Yong‐Ki Choi scite author profile

Global warming is considered one of the great challenges of the twenty-first century. In order to reduce the ever-increasing amount of methane (CH 4 ) released into the atmosphere, and thus its impact on global climate change, CH 4 storage technologies are attracting significant research interest. CH 4 storage processes are attracting technological interest, and methane is being applied as an alternative fuel for vehicles. CH 4 storage involves many technologies, among which, adsorption processes such as processes using porous adsorbents are regarded as an important green and economic technology. It is very important to develop highly efficient adsorbents to realize techno-economic systems for CH 4 adsorption and storage. In this review, we summarize the nanomaterials being used for CH 4 adsorption, which are divided into non-carbonaceous (e.g., zeolites, metal-organic frameworks, and porous polymers) and carbonaceous materials (e.g., activated carbons, ordered porous carbons, and activated carbon fibers), with a focus on recent research.

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Preparation and characterization of sucrose-based microporous carbons for increasing hydrogen storage

Choi

Park

2015

Journal of Industrial and Engineering Chemistry

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Hydrogen storage capacity of highly porous carbons synthesized from biomass-derived aerogels

Choi¹,

Park²

2015

Carbon letters

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In this work, highly porous carbons were prepared by chemical activation of carbonized biomass-derived aerogels. These aerogels were synthesized from watermelon flesh using a hydrothermal reaction. After carbonization, chemical activation was conducted using potassium hydroxide to enhance the specific surface area and microporosity. The micro-structural properties and morphologies were measured by X-ray diffraction and scanning electron microscopy, respectively. The specific surface area and microporosity were investigated by N 2 /77 K adsorption-desorption isotherms using the Brunauer-Emmett-Teller method and Barrett-Joyner-Halenda equation, respectively. Hydrogen storage capacity was dependent on the activation temperature. The highest capacity of 2.7 wt% at 77 K and 1 bar was obtained with an activation temperature of 900°C.

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Yong‐Ki Choi

Hydrogen storage in sonicated carbon materials

A review: methane capture by nanoporous carbon materials for automobiles

Preparation and characterization of sucrose-based microporous carbons for increasing hydrogen storage

Hydrogen storage capacity of highly porous carbons synthesized from biomass-derived aerogels

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