Molecular-dynamics simulation of methane-hydrate crystallisation in terahertz electromagnetic fields: Assessment of field intensities

doi:10.1088/1674-1056/ae5474

中国物理B ›› 2026, Vol. 35 ›› Issue (5): 50501-050501.doi: 10.1088/1674-1056/ae5474

Molecular-dynamics simulation of methane-hydrate crystallisation in terahertz electromagnetic fields: Assessment of field intensities

Niall J. English

School of Chemical and Bioprocess Engineering, University College Dublin, Belfield, Dublin 4, Ireland

收稿日期:2026-01-06 修回日期:2026-03-09 出版日期:2026-03-19 发布日期:2026-03-19
通讯作者: Niall J. English E-mail:niall.english@ucd.ie

Molecular-dynamics simulation of methane-hydrate crystallisation in terahertz electromagnetic fields: Assessment of field intensities

Niall J. English

School of Chemical and Bioprocess Engineering, University College Dublin, Belfield, Dublin 4, Ireland

Received:2026-01-06 Revised:2026-03-09 Online:2026-03-19 Published:2026-03-19
Contact: Niall J. English E-mail:niall.english@ucd.ie

摘要/Abstract

摘要： Non-equilibrium molecular dynamics simulations were conducted to study the growth and dissolution of a spherical methane hydrate crystallite, using a polarizable water potential, encircled by a liquid phase of saturated water and methane, both in the microwave to far-infrared range and under applied external electromagnetic (e/m) fields (5 GHz to 7.5 THz) at r.m.s. electric-field strengths of up to the order of 1 V$\cdot$nm$^{-1}$ — in an attempt to assess and model the ''threshold'' field intensities required to initiate hydrate dissolution. The average growth rate of the crystallite in the absence of a field was found to be approximately 0.32 water and 0.045 methane molecules per picosecond. Upon applying e/m fields, deviations from zero-field crystal growth patterns were observed for r.m.s. field strengths, especially at $\sim 1$ V$\cdot$nm$^{-1}$ as a rough 'threshold'. When the water dipole was aligned with the external field, systematic frequency variations were observed, providing a mechanistic rationale for field-coupling effects on dipole direction/magnitude and hydrogen-bonding shifts.

关键词: molecular dynamics, clathrate hydrates, crystallisation, electromagnetic fields

Abstract: Non-equilibrium molecular dynamics simulations were conducted to study the growth and dissolution of a spherical methane hydrate crystallite, using a polarizable water potential, encircled by a liquid phase of saturated water and methane, both in the microwave to far-infrared range and under applied external electromagnetic (e/m) fields (5 GHz to 7.5 THz) at r.m.s. electric-field strengths of up to the order of 1 V$\cdot$nm$^{-1}$ — in an attempt to assess and model the ''threshold'' field intensities required to initiate hydrate dissolution. The average growth rate of the crystallite in the absence of a field was found to be approximately 0.32 water and 0.045 methane molecules per picosecond. Upon applying e/m fields, deviations from zero-field crystal growth patterns were observed for r.m.s. field strengths, especially at $\sim 1$ V$\cdot$nm$^{-1}$ as a rough 'threshold'. When the water dipole was aligned with the external field, systematic frequency variations were observed, providing a mechanistic rationale for field-coupling effects on dipole direction/magnitude and hydrogen-bonding shifts.

Key words: molecular dynamics, clathrate hydrates, crystallisation, electromagnetic fields

中图分类号: (Computational methods in statistical physics and nonlinear dynamics)

05.10.-a

Niall J. English. Molecular-dynamics simulation of methane-hydrate crystallisation in terahertz electromagnetic fields: Assessment of field intensities[J]. 中国物理B, 2026, 35(5): 50501-050501.

Niall J. English. Molecular-dynamics simulation of methane-hydrate crystallisation in terahertz electromagnetic fields: Assessment of field intensities[J]. Chin. Phys. B, 2026, 35(5): 50501-050501.

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Molecular-dynamics simulation of methane-hydrate crystallisation in terahertz electromagnetic fields: Assessment of field intensities

Molecular-dynamics simulation of methane-hydrate crystallisation in terahertz electromagnetic fields: Assessment of field intensities

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