MoS2 monolayer catalyst doped with isolated Co atoms for the hydrodeoxygenation reaction

Liu, Guoliang; Robertson, Alex W.; Li, Molly Meng‐Jung; Kuo, Winson C. H.; Darby, Matthew T.; Muhieddine, Mohamad H.; Lin, Yung‐Chang; Suenaga, Kazu; Stamatakis, Michail; Warner, Jamie H.; Tsang, Shik Chi Edman

doi:10.1038/nchem.2740

Cited by 705 publications

(478 citation statements)

References 34 publications

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“…MoS 2 is one of the most promising precious raremetal-free catalysts for the hydrogen evolution reaction (HER). [1] To improve the catalytic activity of MoS 2 ,s ignificant efforts have been made in terms of conductivity improvement, [2] chemical doping, [3] phase transition, [4] strain, [5] and defect engineering. [6] However, most of the research characterizes the macroscopic catalytic activity of al arge number of MoS 2 nanosheets;q uantitatively identifying and characterizing catalytically active sites in MoS 2 are critically important for understanding the catalysis of MoS 2 .…”

Section: Introductionmentioning

confidence: 99%

High‐Resolution Electrochemical Mapping of the Hydrogen Evolution Reaction on Transition‐Metal Dichalcogenide Nanosheets

et al. 2020

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High‐resolution scanning electrochemical cell microscopy (SECCM) is used to image and quantitatively analyze the hydrogen evolution reaction (HER) catalytically active sites of 1H‐MoS2 nanosheets, MoS2, and WS2 heteronanosheets. Using a 20 nm radius nanopipette and hopping mode scanning, the resolution of SECCM was beyond the optical microscopy limit and visualized a small triangular MoS2 nanosheet with a side length of ca. 130 nm. The electrochemical cell provides local cyclic voltammograms with a nanoscale spatial resolution for visualizing HER active sites as electrochemical images. The HER activity difference of edge, terrace, and heterojunction of MoS2 and WS2 were revealed. The SECCM imaging directly visualized the relationship of HER activity and number of MoS2 nanosheet layers and unveiled the heterogeneous aging state of MoS2 nanosheets. SECCM can be used for improving local HER activities by producing sulfur vacancies using electrochemical reaction at the selected region.

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Section: Introductionmentioning

confidence: 99%

High‐Resolution Electrochemical Mapping of the Hydrogen Evolution Reaction on Transition‐Metal Dichalcogenide Nanosheets

et al. 2020

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“…Various grain boundaries [13][14][15][16][17][18][19][20][21][22][23][24][25] show distinct optical, electrical, magnetic, and catalytic properties. Herein, structural defects or external dopants are able to endow a broad range of promising applications in 2D materials based on the defect topology and density, such as nanoelectronics, 26 optoelectronics, 26 valleytronics, 27 catalysis, 28,29 and so on. In most cases, various types of structural defects coexist in one sample, and defect density varies in different locations.…”

Section: Introductionmentioning

confidence: 99%

A machine perspective of atomic defects in scanning transmission electron microscopy

Dan

Zhao

Pennycook

2019

InfoMat

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Enabled by the advances in aberration‐corrected scanning transmission electron microscopy (STEM), atomic‐resolution real space imaging of materials has allowed a direct structure‐property investigation. Traditional ways of quantitative data analysis suffer from low yield and poor accuracy. New ideas in the field of computer vision and machine learning have provided more momentum to harness the wealth of big data and sophisticated information in STEM data analytics, which has transformed STEM from a localized characterization technique to a macroscopic tool with intelligence. In this review article, we discuss the prime significance of defect topology and density in two‐dimensional (2D) materials, which have proved to be a powerful means to tune a wide range of properties. Subsequently, we systematically review advanced data analysis methods that have demonstrated promising prospects in analyzing STEM data, particularly for identifying structural defects, with high throughput and veracity. A unified framework for atomic structure identification is also summarized.

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“…Biomass hasb een extensivelyi nvestigateda sasource of renewable fuels and chemicals, [1][2][3] with the development of competitive biorefineries requiring efficient processes able to valorize all components in biomass. [1] The utilization of cellulose and hemicellulose to produce fuels and chemicals is a maturet echnology, [4][5][6] whereas utilization of the more recalcitrant biopolymer,l ignin, remains challenging despite excellent progress.…”

Section: Introductionmentioning

confidence: 99%

“…[40][41][42][43] Carbon-supported metal-sulfide catalysts have been obtained from atraditional multistepp rocess comprising incipient wetness, co-impregnationo na ctivated carbon, and sulfidization in as ubsequent step under af low of H 2 S/H 2 [36,44,45] or through heat treatment with sulfur-containing organics, that is, dimethylsulfide [37] or thiourea. [2] To bypasst he sulfidation step, we decided to use LS as precursor to synthesize highly dis-Catalytic lignosulfonate valorization is hampered by the in situ liberation of sulfur that ultimately poisons the catalyst. To overcome this limitation, metal sulfide catalysts were developed that are able to cleave the CÀOb onds of lignosulfonate and are resistant to sulfur poisoning.…”

Section: Introductionmentioning

confidence: 99%

Metal‐Sulfide Catalysts Derived from Lignosulfonate and their Efficient Use in Hydrogenolysis

et al. 2019

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Catalytic lignosulfonate valorization is hampered by the in situ liberation of sulfur that ultimately poisons the catalyst. To overcome this limitation, metal sulfide catalysts were developed that are able to cleave the C−O bonds of lignosulfonate and are resistant to sulfur poisoning. The catalysts were prepared by using the lignosulfonate substrate as a precursor to form well‐dispersed carbon‐supported metal (Co, Ni, Mo, CoMo, NiMo) sulfide catalysts. Following optimization of the reaction conditions employing a model substrate, the catalysts were used to generate guaiacyl monomers from lignosulfonate. The Co catalyst was able to produce 23.7 mg of 4‐propylguaiacol per gram of lignosulfonate with a selectivity of 84 %. The catalysts operated in water and could be recycled and reused multiple times. Thus, it was demonstrated that an inexpensive, sulfur‐tolerant catalyst based on an earth‐abundant metal and lignosulfonate efficiently catalyzed the selective hydrogenolysis of lignosulfonate in water in the absence of additives.

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MoS2 monolayer catalyst doped with isolated Co atoms for the hydrodeoxygenation reaction

Cited by 705 publications

References 34 publications

High‐Resolution Electrochemical Mapping of the Hydrogen Evolution Reaction on Transition‐Metal Dichalcogenide Nanosheets

High‐Resolution Electrochemical Mapping of the Hydrogen Evolution Reaction on Transition‐Metal Dichalcogenide Nanosheets

A machine perspective of atomic defects in scanning transmission electron microscopy

Metal‐Sulfide Catalysts Derived from Lignosulfonate and their Efficient Use in Hydrogenolysis

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