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Mechanical Properties of Anhydrous and Hydrated Uric Acid Crystals
Fan Liu
, Daniel E. Hooks
, Nan Li
,
Nathan A. Mara
, Jennifer A. Swift
Chemical Engineering and Materials Science
Research output
:
Contribution to journal
›
Article
›
peer-review
56
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Scopus citations
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Keyphrases
Mechanical Properties
100%
Dihydrate
100%
Uric Acid Crystals
100%
Crystal Form
75%
Nanoindentation
25%
High Mass Loading
25%
Crystal Surface
25%
Mechanical Strength
25%
Physical Properties
25%
Crystal Orientation
25%
Layered Structure
25%
Uric Acid
25%
Hydration State
25%
Creep
25%
Axial Stress
25%
Self-healing
25%
Indentation
25%
Load-displacement Curve
25%
Crack Formation
25%
Atomic Force Microscopy Image
25%
Load Force
25%
Atomic Force Microscopy Imaging
25%
Indentation Depth
25%
Slip Plane
25%
Two-dimensional Layer
25%
Molecular Compounds
25%
Layer Direction
25%
Oriented Crack
25%
Engineering
Form Crystal
100%
Atomic Force Microscopy
66%
Indentation
66%
Two Dimensional
33%
Load Displacement Curve
33%
Crack Formation
33%
Creep
33%
Crystallizes
33%
Layer Structure
33%
Slip Plane
33%
Mechanical Stability
33%
Crystal Surface
33%
Material Science
Atomic Force Microscopy
100%
Indentation
100%
Surface (Surface Science)
100%
Nanoindentation
50%
Physical Property
50%
Creep
50%
Crack Formation
50%
Chemistry
Crystal Morphology
100%
Uric Acid
100%
Atomic Force Microscopy
66%
Mechanical Strength
33%
Crack Initiation
33%
Self-Healing
33%