Reduced Graphene Oxide/Polymer Monolithic Materials for Selective CO2 Capture.

Nikolaos Politakos,Tomás Cordero-Lanzac,Alba Gonzalez,Ronen Zangi,Iranzu Barbarin,Radmila Tomovska

doi:10.3390/polym12040936

Nikolaos Politakos, Tomás Cordero-Lanzac + Show 4 more

Open Access

https://doi.org/10.3390/polym12040936

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Journal: Polymers	Publication Date: Apr 17, 2020
Citations: 28	License type: CC BY 4.0

Affiliation: University of the Basque Country, Ikerbasque

Abstract

Polymer composite materials with hierarchical porous structure have been advancing in many different application fields due to excellent physico-chemical properties. However, their synthesis continues to be a highly energy-demanding and environmentally unfriendly process. This work reports a unique water based synthesis of monolithic 3D reduced graphene oxide (rGO) composite structures reinforced with poly(methyl methacrylate) polymer nanoparticles functionalized with epoxy functional groups. The method is based on reduction-induced self-assembly process performed at mild conditions. The textural properties and the surface chemistry of the monoliths were varied by changing the reaction conditions and quantity of added polymer to the structure. Moreover, the incorporation of the polymer into the structures improves the solvent resistance of the composites due to the formation of crosslinks between the polymer and the rGO. The monolithic composites were evaluated for selective capture of CO2. A balance between the specific surface area and the level of functionalization was found to be critical for obtaining high CO2 capacity and CO2/N2 selectivity. The polymer quantity affects the textural properties, thus lowering its amount the specific surface area and the amount of functional groups are higher. This affects positively the capacity for CO2 capture, thus, the maximum achieved was in the range 3.56–3.85 mmol/g at 1 atm and 25 °C.

Highlights

One of the major issues humanity is facing is climate change and the ramifications it brings on the whole life on the planet [1,2]
We present a unique latex based technique for the synthesis of composite polymer/graphene monolithic materials for CO2 selective capture
The self-assembly process of graphene oxide (GO) platelets occurring within the polymer latex is a complex hierarchical process, where the interactions between two different types of materials result in the formation of porous sponge-like monolithic composite materials

Summary

Introduction

One of the major issues humanity is facing is climate change and the ramifications it brings on the whole life on the planet [1,2]. Despite all the efforts to develop alternative energy solutions, the majority of the world energy is still supplied from fossil fuel power plants, which cover 85% of the world energy demands and are responsible for an emission of 40% of the CO2 released in the atmosphere [1]. CO2 is one of the major players in the climate change, contributing to 80% of global warming effects [3]. The development of effective technologies to reduce atmospheric CO2 concentration is an urgent and important task to make the transition towards green energy more smoothly [4]. Liquid absorption is the most widely used technology for applications in CCS, both high energy required for regeneration and corrosiveness of amine solution absorbents are the major drawbacks [8]

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