S. Saravanan scite author profile

Large-scale carbon fixation requires high-volume chemicals production from carbon dioxide. Dry reforming of methane could provide an economically feasible route if coke- and sintering-resistant catalysts were developed. Here, we report a molybdenum-doped nickel nanocatalyst that is stabilized at the edges of a single-crystalline magnesium oxide (MgO) support and show quantitative production of synthesis gas from dry reforming of methane. The catalyst runs more than 850 hours of continuous operation under 60 liters per unit mass of catalyst per hour reactive gas flow with no detectable coking. Synchrotron studies also show no sintering and reveal that during activation, 2.9 nanometers as synthesized crystallites move to combine into stable 17-nanometer grains at the edges of MgO crystals above the Tammann temperature. Our findings enable an industrially and economically viable path for carbon reclamation, and the “Nanocatalysts On Single Crystal Edges” technique could lead to stable catalyst designs for many challenging reactions.

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Precious metal recovery from electronic waste by a porous porphyrin polymer

Hong

Thirion

Saravanan

et al. 2020

Proc. Natl. Acad. Sci. U.S.A.

191

111

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Urban mining of precious metals from electronic waste, such as printed circuit boards (PCB), is not yet feasible because of the lengthy isolation process, health risks, and environmental impact. Although porous polymers are particularly effective toward the capture of metal contaminants, those with porphyrin linkers have not yet been considered for precious metal recovery, despite their potential. Here, we report a porous porphyrin polymer that captures precious metals quantitatively from PCB leachate even in the presence of 63 elements from the Periodic Table. The nanoporous polymer is synthesized in two steps from widely available monomers without the need for costly catalysts and can be scaled up without loss of activity. Through a reductive capture mechanism, gold is recovered with 10 times the theoretical limit, reaching a record 1.62 g/g. With 99% uptake taking place in the first 30 min, the metal adsorbed to the porous polymer can be desorbed rapidly and reused for repetitive batches. Density functional theory (DFT) calculations indicate that energetically favorable multinuclear-Au binding enhances adsorption as clusters, leading to rapid capture, while Pt capture remains predominantly at single porphyrin sites.

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A review of natural polysaccharides for drug delivery applications: Special focus on cellulose, starch and glycogen

Gopinath

Saravanan

Al-Maleki

et al. 2018

Biomedicine & Pharmacotherapy

232

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Highly Efficient Catalytic Cyclic Carbonate Formation by Pyridyl Salicylimines

Saravanan

Park

Byun

et al. 2018

ACS Appl. Mater. Interfaces

116

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Cyclic carbonates as industrial commodities offer a viable nonredox carbon dioxide fixation, and suitable heterogeneous catalysts are vital for their widespread implementation. Here, we report a highly efficient heterogeneous catalyst for CO addition to epoxides based on a newly identified active catalytic pocket consisting of pyridine, imine, and phenol moieties. The polymeric, metal-free catalyst derived from this active site converts less-reactive styrene oxide under atmospheric pressure in quantitative yield and selectivity to the corresponding carbonate. The catalyst does not need additives, solvents, metals, or co-catalysts, can be reused at least 10 cycles without the loss of activity, and scaled up easily to a kilogram scale. Density functional theory calculations reveal that the nucleophilicity of pyridine base gets stronger due to the conjugated imines and H-bonding from phenol accelerates the reaction forward by stabilizing the intermediate.

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Catalytic Non-redox Carbon Dioxide Fixation in Cyclic Carbonates

Saravanan

Oppenheim

Kim

et al. 2019

Chem

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Yavuz and colleagues introduced a highly active catalyst for non-redox fixation of CO 2 into cyclic carbonates, a versatile product family with potential use in green polymers and solvents. The metal-free, heterogeneous imidazolinium network structure is easily made, scaled up, recycled, and inexpensive and provides quantitative selectivity and conversion yields over a wide substrate scope of epoxides.

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S. Saravanan

Dry reforming of methane by stable Ni–Mo nanocatalysts on single-crystalline MgO

Precious metal recovery from electronic waste by a porous porphyrin polymer

A review of natural polysaccharides for drug delivery applications: Special focus on cellulose, starch and glycogen

Highly Efficient Catalytic Cyclic Carbonate Formation by Pyridyl Salicylimines

Catalytic Non-redox Carbon Dioxide Fixation in Cyclic Carbonates

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