Publications and Citations Summary

Citation Data:  Sum of the Times Cited: > 290;  h-index : 7

Total Number of Publications: 8

Average impact factor per article: 16.62 (from BS-MS)

Average citation per article: 36

Significant Citations and number of papers: 1 >100 citations, 3 >30 citations

Research Article: 8, Reviews/Perspectives: under review 

Links:  Google Scholar     Research Gate       ORCID       Researcher ID    

Publications

Poster 

Projects

Composite Membrane for Environmental Applications

Advanced porous material has supremacy in terms of flexible framework, and structure-property correlations. Thermal, mechanical, and chemical stability, structure, and geometry will be tuned accordingly, and synthesize of the composite material depending on various applications like gas separation and storage, catalysis, ion sieving, and device fabrication. Hybrid composite materials are represented something of ''holy grail'' and spurred a significant deal of attention due to the creation of unique and multifunctional platforms to achieve desired applications. In virtue of this, for the synthesis of 2D membrane, I have rationally chosen characteristics of MOF, COF, POP cage, polymer, fiber, can result in a unique hybrid composite that will have different functional groups, active site, robust in stability, and superior for environmental applications. I also focus on utilizing Machine Learning algorithms and packages to obtain desired structure-property correlation.

Covalent Organic Framewoks (COFs), Metal Organic Frameworks (MOFs), Mxene and various composite for Li ion / Na ion battery

Metal-organic frameworks (MOFs) and covalent organic frameworks (COFs) as two burgeoning families of crystalline porous materials (CPMs) have been extensively investigated and applied in various fields on account of their enticing features as large surface area, controllable crystalline structure and highly ordered pores/channels. Crystalline porous materials including MOFs and COFs have generated great interest in battery fields (Li/Na ion) because the ordered porous frameworks can offer a fast-ionic transportation and storage path without large volume variation. MOFs and COFs cab be utilized in three main parts of battery, including electrode materials or host materials, solid-state electrolyte and separator.

Porous Materials for contaminated water purification

The global crisis of insufficient availability of clean water that meets the stringent guidelines of different environmental regulatory agencies has risen remarkably. Since the advent of the industrial revolution, human activities have significantly accelerated water pollution that disturbs our Earth's ecosystem. According to the US-based Environmental Protection Agency (EPA), inorganic oxoanions are the primary source of water pollution, among various other pollutants. Most of these toxic water-polluting species mobilize in aquatic environments such as lakes, rivers, oceans, groundwater, etc., making them challenging to filter out even by traditional, commercially available energy-efficient technologies. Unsafe drinking water jeopardises human health, leading to death in its most serious cases, and causes severe environmental contamination. Therefore, remediation of such a class of toxic elements from the contaminated water is paramount to re-establish the planet's ecological balance.

Cu MOFs derived composite for CO2 capture and reduction

Cu MOFs (Metal-Organic Frameworks) derived composites have emerged as promising materials for both CO2 capture and reduction processes. These innovative materials combine the high surface area and tunable pore structures of MOFs with the catalytic properties of copper to efficiently capture and convert carbon dioxide. These composites offer a dual functionality: firstly, they capture CO2 from direct air, and then they catalyze its conversion into valuable products like carbon monoxide and hydrocarbon. This dual-purpose approach makes Cu MOFs derived composites a pivotal player in addressing the urgent challenge of mitigating CO2 emissions while harnessing its potential for sustainable chemical transformations.

© Satyam Saurabh