Synthesis of Single-Atom Catalysts Through Top-Down Atomization Approaches

Aijing, Zhang; Ming-zheng, Zhou; Liu, Siyuan; Chai, Maorong; Jiang, Shengjuan

doi:10.3389/fctls.2021.754167

Cited by 17 publications

(15 citation statements)

References 74 publications

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“…To localize the single cobalt atom [ 23 , 24 , 25 , 26 , 27 , 28 , 29 , 30 , 31 , 32 , 33 , 34 , 35 , 36 ] which is expressed in CoNx bonding in the carbon matrix, HRTEM pictures taken from Figure 5 a at two selected sites (sites 1 and 2) are shown in Figure 5 b,d, respectively. Many CoNx dots are dispersed around Co crystalline in Figure 5 b and the electron diffraction pattern which is also demonstrated in Figure 5 c. From the HRTEM micrograph revealed in Figure 5 d, the Co(111) and C(002) planes are identified, and the electron diffraction pattern of the Co crystalline is illustrated in Figure 5 e.…”

Section: Resultsmentioning

confidence: 99%

“…To localize the single cobalt atom [23][24][25][26][27][28][29][30][31][32][33][34][35][36] which is expressed in Co carbon matrix, HRTEM pictures taken from Figure 5a at two selected s…”

Section: Sem and Tem Micrographsmentioning

confidence: 99%

“…The embedded Co metal or CoO inside CoNC-1000A-900 can also be found in Figure 4f or Figure 4g. To localize the single cobalt atom [23][24][25][26][27][28][29][30][31][32][33][34][35][36] which is expressed in CoNx bonding in the carbon matrix, HRTEM pictures taken from Figure 5a at two selected sites (sites 1 and 2) are shown in Figure 5b,d, respectively. Many CoNx dots are dispersed around Co crystalline in Figure 5b and the electron diffraction pattern which is also demonstrated in Figure 5c.…”

Section: Sem and Tem Micrographsmentioning

confidence: 99%

See 2 more Smart Citations

Cobalt-Based Cathode Catalysts for Oxygen-Reduction Reaction in an Anion Exchange Membrane Fuel Cell

Hsieh¹,

Wang²,

Ho³

2022

Membranes

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A novel cobalt-chelating polyimine (Co-PIM) containing an additional amine group is prepared from the condensation polymerization of diethylene triamine (DETA) and terephthalalehyde (PTAl) by the Schiff reaction. A Co, N-co-doped carbon material (Co-N-C), obtained from two-stage calcination in different gas atmospheres is used as the cathode catalyst of an anion exchange membrane fuel cell (AEMFC). The Co-N-C catalyst demonstrates a CoNx-type single-atom structure seen under high-resolution transmission electron microscopy (HRTEM). The Co-N-C catalysts are characterized by FTIR, XRD, and Raman spectroscopy as well. Their morphologies are also illustrated by SEM and TEM micrographs, respectively. Surface area and pore size distribution are found by BET analysis. Co-N-C catalysts exhibit a remarkable oxygen reduction reaction (ORR) at 0.8 V in the KOH(aq). From the LSV (linear-sweeping voltammetry) curves, the onset potential relative to RHE is 1.19–1.37 V, the half wave potential is 0.73–0.78 V, the Tafel slopes are 76.9–93.6 mV dec−1, and the average number of exchange electrons is 3.81. The limiting reduction current of CoNC-1000A-900 is almost the same as that of commercial 20 wt% Pt-deposited carbon particles (Pt/C), and the max power density (Pmax) of the single cell using CoNC-1000A-900 as the cathode catalyst reaches 361 mW cm−2, which is higher than Pt/C (284 mW cm−2).

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Section: Resultsmentioning

confidence: 99%

“…To localize the single cobalt atom [23][24][25][26][27][28][29][30][31][32][33][34][35][36] which is expressed in Co carbon matrix, HRTEM pictures taken from Figure 5a at two selected s…”

Section: Sem and Tem Micrographsmentioning

confidence: 99%

Section: Sem and Tem Micrographsmentioning

confidence: 99%

See 1 more Smart Citation

Cobalt-Based Cathode Catalysts for Oxygen-Reduction Reaction in an Anion Exchange Membrane Fuel Cell

Hsieh¹,

Wang²,

Ho³

2022

Membranes

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“…Therefore, most of the time the synthesis of SACs is carried out under inert atmospheres (Ar or N 2 ). [ 18 ] Another factor that is to be considered is the type of support on which single atoms are stabilized. One successful attempt of altering the oxidation states in a SAC utilizing this strategy was achieved via alteration of the Pt coordination environments with oxygen atoms on CeO 2 support in order to attenuate the electron dynamics over the metal/CeO 2 surface.…”

Section: Introductionmentioning

confidence: 99%

Engineering at Subatomic Scale: Achieving Selective Catalytic Pathways via Tuning of the Oxidation States in Functionalized Single‐Atom Quantum Catalysts

Zeb

Sahar

et al. 2022

Small

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Regulating the catalytic pathways of single‐atom sites in single atom catalysts (SACs) is an exciting debate at the moment, which has redirected the research towards understanding and modifying the single‐atom catalytic sites through various strategies including altering the coordination environment of single atom for desirable outcomes as well as increasing their number. One useful aspect concerning the tunability of the catalytic pathways of SACs, which has been overlooked, is the oxidation state dynamics of the single atoms. In this study, iron single‐atoms (FeSA) with variable oxidation states, dependent on the precursors, are harnessed inside a nitrogen‐rich functionalized carbon quantum dots (CQDs) matrix via a facile one‐step and low‐temperature synthesis process. Dynamic electronic properties are imparted to the FeSAs by the simpler carbon dots matrix of CQDs in order to achieve the desired catalytic pathways of reactive oxygen species (ROS) generation in different environments, which are explored experimentally and theoretically for an in‐depth understanding of the redox chemistry that drives the alternative catalytic pathways in FeSA@CQDs. These alternative and oxidation state‐dependent catalytic pathways are employed for specific as well as cascade‐like activities simulating natural enzymes as well as biomarkers for the detection of cancerous cells.

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“…[9b,10] Atom-scale defects on these support materials such as oxygen vacancies, unsaturated coordination sites, and heteroatom dopants serve as anchoring sites on which platinum atoms can bind to. Although the single-atom platinum catalysts allow for significant enhancement in the catalytic activity compared to the platinum nanoparticles on a per atom basis, [9a] their practical application in electrochemical water splitting is hindered because 1) scalable production of finely distributed defect sites at high densities is still challenging; [11] 2) the catalyst loading needs to be kept low (typically < 1 wt%) to ensure atomic dispersion of platinum without nanoparticle formation, which often leads to a low electrochemical activity per unit electrode area; [12] and 3) platinum atoms tend to detach from the anchoring sites and aggregate into nanoparticles during catalytic reaction. [11,13] Besides downsizing of the platinum catalysts, engineering of nanoscale particle morphology has also been intensively pursued to enhance the surface-to-volume ratio and the catalytic properties.…”

Section: Introductionmentioning

confidence: 99%

Scalable Synthesis of Pt Nanoflowers on Solution‐Processed MoS₂ Thin Film for Efficient Hydrogen Evolution Reaction

et al. 2022

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Nanostructuring of Pt nanocatalysts increases the surface‐to‐volume ratio, thus enabling efficient usage of Pt for hydrogen evolution reaction (HER). Direct electrochemical reduction of Pt on the electrode can produce nanostructured Pt catalysts, which has been time‐consuming for the conventional colloidal synthesis. However, carbon‐based growth templates commonly used to create Pt nanoparticles offer limited control over morphologies and HER performance. Herein, a facile electrochemical synthesis of Pt nanoflowers (NFs) with well‐defined petals is presented. Semiconducting MoS2 nanosheets are solution processed into a film on a carbon paper (CP) to synthesize Pt NFs upon reduction of Pt precursor. The Pt NFs show higher HER activities than spherical or spiky Pt nanoparticles because of their larger active surface area and enable faster release of hydrogen bubbles during HER. By generating sulfur vacancies and MoOx on the MoS2 template using a reactive ion etching, the areal density and spatial uniformity of Pt NFs can be greatly enhanced and a mass activity can be achieved more than 10 times as high as that of the conventional Pt/C electrode. Multiple electrodes with nearly similar electrochemical properties can be repeatedly produced by using a single precursor solution, which highlights the cost‐efficiency and scalability of our synthesis strategy.

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Synthesis of Single-Atom Catalysts Through Top-Down Atomization Approaches

Cited by 17 publications

References 74 publications

Cobalt-Based Cathode Catalysts for Oxygen-Reduction Reaction in an Anion Exchange Membrane Fuel Cell

Cobalt-Based Cathode Catalysts for Oxygen-Reduction Reaction in an Anion Exchange Membrane Fuel Cell

Engineering at Subatomic Scale: Achieving Selective Catalytic Pathways via Tuning of the Oxidation States in Functionalized Single‐Atom Quantum Catalysts

Scalable Synthesis of Pt Nanoflowers on Solution‐Processed MoS₂ Thin Film for Efficient Hydrogen Evolution Reaction

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Synthesis of Single-Atom Catalysts Through Top-Down Atomization Approaches

Cited by 17 publications

References 74 publications

Cobalt-Based Cathode Catalysts for Oxygen-Reduction Reaction in an Anion Exchange Membrane Fuel Cell

Cobalt-Based Cathode Catalysts for Oxygen-Reduction Reaction in an Anion Exchange Membrane Fuel Cell

Engineering at Subatomic Scale: Achieving Selective Catalytic Pathways via Tuning of the Oxidation States in Functionalized Single‐Atom Quantum Catalysts

Scalable Synthesis of Pt Nanoflowers on Solution‐Processed MoS2 Thin Film for Efficient Hydrogen Evolution Reaction

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Product

Resources

About

Scalable Synthesis of Pt Nanoflowers on Solution‐Processed MoS₂ Thin Film for Efficient Hydrogen Evolution Reaction