Quantum mechanical study of chemical reactivity of graphene doped with iron in aqueous medium for applications in biomedicine

“…Since the observation of graphene with two‐dimensional honeycomb lattice structure by mechanical stripping of graphite in 2004, [1,2] graphene has been attracted much attention due to its high specific surface area, superior mechanical strength, prominent thermal and electrical conductivities [3,4] . Graphene has wide applications across fields of supercapacitors, [5] composites, [6] catalyst, [7] corrosion preventions, [8] biosensors, [9] and biomedicine [10] . During the past decades, strategies to produce graphene include: mechanical or ultrasonic exfoliation, [11] laser irradiation, [12] microbial reduction, [13] chemical vapor deposition (CVD), [14] solvothermal reduction, [15] and chemical reduction of dispersed graphene oxide (GO) [16] .…”

“…[3,4] Graphene has wide applications across fields of supercapacitors, [5] composites, [6] catalyst, [7] corrosion preventions, [8] biosensors, [9] and biomedicine. [10] During the past decades, strategies to produce graphene include: mechanical or ultrasonic exfoliation, [11] laser irradiation, [12] microbial reduction, [13] chemical vapor deposition (CVD), [14] solvothermal reduction, [15] and chemical reduction of dispersed graphene oxide (GO). [16] Of all the synthesis methods, the chemical reduction is deemed to be one the most economical approaches with potential production in full-scale.…”

A Green Method to Prepare a Highly Concentrated Reduced Graphene Oxide (RGO) Dispersion and Its Anti‐Ultraviolet Radiation Property in RGO‐Modified Cotton Fabric

“…Since the observation of graphene with two‐dimensional honeycomb lattice structure by mechanical stripping of graphite in 2004, [1,2] graphene has been attracted much attention due to its high specific surface area, superior mechanical strength, prominent thermal and electrical conductivities [3,4] . Graphene has wide applications across fields of supercapacitors, [5] composites, [6] catalyst, [7] corrosion preventions, [8] biosensors, [9] and biomedicine [10] . During the past decades, strategies to produce graphene include: mechanical or ultrasonic exfoliation, [11] laser irradiation, [12] microbial reduction, [13] chemical vapor deposition (CVD), [14] solvothermal reduction, [15] and chemical reduction of dispersed graphene oxide (GO) [16] .…”

“…[3,4] Graphene has wide applications across fields of supercapacitors, [5] composites, [6] catalyst, [7] corrosion preventions, [8] biosensors, [9] and biomedicine. [10] During the past decades, strategies to produce graphene include: mechanical or ultrasonic exfoliation, [11] laser irradiation, [12] microbial reduction, [13] chemical vapor deposition (CVD), [14] solvothermal reduction, [15] and chemical reduction of dispersed graphene oxide (GO). [16] Of all the synthesis methods, the chemical reduction is deemed to be one the most economical approaches with potential production in full-scale.…”

A Green Method to Prepare a Highly Concentrated Reduced Graphene Oxide (RGO) Dispersion and Its Anti‐Ultraviolet Radiation Property in RGO‐Modified Cotton Fabric

DFT study of carbaryl pesticide adsorption on vacancy and nitrogen-doped graphene decorated with platinum clusters