Methane Hydrate Formation on Hydrophilic Zr<sup>4+</sup>/D-Gel-Coated Surfaces

Methane Hydrate Formation on Hydrophilic Zr<sup>4+</sup>/D-Gel-Coated Surfaces

During the production and transportation of natural gas, hydrate formation and accumulation in pipelines can lead to blockages, resulting in gas leakage, economic losses, and safety hazards. Recently, the development of superhydrophobic antigas hydrate coatings for pipelines has been identified as a...

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Bibliographic Details
Main Author: Cuiping Tang (735149) (author)
Other Authors: Xinqi Liu (187440) (author), Yong Chen (109188) (author), Xiaoya Zang (13987986) (author), Jinan Guan (417708) (author), Deqing Liang (588389) (author)
Published: 2025
Subjects:
Cell Biology
Biotechnology
Ecology
Cancer
Inorganic Chemistry
Space Science
Chemical Sciences not elsewhere classified
nucleation induction period
mitigate pipeline plugging
microscopic observations revealed
water molecules resulted
water molecule ordering
large water layer
hydrate cage structures
although superhydrophobic surfaces
surface water molecules
hydrophilic gel coating
natural gas pipelines
methane hydrate formation
reduce wall adhesion
natural gas
superhydrophobic surfaces
bound water
bonded water
methane hydrate
coating surface
adhesion strength
gas leakage
solid surfaces
coated surfaces
hydrate formation
thereby inhibiting
term stability
study proposes
safety hazards
results showed
resistant coatings
relatively fragile
raman spectroscopy
novel approach
hydrophilic zr
effectively reduce
effective strategy
economic losses
coordinated hydrogen
antiplugging strategies
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Summary:During the production and transportation of natural gas, hydrate formation and accumulation in pipelines can lead to blockages, resulting in gas leakage, economic losses, and safety hazards. Recently, the development of superhydrophobic antigas hydrate coatings for pipelines has been identified as an effective strategy to mitigate pipeline plugging. Although superhydrophobic surfaces can effectively reduce the adhesion strength of hydrates to the wall, they tend to promote surface gas enrichment and water molecule ordering, thereby accelerating hydrate nucleation and growth. Furthermore, the microstructure of superhydrophobic surfaces is relatively fragile and susceptible to damage, which limits their long-term stability and reliability. This study proposes a hydrophilic gel coating, Zr<sup>4+</sup>/DMSO-Gel, which can delay the nucleation induction period of methane hydrates on solid surfaces and reduce their growth rate. Microscopic observations revealed that the coating induced partial decomposition of methane hydrate, resulting in the formation of a large water layer, which can reduce wall adhesion. Furthermore, Raman spectroscopy was employed to analyze the structure of surface water molecules, revealing the mechanism by which the coating inhibits hydrate formation. The results showed that strong hydrogen bonding interactions between the coating surface and water molecules resulted in the predominance of bound water (BW) on the surface, while the proportion of tetra-coordinated hydrogen-bonded water (4-HBW) was reduced, thereby inhibiting the formation of hydrate cage structures. These findings not only provide a novel approach for the development of hydrate-resistant coatings but also offer new insights into antiplugging strategies for natural gas pipelines.

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