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Harnessing the structural attributes of NiMg-CUK-1 MOF for the dual-function capture and transformation of carbon dioxide into methane

Abstract

Carbon capture and conversion into chemical fuels are often considered distinct processes, whereby a sorbent is responsible for enriching a CO2 stream while a catalyst facilitates transformation into value-added commodities. Herein, we implement NiMg-CUK-1, a metal-organic framework (MOF) possessing the characteristics of both adsorbent and catalyst for the sequential capture and conversion of CO2 to methane (CH4). By harnessing the disparity in thermal stability between Ni-and Mg-CUK-1 analogues, Ni nanoparticles are preferentially generated throughout the preserved Mg portion of the framework. Tuning the Ni:Mg ratio and the NiMg-CUK-1 treatment temperature maximizes catalytic performance while preserving a substantial portion of the CO2 capture func-tionality inherent to the MOF. The optimized NiMg-CUK-1 is deployed in a dual-mode reactor system that al-ternates between ambient temperature CO2 capture and methanation under mild reaction conditions (250 degrees C). After five cycles, the optimal NiMg-CUK-1 reaches a levelled-out performance of 1.46 +/- 0.24 mmol CO2 captured g- 1, and 1.52 +/- 0.23 mmol CH4 produced g- 1, surpassing similar sorbent-based catalysts reliant on the chemical looping of metal oxides and carbonates. The introduced approach paves the way for combined capture and conversion of CO2 using a single dual-functional material capable of both low-temperature CO2 desorption and CH4 production.

article Article

date_range 2023

language English

link Link of the paper

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Zurrer Timothy

Lovell Emma

Han Zhaojun

Liang Kang

Scott Jason

Amal Rose

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Featured Keywords

Carbon capture and utilization

Chemical fuels

Carbon dioxide removal

CO2 hydrogenation

Metal-organic framework

Dual functional material

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Assessment of reinforced concrete building damages following the Kahramanmaraş earthquakes in Malatya, Turkey (February 6, 2023)

Abstract

Earthquakes of magnitude Mw = 7.7 and Mw = 7.6 hit the city of Kahramanmaraş (Turkey) on 6 February 2023. These earthquakes caused serious damage in 11 provinces in Turkey resulting in over 50,000 deaths and huge economic losses with the collapse of thousands of buildings. Two consecutive devastating earthquakes have severely damaged the reinforced concrete building stock located in Malatya. There are many reasons reinforced concrete structures suffer damage under the influence of seismic loads. These reasons can be listed as material and section properties that do not comply with earthquake codes, workmanship defects, ground parameters that are not considered and design errors, as seen in field investigations after earthquakes in Turkey in the past. In this research, a field study was conducted on reinforced concrete buildings damaged after the earthquakes in Malatya province. The causes of structural damages in reinforced concrete buildings between 6–26 years of age were assessed in terms of design and material defects. The structural damages were mainly caused due to insufficient stirrups in structural members, short column, strong beam–weak column, failures of infill walls, soft story type collapse, poor concrete quality, and reinforcement corrosion. In addition to the field investigation, the spectrum relationships created using raw acceleration data obtained from DEMP (Disaster and Emergency Management Presidency) stations in Malatya province were compared with the design response spectra.

article Article

date_range 2024

language English

link Link of the paper

Collapsed buildings

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