Abstract
The high carbon dioxide emission levels due to the increased consumption of fossil fuels has led to various environmental problems. Efficient strategies for the capture and storage of greenhouse gases, such as carbon dioxide are crucial in reducing their concentrations in the environment. Considering this, herein, three novel heteroatom-doped porous-organic polymers (POPs) containing phosphate units were synthesized in high yields from the coupling reactions of phosphate esters and 1,4-diaminobenzene (three mole equivalents) in boiling ethanol using a simple, efficient, and general procedure. The structures and physicochemical properties of the synthesized POPs were established using various techniques. Field emission scanning electron microscopy (FESEM) images showed that the surface morphologies of the synthesized POPs were similar to coral reefs. They had grooved networks, long range periodic macropores, amorphous surfaces, and a high surface area (SBET = 82.71–213.54 m2/g). Most importantly, they had considerable carbon dioxide storage capacity, particularly at high pressure. The carbon dioxide uptake at 323 K and 40 bar for one of the POPs was as high as 1.42 mmol/g (6.00 wt %). The high carbon dioxide uptake capacities of these materials were primarily governed by their geometries. The POP containing a meta-phosphate unit leads to the highest CO2 uptake since such geometry provides a highly distorted and extended surface area network compared to other POPs.
Highlights
The high consumption of fossil fuels in power plants, automobiles, and various human activities contributes to the dramatically increasing level of carbon dioxide (CO2 ) in the atmosphere [1]
The aim of the current work was to synthesis novel porous-organic polymers (POPs) containing phosphate units using a simple and general procedure to be used as potential media for CO2 storage
Fourier-transform infrared (FT-IR) spectra in the range 400–4000 cm–1 were recorded on an 8300 Shimadzu FT-IR spectrophotometer (Tokyo, Japan)
Summary
The high consumption of fossil fuels in power plants, automobiles, and various human activities contributes to the dramatically increasing level of carbon dioxide (CO2 ) in the atmosphere [1]. Fossil fuel contributes to about 60% of greenhouse gas emission [2]. Most of the CO2 emissions (70%) are produced from health production and electricity, agriculture, and industry sectors [3]. The emission of CO2 , in turn, leads to serious environmental and economic problems globally [4,5,6]. The high CO2 level is the main cause of global warming, climate changes, rise in sea and ocean levels, and increased acidity of.
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