Herein we report the electrocatalytic activity of boron-doped graphene for the reduction of CO2. Electrolysis takes place at low overpotentials leading exclusively to formate as the product (vis-à-vis benchmark Bi catalyst). Computational studies reveal mechanistic details of CO2 adsorption and subsequent conversion to formic acid/formate.
Enhancing
the intrinsic activity of a benchmarked electrocatalyst
such as platinum (Pt) is highly intriguing from fundamental as well
as applied perspectives. In this work, hydrogen evolution reaction
(HER) activity of Pt electrodes, benchmarked HER catalysts, modified
with ultrathin sheets of hexagonal boron nitride (h-BN) is studied
in acidic medium (Pt/h-BN), and augmented HER performance, in terms
of the overpotential at a 10 mA cm–2 current density
(10 mV lower than that of Pt nanoparticles) and a lower Tafel slope
(29 ± 1 mV/decade), of the Pt/h-BN system is demonstrated. The
effects of h-BN surface modification of bulk Pt as well as Pt nanoparticles
are studied, and the origin of such an enhanced HER activity is probed
using density functional theory-based calculations. The HER charge
transfer resistance of h-BN-modified Pt is found to be drastically
reduced, and this enhances the charge transfer kinetics of the Pt/h-BN
system because of the synergistic interaction between h-BN and Pt.
An enormous reduction in the hydrogen adsorption energy on h-BN monolayers
is also found when they are placed over the Pt electrode [−2.51
eV (h-BN) to −0.25 eV (h-BN over Pt)]. Corrosion preventive
atomic layers such as h-BN-protected Pt electrodes that perform better
than Pt electrodes do open possibilities of benchmarked catalysts
by simple modification of a surface via atomic layers.
A single material that can perform water oxidation and oxygen reduction reactions (ORR), also called bifunctional catalyst, represents a novel concept that emerged from recent materials research and that has led to applications in new‐generation energy‐storage systems, such as regenerative fuel cells. Here, metal/metal‐oxide free, doped graphene derived from rhombohedral boron carbide (B4C) is demonstrated to be an effective bifunctional catalyst for the first time. B4C, one of the hardest materials in nature next to diamond and cubic boron nitride, is converted and separated in bulk to form heteroatom (boron, B) doped graphene (BG, yield ≈7% by weight, after the first cycle). This structural conversion of B4C to graphene is accompanied by in situ boron doping and results in the formation of an electrochemically active material from a non‐electrochemically active material, broadening its potential for application in various energy‐related technologies. The electrocatalytic efficacy of BG is studied using various voltammetric techniques. The results show a four‐electron transfer mechanism as well as a high methanol tolerance and stability towards ORR. The results are comparable to those from commercial 20 wt% Pt/C in terms of performance. Furthermore, the bifunctionality of the BG is also demonstrated by its performance in water oxidation.
Although graphene technology has reached technology readiness level 9 and hydrogen fuel has been identified as a viable futuristic energy resource, pristine atomic layers such as graphene are found to be inactive towards the hydrogen evolution reaction (HER). Enhancing the intrinsic catalytic activity of a material and increasing its number of active sites by nanostructuring are two strategies in novel catalyst development. Here, electrocatalytically inert graphene (G) and hexagonal boron nitride (hBN) are made active for the HER by forming van der Waals (vdW) heterostructures via vertical stacking. The HER studies are conducted using defect free shear exfoliated graphite and hBN modified glassy carbon electrodes via layer by layer sequential stacking. The G/hBN stacking pattern (AA, AB, and AB') and stacking sequence (G/hBN or hBN/G) have been found to play important roles in the HER activity. Enhancement in the intrinsic activity of graphene by the formation of G/hBN vdW stacks has been further confirmed with thermally reduced graphene oxide and hBN based structures. Tunability in the HER performance of the G/hBN vdW stack is also confirmed via a three-dimensional rGO/hBN electrode. HER active sites in the G/hBN vdW structures are then mapped using density functional theory calculations, and an atomistic interpretation has been identified.
Phosphorene has attracted great interest
in the rapidly emerging field of two-dimensional layered nanomaterials.
Recent studies show promising electrocatalytic activity of few-layered
phosphorene sheets toward the oxygen evolution reaction (OER). However,
controllable synthesis of mono/few-layered phosphorene nanostructures
with a large number of electrocatalytically active sites and exposed
surface area is important to achieve significant enhancement in OER
activity. Here, a novel strategy for controlled synthesis and in situ surface functionalization of phosphorene quantum
dots (PQDs) using a single-step electrochemical exfoliation process
is demonstrated. Phosphorene quantum dots functionalized with nitrogen-containing
groups (FPQDs) exhibit efficient and stable electrocatalytic activity
for OER with an overpotential of 1.66 V @ 10 mA cm–2, a low Tafel slope of 48 mV dec–1, and excellent
stability. Further, we observe enhanced electron transfer kinetics
for FPQDs toward the Fe2+/Fe3+ redox probe in
comparison with pristine PQDs. The results demonstrate the promising
potential of phosphorene as technologically viable OER electrodes
for water-splitting devices.
Exploring
highly efficient and low-cost electrocatalysts for the
oxygen evolution reaction (OER) is very important for the development
of renewable energy conversion and storage systems. Layered metal
hydroxides have been studied with great interest owing to their high
electrochemical activity and stability toward OER. Herein, we demonstrate
an efficient approach to engineer the surface active sites in β-Co(OH)2 for enhanced electrocatalysis of OER. We employ a single-step
bipolar electrochemical technique for the exfoliation of pristine
β-Co(OH)2(Co(OH)2-Bulk) into thinner and
smaller sheets. The as-synthesized Co(OH)2 nanostructures
with improved active sites exhibit enhanced electrocatalytic activity
toward OER with a very low overpotential of 390 mV at 10 mA cm–2 and a Tafel slope of 57 mV dec–1 in alkaline media. The results provide a promising lead for the
development of efficient and economically viable electrode materials
for oxygen evolution electrocatalysis.
Synthesis of low cost, durable and efficient electrocatalysts that support oxygen evolution reaction (OER) and hydrogen evolution reaction (HER) are the bottlenecks in water electrolysis. Here we propose a strategy for the development of controllably alloyed, porous, and low density nickel (Ni) and cobalt (Co) based alloys - whose electrocatalytic properties can be tuned to make them multifunctional. Ni and Co based alloy with the chemical structure of Ni1Co2 is identified as an efficient OER catalyst among other stoichiometric structures in terms of over potential @ 10 mAcm−2 (1.629 V), stability, low tafel slope (87.3 mV/dec), and high Faradaic efficiency (92%), and its OER performance is also found to be on par with the benchmarked IrO2. Tunability in the porous metal synthesis strategy allowed the incorporation of graphene during the Ni sponge formation, and the Ni- incorporated nitrogen doped graphene sponge (Ni-NG) is found to have very high HER activity. A water electrolysis cell fabricated and demonstrated with these freestanding electrodes is found to have high stability (>10 hours) and large current density (10 mAcm−2 @ 1.6 V), opening new avenues in the design and development of cost effective and light weight energy devices.
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