Skip to main navigation
Skip to search
Skip to main content
Penn State Home
Help & FAQ
Home
Researchers
Research output
Research units
Equipment
Grants & Projects
Prizes
Activities
Search by expertise, name or affiliation
An equation-of-state model to predict surfactant/oil/brine-phase behavior
S. Ghosh,
R. T. Johns
John and Willie Leone Department of Energy & Mineral Engineering (EME)
Research output
:
Contribution to journal
›
Article
›
peer-review
69
Scopus citations
Overview
Fingerprint
Fingerprint
Dive into the research topics of 'An equation-of-state model to predict surfactant/oil/brine-phase behavior'. Together they form a unique fingerprint.
Sort by
Weight
Alphabetically
Keyphrases
Brine
100%
Phase Behavior
100%
Surfactant
100%
Equation of State Model
100%
Polymer Flooding
75%
Solubilization Efficiency
75%
Polymeric Surfactant
75%
Atmospheric Pressure
50%
Oil Reservoir
50%
Microemulsion Phase Behavior
50%
Change of Variables
50%
Average Curvature
50%
Curvature Model
50%
Formulation Variables
50%
Winsor III
50%
Temperature Effect
25%
Phase Transition
25%
Pressure Effect
25%
Predictive Ability
25%
Pressure Change
25%
Pressure-temperature
25%
New Factors
25%
Pressure Variation
25%
Behavioral Model
25%
Relative Error
25%
Limited Experimental Data
25%
Flooding Process
25%
Phase Volume
25%
Residual Oil
25%
Chemical Flooding
25%
Microemulsion
25%
Optimum Salinity
25%
Equivalent Alkane Carbon number
25%
Waterflood
25%
Temperature Equivalent
25%
Predictive Approach
25%
State-like
25%
Recovery Prediction
25%
Flood Design
25%
Optimum Formulation
25%
Oil Equivalent
25%
Engineering
State Model
100%
Surfactant
100%
Equations of State
100%
Polymer Flood
50%
Microemulsion
50%
Oil Reservoir
33%
Atmospheric Pressure
33%
Key Parameter
16%
Alkane
16%
Induced Change
16%
Relative Error
16%
Predictive Capability
16%
Chemical Flood
16%
Residual Oil
16%
Oil Equivalent
16%
Material Science
Surface Active Agent
100%
Microemulsions
50%
Solubilization
50%
Chemical Engineering
Surfactant
100%
Microemulsion
50%