dc.description.abstract |
Carbon dioxide (CO2) is a major heat-trapping gas responsible for global warming
through the greenhouse effect. Anthropogenic activities such as deforestation and burning
fossil fuels account for large-scale CO2 emissions, along with some natural processes such as
respiration and volcanic eruptions. According to the recent report (2017) from NASA, the
atmospheric CO2 concentration is already reaching alarming levels. In fact, the Mid-
Tropospheric CO2 concentration has gone up by 110 ppm (from 365ppm to 475ppm) since
last one and half decade. So, there is a need for developing technologies to reduce the
atmospheric CO2 concentration. Also, this can bring some economic benefits in coal-based
power production. Carbon Capture and Storage (CCS) is the most promising technique for
this purpose. Though the present industrial CO2 capture technology uses liquid amine-based
sorbents, adsorptive separation methods employing solid sorbents are realized to be the most
energy efficient and thereby cost-effective. The large-scale adsorptive separation of CO2 from
industrial gas mixtures is achieved using zeolites, activated carbons, silica gels as sorbents.
With an ever-growing demand for more energy-saving and thereby cost-effective, and
environmentally friendly procedures for gas separation, new-generation sorbents with better
efficiency are required. Metal Organic Frameworks (MOFs), made up of metal ions/metaloxo
clusters connected via organic linkers, have been recognized as well-suited materials for
the application mentioned above. During last decade several reports on gas separation using
both Micro/Ultra-micro porous MOFs have appeared. However, MOFs with ultra-micropores
(< 6 Å) seems to be the most potential candidate for the gas separation applications,
especially for carbon capture. In this context, we have developed few ultra-microporous
MOFs (Um-MOFs) which display very interesting CO2 capture characteristics. For example,
a Um-MOF, Ni9(μ-H2O)4(H2O)2(4-PyC)18(H2O)17(CH3OH)4(C4H8O)4, IISERP-MOF1,
displays the best properties suitable for pre-combustion CO2 capture and H2 purification.
While, another MOF, Ni(4-PyC)2.DMF, IISERP-MOF2, exhibits lowest parasitic energy (655
KJ/kg CO2) when applied for post-combustion CO2 capture. Following this, we have
developed few more 4-PyC based MOFs utilizing Mg, Mn and Cu metal ions. However,
these MOFs are dense as ascertained from the crystal structure. In one of the chapters in my
thesis, we show how porosity can be introduced into such non-porous frameworks by
utilizing coordination flexibility. In another study, we have incorporated different basic
functional moieties (triazolyl, imidazolyl and benzimidazole) to form Um-MOFs and have
investigated the atomic-level details about their adsorption sites using a combined
x
experimental-computational approach. Our investigations include (i) the triazolyl and
imidazolyl functionalized MOFs with hydrophobic methyl group-lined pores for humid CO2
capture; (ii) understanding the adsorption characteristics of MOF simultaneously lined with
strong adsorptions sites of different chemistry. |
en_US |