Skip to main navigation
Skip to search
Skip to main content
Arizona State University Home
Home
Profiles
Departments and Centers
Scholarly Works
Activities
Equipment
Grants
Datasets
Prizes
Search by expertise, name or affiliation
A general binary isotherm model for amines interacting with CO
2
and H
2
O
Yuta Kaneko,
Klaus S. Lackner
Engineering, Ira A. Fulton Schools of (IAFSE)
Research output
:
Contribution to journal
›
Article
›
peer-review
2
Scopus citations
Overview
Fingerprint
Fingerprint
Dive into the research topics of 'A general binary isotherm model for amines interacting with CO
2
and H
2
O'. Together they form a unique fingerprint.
Sort by
Weight
Alphabetically
Keyphrases
Amines
100%
Secondary Amines
100%
Isotherm Models
100%
Binary Adsorption Isotherms
100%
Quaternary Ammonium Salt
75%
CO2 Sorption
75%
Aqueous Alkaline Solution
75%
Strong Base
50%
Isotherm
50%
Tertiary Amine
50%
Water Activity
50%
Primary Amines
50%
Isotherm Equations
50%
Aqueous Ammonia
50%
Design Process
25%
Global Warming
25%
CO2 Capture
25%
Theoretical Understanding
25%
CO2 Emissions
25%
Anion Exchange
25%
Analytical Model
25%
Functional Groups
25%
Weak Base
25%
Drastic Change
25%
Formaldehyde
25%
Design Understanding
25%
CO2 Uptake Capacity
25%
Polymer Resin
25%
Absorption Behavior
25%
Industrial Importance
25%
Toth Model
25%
Solid Amine
25%
Aqueous Amine
25%
Engineering
Alkaline Solution
100%
Stronger Base
66%
Secondary Amine
66%
Empirical Model
33%
Carbon Dioxide Capture
33%
Analytical Model
33%
Process Design
33%
Global Warming
33%
Functional Group
33%
Drastic Change
33%
Ion Exchange
33%
Chemical Engineering
Carbon Dioxide
100%
Isotherm Models
100%
Functional Group
14%
Carbon Dioxide Capture
14%
Anion Exchange
14%
Biochemistry, Genetics and Molecular Biology
Solution and Solubility
100%
Absorption
50%
Quantitative Technique
25%
Process Design
25%
Ion Exchange
25%
Earth and Planetary Sciences
Carbon Dioxide
100%
Carbon Dioxide Emission
16%
Global Warming
16%
Carbon Dioxide Capture
16%
Ion Exchange
16%
Material Science
Carbon Dioxide
100%