@misc{41f3f7ea0690417e9240b7a859bd5907,
title = "CO2 Capture Using Amines Bound to Silica",
abstract = "One of the main culprits of global warming is the increased amount of carbon dioxide, or CO2, in the atmosphere. NASA's global climate reports a 13% increase in atmospheric CO2 from 2000 to present. Adsorptive CO2 capture by nitrogen groups of amine-containing solvents is one of the most mature technologies deployed in petrochemical and natural gas processing plants to purify industrial gases. However, key challenges in widespread application include solvent induced reactor corrosion, amine degradation, and high regeneration energy for repeated cycling. An alternative approach is to immobilize amines on solid supports. Key performance metrics of solid amine-based CO2 adsorbents include the CO2 adsorption capacity and stability to degradation over hundreds of thousands of regeneration cycles. Our research aims to develop descriptors for CO2 capture capacity and stability against oxygen-induced degradation for amines bound to porous silica supports using experimental and computational techniques. We experimentally measure the change in CO2-uptake using solid amine adsorbents with varying chemical compositions and exposure to varying gas streams and use high-performance computers to simulate the nature and strength of CO2-adsorption and oxidative degradation reaction mechanisms. Insights from our work can facilitate the development of stable solid amine adsorbents for large-scale CO2 capture processes.",
keywords = "amines, CO2 capture, DFT, silica support",
author = "Neha Mehra and Wilson McNeary and Gabrielle Kliegle and Wade Braunecker and Carrie Farberow",
year = "2024",
language = "American English",
series = "Presented at the STEM Poster Day at the Capitol, 13 March 2024, Denver, Colorado",
publisher = "National Renewable Energy Laboratory (NREL)",
address = "United States",
type = "Other",
}