilient to pressure, the ambient-pressure crystalline phase persisting until 13.6 GPa. At 15.46 GPa, L-alanine undergoes a reversible transformation to an amorphous phase. Hirshfeld fingerprint analysis and PIXEL calculations show that there is no development of destabilising contacts as pressure increases, so minimisation of volume is the likely driving force for this transition. Void-space analysis suggests that interstitial voids are all but absent in alanine at 13.6 GPa, and further compression is only possible with a change of phase. With the exception of benzene, 15.46 GPa is the highest pressure for which crystal structure data have been obtained for an organic system.",

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N2 - L-Alanine is the smallest chiral amino acid, crystallising in the space group P2(1)2(1)2(1). By comparison with other amino acids its crystal structure is extremely resilient to pressure, the ambient-pressure crystalline phase persisting until 13.6 GPa. At 15.46 GPa, L-alanine undergoes a reversible transformation to an amorphous phase. Hirshfeld fingerprint analysis and PIXEL calculations show that there is no development of destabilising contacts as pressure increases, so minimisation of volume is the likely driving force for this transition. Void-space analysis suggests that interstitial voids are all but absent in alanine at 13.6 GPa, and further compression is only possible with a change of phase. With the exception of benzene, 15.46 GPa is the highest pressure for which crystal structure data have been obtained for an organic system.

AB - L-Alanine is the smallest chiral amino acid, crystallising in the space group P2(1)2(1)2(1). By comparison with other amino acids its crystal structure is extremely resilient to pressure, the ambient-pressure crystalline phase persisting until 13.6 GPa. At 15.46 GPa, L-alanine undergoes a reversible transformation to an amorphous phase. Hirshfeld fingerprint analysis and PIXEL calculations show that there is no development of destabilising contacts as pressure increases, so minimisation of volume is the likely driving force for this transition. Void-space analysis suggests that interstitial voids are all but absent in alanine at 13.6 GPa, and further compression is only possible with a change of phase. With the exception of benzene, 15.46 GPa is the highest pressure for which crystal structure data have been obtained for an organic system.

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Alanine at 13.6 GPa and its pressure-induced amorphisation at 15 GPa

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