Scanning Electron Microscopy investigations of laboratory-grown gas clathrate hydrates formed from melting ice, and comparison to natural hydrates

Abstract Scanning electron microscopy (SEM) was used to investigate grain texture and pore structure development within various compositions of pure sI and sII gas hydrates synthesized in the laboratory, as well as in natural samples retrieved from marine (Gulf of Mexico) and permafrost (NW Canada) settings. Several samples of methane hydrate were also quenched after various extents of partial reaction for assessment of mid-synthesis textural progression. All laboratory-synthesized hydrates were grown under relatively high-temperature and high-pressure conditions from rounded ice grains with geometrically simple pore shapes, yet all resulting samples displayed extensive recrystallization with complex pore geometry. Growth fronts of mesoporous methane hydrate advancing into dense ice reactant were prevalent in those samples quenched after limited reaction below and at the ice point. As temperatures transgress the ice point, grain surfaces continue to develop a discrete “rind” of hydrate, typically 5 to 30 μm thick. The cores then commonly melt, with rind microfracturing allowing migration of the melt to adjacent grain boundaries where it also forms hydrate. As the reaction continues under progressively warmer conditions, the hydrate product anneals to form dense and relatively pore-free regions of hydrate grains, in which grain size is typically several tens of micrometers. The prevalence of hollow, spheroidal shells of hydrate, coupled with extensive redistribution of reactant and product phases throughout reaction, implies that a diffusion-controlled shrinking-core model is an inappropriate description of sustained hydrate growth from melting ice. Completion of reaction at peak synthesis conditions then produces exceptional faceting and euhedral crystal growth along exposed pore walls. Further recrystallization or regrowth can then accompany even short-term exposure of synthetic hydrates to natural ocean-floor conditions, such that the final textures may closely mimic those observed in natural samples of marine origin. Of particular note, both the mesoporous and highly faceted textures seen at different stages during synthetic hydrate growth were notably absent from all examined hydrates recovered from a natural marine-environment setting.

[1]  A. Putnis,et al.  The microtexture of analcime phenocrysts in igneous rocks , 1994 .

[2]  J. Pinkston,et al.  Measurement of gas yields and flow rates using a custom flowmeter , 2001 .

[3]  Y. Mori,et al.  Mass transport across clathrate hydrate films : a capillary permeation model , 1997 .

[4]  A. Nur,et al.  Measured temperature and pressure dependence of Vp and Vs in compacted, polycrystalline sI methane and sII methaneethane hydrate , 2003 .

[5]  Bryan C. Chakoumakos,et al.  CO2 hydrate: Synthesis, composition, structure, dissociation behavior, and a comparison to structure I CH4 hydrate , 2003 .

[6]  E. Peltzer,et al.  Dissolution rates of pure methane hydrate and carbon-dioxide hydrate in undersaturated seawater at 1000-m depth , 2004 .

[7]  E. Peltzer,et al.  Dissolution of Hydrocarbon Gas Hydrates in Seawater at 1030-m; Effects of Porosity, Structure, and Compositional Variation as Determined by High-Definition Video and SEM Imaging. , 2002 .

[8]  E. A. Smelik,et al.  Crystal-growth studies of natural gas clathrate hydrates using a pressurized optical cell , 1997 .

[9]  C. Ratcliffe,et al.  Hydrate Layers on Ice Particles and Superheated Ice: a 1H NMR Microimaging Study† , 1999 .

[10]  R. Henning,et al.  Neutron Diffraction Studies of CO2Clathrate Hydrate: Formation from Deuterated Ice , 2000 .

[11]  Stephen H. Kirby,et al.  The strength and rheology of methane clathrate hydrate , 2003 .

[12]  S. Takeya,et al.  In Situ Observation of CO2 Hydrate by X‐ray Diffraction , 2000 .

[13]  W. Waite,et al.  Laboratory synthesis of pure methane hydrate suitable for measurement of physical properties and decomposition behavior , 2000 .

[14]  Stephen H. Kirby,et al.  Polycrystalline Methane Hydrate: Synthesis from Superheated Ice, and Low-Temperature Mechanical Properties , 1998 .

[15]  T. Inoue,et al.  Scientific results from the Mallik 2002 gas hydrate production research well program, Mackenzie Delta, northwest territories, Canada: Preface , 2005 .

[16]  B. Chakoumakos,et al.  Neutron powder diffraction studies as a function of temperature of structure II hydrate formed from propane , 2003 .

[17]  I. Chou,et al.  OPTICAL-CELL EVIDENCE FOR SUPERHEATED ICE UNDER GAS-HYDRATE-FORMING CONDITIONS , 1998 .

[18]  D. Staykova,et al.  Structural studies of gas hydrates , 2003 .

[19]  W. Durham,et al.  Ductile flow of methane hydrate , 2003 .

[20]  V. Altuzar,et al.  Atmospheric pollution profiles in Mexico City in two different seasons , 2003 .

[21]  A. Putnis Mineral replacement reactions: from macroscopic observations to microscopic mechanisms , 2002, Mineralogical Magazine.

[22]  Y. Mori,et al.  Modeling of Simultaneous Heat and Mass Transfer to/from and across a Hydrate Film , 2000 .

[23]  W. Kuhs,et al.  The formation of meso‐ and macroporous gas hydrates , 2000 .

[24]  Doroteya K. Staykova,et al.  Formation of Porous Gas Hydrates from Ice Powders: Diffraction Experiments and Multistage Model , 2003 .

[25]  Xiaoping Wang,et al.  Kinetics of Methane Hydrate Formation from Polycrystalline Deuterated Ice , 2002 .

[26]  Stephen H. Kirby,et al.  The effect of elevated methane pressure on methane hydrate dissociation , 2004 .

[27]  R. Larsen,et al.  NMR Imaging Study of Hydrates in Sediments , 2000 .

[28]  Stephen H. Kirby,et al.  Peculiarities of Methane Clathrate Hydrate Formation and Solid-State Deformation, Including Possible Superheating of Water Ice , 1996, Science.

[29]  W. Durham,et al.  Temperature, pressure, and compositional effects on anomalous or , 2003 .

[30]  Martin R. Lee,et al.  Micropores and micropermeable texture in alkali feldspars: geochemical and geophysical implications , 1995, Mineralogical Magazine.

[31]  B. Chakoumakos,et al.  CO 2 Hydrate : Synthesis , Composition , Structure , Dissociation Behavior , and a Comparison to Structure I CH 4 Hydrate , 2022 .

[32]  Timothy J Kneafsey,et al.  Use of computed X-ray tomographic data for analyzing the thermodynamics of a dissociating porous sand/hydrate mixture , 2002 .

[33]  C. Ruppel,et al.  Thermal Conductivity Measurements in Porous Mixtures of Methane Hydrate and Quartz Sand , 2002 .

[34]  J. Ripmeester,et al.  Nucleation and Growth of Hydrates on Ice Surfaces: New Insights from 129Xe NMR Experiments with Hyperpolarized Xenon , 2001 .

[35]  T. Uchida,et al.  Dissociation of Natural Gas Hydrates Observed by X‐ray CT Scanner , 2000 .

[36]  Jun Mikami,et al.  Occurrences of Natural Gas Hydrates beneath the Permafrost Zone in Mackenzie Delta: Visual and X‐ray CT Imagery , 2000 .