Your search keyword '"Binhang Yan"' showing total 22 results

1. Design Principle of Molybdenum-Based Metal Nitrides for Lattice Nitrogen-Mediated Ammonia Production

Author

Shuairen Qian, Tianying Dai, Kai Feng, Zhengwen Li, Xiaohang Sun, Yuxin Chen, Kaiqi Nie, Binhang Yan, and Yi Cheng

Subjects

Chemistry, QD1-999

Published

2024

2. Upgrading CO2 to sustainable aromatics via perovskite-mediated tandem catalysis

Author

Guo Tian, Zhengwen Li, Chenxi Zhang, Xinyan Liu, Xiaoyu Fan, Kui Shen, Haibin Meng, Ning Wang, Hao Xiong, Mingyu Zhao, Xiaoyu Liang, Liqiang Luo, Lan Zhang, Binhang Yan, Xiao Chen, Hong-Jie Peng, and Fei Wei

Subjects

Science

Abstract

Abstract The directional transformation of carbon dioxide (CO2) with renewable hydrogen into specific carbon-heavy products (C6+) of high value presents a sustainable route for net-zero chemical manufacture. However, it is still challenging to simultaneously achieve high activity and selectivity due to the unbalanced CO2 hydrogenation and C–C coupling rates on complementary active sites in a bifunctional catalyst, thus causing unexpected secondary reaction. Here we report LaFeO3 perovskite-mediated directional tandem conversion of CO2 towards heavy aromatics with high CO2 conversion (> 60%), exceptional aromatics selectivity among hydrocarbons (> 85%), and no obvious deactivation for 1000 hours. This is enabled by disentangling the CO2 hydrogenation domain from the C-C coupling domain in the tandem system for Iron-based catalyst. Unlike other active Fe oxides showing wide hydrocarbon product distribution due to carbide formation, LaFeO3 by design is endowed with superior resistance to carburization, therefore inhibiting uncontrolled C–C coupling on oxide and isolating aromatics formation in the zeolite. In-situ spectroscopic evidence and theoretical calculations reveal an oxygenate-rich surface chemistry of LaFeO3, that easily escape from the oxide surface for further precise C–C coupling inside zeolites, thus steering CO2-HCOOH/H2CO-Aromatics reaction pathway to enable a high yield of aromatics.

Published

2024

3. Defect-Driven Efficient Selective CO2 Hydrogenation with Mo-Based Clusters

Author

Jiajun Zhang, Kai Feng, Zhengwen Li, Bin Yang, Binhang Yan, and Kai Hong Luo

Subjects

Chemistry, QD1-999

Published

2023

4. Hydrolase mimic via second coordination sphere engineering in metal-organic frameworks for environmental remediation

Author

Xin Yuan, Xiaoling Wu, Jun Xiong, Binhang Yan, Ruichen Gao, Shuli Liu, Minhua Zong, Jun Ge, and Wenyong Lou

Subjects

Science

Abstract

Abstract Enzymes achieve high catalytic activity with their elaborate arrangements of amino acid residues in confined optimized spaces. Nevertheless, when exposed to complicated environmental implementation scenarios, including high acidity, organic solvent and high ionic strength, enzymes exhibit low operational stability and poor activity. Here, we report a metal-organic frameworks (MOFs)-based artificial enzyme system via second coordination sphere engineering to achieve high hydrolytic activity under mild conditions. Experiments and theoretical calculations reveal that amide cleavage catalyzed by MOFs follows two distinct catalytic mechanisms, Lewis acid- and hydrogen bonding-mediated hydrolytic processes. The hydrogen bond formed in the secondary coordination sphere exhibits 11-fold higher hydrolytic activity than the Lewis acidic zinc ions. The MOFs exhibit satisfactory degradation performance of toxins and high stability under extreme working conditions, including complicated fermentation broth and high ethanol environments, and display broad substrate specificity. These findings hold great promise for designing artificial enzymes for environmental remediation.

Published

2023

5. Plasma treated M1 MoVNbTeOx–CeO2 composite catalyst for improved performance of oxidative dehydrogenation of ethane

Author

Shuairen Qian, Yuxin Chen, Binhang Yan, and Yi Cheng

Subjects

Oxidative dehydrogenation of ethane (ODHE), MoVNbTeOx, Composite catalyst, Oxygen plasma, Energy conversion, Renewable energy sources, TJ807-830, Ecology, QH540-549.5

Abstract

High activity and productivity of MoVNbTeOx catalyst are challenging tasks in oxidative dehydrogenation of ethane (ODHE) for industrial application. In this work, phase-pure M1 with 30 wt% CeO2 composite catalyst was treated by oxygen plasma to further enhance catalyst performance. The results show that the oxygen vacancies generated by the solid-state redox reaction between M1 and CeO2 capture active oxygen species in gas and transform V4+ to V5+ without damage to M1 structure. The space-time yield of ethylene of the plasma-treated catalyst was significantly increased, in which the catalyst shows an enhancement near ∼100% than that of phase-pure M1 at 400 °C for ODHE process. Plasma treatment for catalysts demonstrates an effective way to convert electrical energy into chemical energy in catalyst materials. Energy conversion is achieved by using the catalyst as a medium.

Published

2023

6. Accelerating syngas-to-aromatic conversion via spontaneously monodispersed Fe in ZnCr2O4 spinel

Author

Guo Tian, Xinyan Liu, Chenxi Zhang, Xiaoyu Fan, Hao Xiong, Xiao Chen, Zhengwen Li, Binhang Yan, Lan Zhang, Ning Wang, Hong-Jie Peng, and Fei Wei

Subjects

Science

Abstract

Spontaneous monodispersion of active species and their stabilization in reductive atmospheres remain a challenge in catalytic syngas chemistry. Here the authors demonstrate that syngas-to-aromatic conversion can be significantly accelerated by the spontaneously monodispersed Fe in ZnCr2O4 spinel.

Published

2022

7. Stable Cu Catalysts Supported by Two‐dimensional SiO2 with Strong Metal–Support Interaction

Author

Shenghua Wang, Kai Feng, Dake Zhang, Deren Yang, Mengqi Xiao, Chengcheng Zhang, Le He, Binhang Yan, Geoffrey A. Ozin, and Wei Sun

Subjects

Cu/SiO2, high‐temperature stability, strong metal–support interaction (SMSI)FF, Science

Abstract

Abstract Cu‐based catalysts exhibit excellent performance in hydrogenation reactions. However, the poor stability of Cu catalysts under high temperatures has restricted their practical applications. The preparation of stable Cu catalysts supported by SiO2 with strong metal–support interaction (SMSI) has thus aroused great interest due to the high abundance, low toxicity, feasible processability, and low cost of SiO2. The challenge in the construction of such SMSI remains to be the inertness of SiO2. Herein, a simple and scalable method is developed to prepare 2D silica (2DSiO2) supported Cu catalysts with SMSI by carefully manipulating the topological exfoliation of CaSi2 with CuCl2 and thereafter calcination. The prepared Cu‐2DSiO2 catalysts with the unique encapsulated Cu nanoparticles exhibit excellent activity and long‐term stability in high‐temperature CO2 hydrogenation reactions. This feasible and low‐cost solution for stabilizing Cu catalysts might shed light on their realistic applications.

Published

2022

8. Inverse ZrO2/Cu as a highly efficient methanol synthesis catalyst from CO2 hydrogenation

Author

Congyi Wu, Lili Lin, Jinjia Liu, Jingpeng Zhang, Feng Zhang, Tong Zhou, Ning Rui, Siyu Yao, Yuchen Deng, Feng Yang, Wenqian Xu, Jun Luo, Yue Zhao, Binhang Yan, Xiao-Dong Wen, José A. Rodriguez, and Ding Ma

Subjects

Science

Abstract

Enhancing the intrinsic activity and space time yield of Cu based heterogeneous methanol synthesis catalysts is one of the major topics in CO2 hydrogenation. Here the authors develop a highly active inverse catalyst composed of fine ZrO2 islands dispersed on metallic Cu nanoparticles.

Published

2020

9. Effect of the Calcination Temperature of LaNiO3 on the Structural Properties and Reaction Performance of Catalysts in the Steam Reforming of Methane

Author

Yujie Wang, Shuairen Qian, Yuxin Chen, Binhang Yan, and Yi Cheng

Subjects

steam reforming of methane, perovskite, LaNiO3, Pechini method, calcination temperature, Chemical technology, TP1-1185, Chemistry, QD1-999

Abstract

The steam reforming of methane (SRM) reaction is a significant process for efficient syngas generation and for promising distributed hydrogen production. In this work, a series of LaNiO3 oxides were prepared using the Pechini method, calcined from 600 °C to 900 °C and tested for the SRM reaction. Fresh, reduced, and used samples were characterized using STA-MS-FTIR, in situ and ex situ XRD, N2 physical adsorption, H2-TPR, TEM, TPO, and Raman. The results show that LaNiO3 begins to crystallize at about 550 °C, and the increase in calcination temperature results in the following differences in the properties of the LaNiO3 samples: larger LaNiO3 grains, smaller specific surface area, higher reduction temperature, smaller Ni0 grains reduced from the bulk phase, and stronger metal–support interaction. The maximum CH4 conversion could be achieved over LaNiO3 calcinated at 800 °C. In addition, the effect of steam-to-carbon ratio (S/C) on the performance of the SRM reaction was studied, and a S/C of 1.5 was found to be optimal for CH4 conversion. Too strong a metal–support interaction and too much unreacted steam causes a loss of catalytic activity. Finally, it was also proved using TPO and Raman that an increase in calcination temperature improves the carbon deposition resistance of the catalyst.

Published

2023

10. State-of-the-Art Review of Oxidative Dehydrogenation of Ethane to Ethylene over MoVNbTeOx Catalysts

Author

Yuxin Chen, Binhang Yan, and Yi Cheng

Subjects

oxidative dehydrogenation of ethane, MoVNbTeOx, catalyst, ethylene, redox process, Chemical technology, TP1-1185, Chemistry, QD1-999

Abstract

Ethylene is mainly produced by steam cracking of naphtha or light alkanes in the current petrochemical industry. However, the high-temperature operation results in high energy demands, high cost of gas separation, and huge CO2 emissions. With the growth of the verified shale gas reserves, oxidative dehydrogenation of ethane (ODHE) becomes a promising process to convert ethane from underutilized shale gas reserves to ethylene at a moderate reaction temperature. Among the catalysts for ODHE, MoVNbTeOx mixed oxide has exhibited superior catalytic performance in terms of ethane conversion, ethylene selectivity, and/or yield. Accordingly, the process design is compact, and the economic evaluation is more favorable in comparison to the mature steam cracking processes. This paper aims to provide a state-of-the-art review on the application of MoVNbTeOx catalysts in the ODHE process, involving the origin of MoVNbTeOx, (post-) treatment of the catalyst, material characterization, reaction mechanism, and evaluation as well as the reactor design, providing a comprehensive overview of M1 MoVNbTeOx catalysts for the oxidative dehydrogenation of ethane, thus contributing to the understanding and development of the ODHE process based on MoVNbTeOx catalysts.

Published

2023

11. Mixed Metal Oxides of M1 MoVNbTeOx and TiO2 as Composite Catalyst for Oxidative Dehydrogenation of Ethane

Author

Yuxin Chen, Dan Dang, Binhang Yan, and Yi Cheng

Subjects

ODHE, ethylene, mixed metal oxides, MoVNbTeOx, TiO2, Chemical technology, TP1-1185, Chemistry, QD1-999

Abstract

Composite catalysts of mixed metal oxides were prepared by mixing a phase-pure M1 MoVNbTeOx with anatase-phase TiO2. Two methods were used to prepare the composite catalysts (the simple physically mixed or sol-gel method) for the improvement of the catalytic performance in the oxidative dehydrogenation of ethane (ODHE) process. The results showed that TiO2 particles with a smaller particle size were well dispersed on the M1 surface for the sol-gel method, which presented an excellent activity for ODHE. At the same operating condition (i.e., the contact time of 7.55 gcat·h/molC2H6 and the reaction temperature of 400 °C), the M1-TiO2-SM and M1-TiO2-PM achieved the space time yields of 0.67 and 0.52 kgC2H4/kgcat/h, respectively, which were about ~76% and ~35% more than that of M1 catalyst (0.38 kgC2H4/kgcat/h), respectively. The BET, ICP, XRD, TEM, SEM, H2-TPR, C2H6-TPSR, and XPS techniques were applied to characterize the catalysts. It was noted that the introduction of TiO2 raised the V5+ abundance on the catalyst surface as well as the reactivity of active oxygen species, which made contribution to the promotion of the catalytic performance. The surface morphology and crystal structure of used catalysts of either M1-TiO2-SM or M1-TiO2-PM remained stable as each fresh catalyst after 24 h time-on-stream tests.

Published

2022

12. Combining CO2 reduction with propane oxidative dehydrogenation over bimetallic catalysts

Author

Elaine Gomez, Shyam Kattel, Binhang Yan, Siyu Yao, Ping Liu, and Jingguang G. Chen

Subjects

Science

Abstract

The oxidative dehydrogenation of propane by CO2 (CO2-ODHP) can potentially fill the gap of propylene production while consuming a greenhouse gas. Here, the authors identify non-precious FeNi and precious NiPt catalysts supported on CeO2 as promising catalysts for CO2-ODHP and dry reforming, respectively, in flow reactor studies.

Published

2018

13. A Raspberry Pi Pico Based Low-Cost, Research-Grade, Open-Source Thermal Conductivity Cell Detector for Chemical Laboratory Analysis

Author

Yuxin Chen, Yuting Wu, Zhengwen Li, Yanyan Zheng, Binhang Yan, and Yi Cheng

Abstract

The "maker" movement is gaining widespread attention, especially in the field of laboratory education. Here we have built a low-cost, "do-it-yourself", open-source thermal conductivity cell detector (TCD) for chemical laboratory analysis, which is assembled from thermal conductivity gas sensor elements and 3D-printed flow cell parts based on a Raspberry Pi Pico microcontroller. An ADS1115 digital-to-analog converter (with 16-bit acquisition resolution) is used to acquire the electrical signal from the thermal conductivity sensor response via a Wheatstone bridge. The device is programmed to acquire data based on the open-source Thonny Micro Python IDE software via I[superscript 2]C communication. Temperature programming analysis (TPA) is an important technique to characterize heterogeneous catalysts; therefore, we apply the assembled TCD to characterize the reduction properties of commercial Cu/ZnO/Al[subscript 2]O[subscript 3] catalysts. The hydrogen temperature-programmed reduction (H[subscript 2]-TPR) profile of the commercial Cu/ZnO/Al[subscript 2]O[subscript 3] catalyst shows a broad peak in the range of 150--250 °C with a peak position at 213 °C, which is consistent with previous reports. The total amount of hydrogen consumed by the commercial catalyst during H[subscript 2]-TPR is 10.7 mmol/g[subscript cat], which can be calculated from the calibrated H[subscript 2] vol % TCD signal result and the peak area of the H[subscript 2]-TPR profile. The results show that the fabricated TCD detector exhibits excellent performance during the testing process and is capable of meeting research-grade applications. In summary, students will learn a wide range of skills in a hands-on learning environment of a chemistry laboratory course.

Published

2023

14. Continuous synthesis of atomically dispersed Rh supported on MgAl2O4 using two-stage microreactor.

Author

Qiangqiang Xue, Binhang Yan, Yujun Wang, and Guangsheng Luo

Subjects

HETEROGENEOUS catalysis, STEAM reforming, NANOPARTICLES, CATALYST synthesis, CATALYSTS

Abstract

Single-atom catalysts with optimal atom utilization and outstanding activity have penetrated the frontier of heterogeneous catalysis. However, the large-scale synthesis of this class of catalysts is still a bottleneck for their industrialization. Herein, we suggest a two-stage micro-dispersion approach to synthesize mesoporous MgAl2O4-supported atomically dispersed Rh, which is more competitive than the batch method for boosting the uniform dispersion of Rh. By increasing the Rh loading, single-atom catalysts (SACs, <0.05 wt%), single-atom catalysts + nanoparticle catalysts (0.05–0.17 wt%), and nanoparticle catalyst (NPCs, 0.17–1.10 wt%) were obtained. For n-octane steam reforming, the turnover frequency of the 0.01-Rh-MgAl2O4 was approximately 30 times that of the 1.10-Rh-MgAl2O4, while the Rh amount of the 0.01-Rh-MgAl2O4 was only 3% that of the 1.10-Rh-MgAl2O4 for the same fuel conversion. Under a high-temperature (750°C) steam atmosphere for 15 h, the hydrogen formation rate only declined from 25.1 to 23.8 mol/mol-C8H18. [ABSTRACT FROM AUTHOR]

Published

2022

15. Inverse ZrO2/Cu as a highly efficient methanol synthesis catalyst from CO2 hydrogenation

Author

Yuchen Deng, Jinjia Liu, Wenqian Xu, Yue Zhao, Ding Ma, Binhang Yan, Tong Zhou, Feng Zhang, Jingpeng Zhang, Congyi Wu, José A. Rodriguez, Feng Yang, Lili Lin, Siyu Yao, Jun Luo, Ning Rui, and Xiaodong Wen

Subjects

Materials science, Science, Inorganic chemistry, General Physics and Astronomy, Nanoparticle, 02 engineering and technology, 010402 general chemistry, Heterogeneous catalysis, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Article, Catalysis, Metal, chemistry.chemical_compound, Adsorption, Chemical engineering, Formate, lcsh:Science, Multidisciplinary, General Chemistry, 021001 nanoscience & nanotechnology, 0104 chemical sciences, X-ray absorption fine structure, chemistry, visual_art, visual_art.visual_art_medium, Nanoparticles, lcsh:Q, Methanol, 0210 nano-technology

Abstract

Enhancing the intrinsic activity and space time yield of Cu based heterogeneous methanol synthesis catalysts through CO2 hydrogenation is one of the major topics in CO2 conversion into value-added liquid fuels and chemicals. Here we report inverse ZrO2/Cu catalysts with a tunable Zr/Cu ratio have been prepared via an oxalate co-precipitation method, showing excellent performance for CO2 hydrogenation to methanol. Under optimal condition, the catalyst composed by 10% of ZrO2 supported over 90% of Cu exhibits the highest mass-specific methanol formation rate of 524 gMeOHkgcat−1h−1 at 220 °C, 3.3 times higher than the activity of traditional Cu/ZrO2 catalysts (159 gMeOHkgcat−1h−1). In situ XRD-PDF, XAFS and AP-XPS structural studies reveal that the inverse ZrO2/Cu catalysts are composed of islands of partially reduced 1–2 nm amorphous ZrO2 supported over metallic Cu particles. The ZrO2 islands are highly active for the CO2 activation. Meanwhile, an intermediate of formate adsorbed on the Cu at 1350 cm−1 is discovered by the in situ DRIFTS. This formate intermediate exhibits fast hydrogenation conversion to methoxy. The activation of CO2 and hydrogenation of all the surface oxygenate intermediates are significantly accelerated over the inverse ZrO2/Cu configuration, accounting for the excellent methanol formation activity observed., Enhancing the intrinsic activity and space time yield of Cu based heterogeneous methanol synthesis catalysts is one of the major topics in CO2 hydrogenation. Here the authors develop a highly active inverse catalyst composed of fine ZrO2 islands dispersed on metallic Cu nanoparticles.

Published

2020

16. Dual Functionalized Interstitial N Atoms in Co3Mo3N Enabling CO2 Activation.

Author

Kai Feng, Jiaming Tian, Jiajun Zhang, Zhengwen Li, Yuxin Chen, Kai Hong Luo, Bin Yang, and Binhang Yan

Published

2022

17. China goes green: cleaner production of chemicals

Author

Wei Lu, Yi Cheng, and Binhang Yan

Subjects

Pollution, Health, Toxicology and Mutagenesis, General Chemical Engineering, media_common.quotation_subject, cleaner production, Nanotechnology, Industrial and Manufacturing Engineering, Vinyl chloride, Waste gas, chemistry.chemical_compound, Environmental Chemistry, low-carbon technology, QD1-999, media_common, green chemical engineering, Waste management, Chlorinated polyvinyl chloride, Clean coal, Renewable Energy, Sustainability and the Environment, Energy consumption, chlor-alkali industry, Polyvinyl chloride, Chemistry, Fuel Technology, chemistry, Cleaner production, clean coal conversion

Abstract

The effort that China is making for cleaner production of chemicals especially based on technology innovations of green processing and synthesizing methods, is reviewed. An example is the rapidly expanding chlor-alkali industry in China, which manufactures a large volume of products of caustic soda, polyvinyl chloride (PVC), etc. With a distinct difference from conventional technologies, a series of novel processes are under investigation, both in academic research and in industrial demonstrations, such as clean coal conversion to acetylene using thermal plasma, mercury free catalysis to synthesize vinyl chloride monomer (VCM) and a plasma-assisted gas-solid contacting process to make chlorinated PVC (CPVC). All efforts are directed to improving the process effi ciency, saving the materials and energy cost, and accordingly to reducing the emission/disposal of waste gases, liquids and solid residues. We try to address the signifi cance of technology innovations to drive the industry reformation, in order to fully update the outdated processes with heavy pollution and energy consumption, to the state of the art green process and synthesis techniques.

Published

2012

18. Active sites for tandem reactions of CO2 reduction and ethane dehydrogenation.

Author

Binhang Yan, Siyu Yao, Kattel, Shyam, Qiyuan Wu, Zhenhua Xie, Gomez, Elaine, Ping Liu, Dong Su, and Jingguang G. Chen

Subjects

*ETHYLENE synthesis, *BINDING sites, *CARBON dioxide reduction, *DEHYDROGENATION, *SCISSION (Chemistry), *CHEMICAL bonds

Abstract

Ethylene (C2H4) is one of the most important raw materials for chemical industry. The tandem reactions of CO2-assisted dehydrogenation of ethane (C2H6) to ethylene creates an opportunity to effectively use the underutilized ethane from shale gas while mitigating anthropogenic CO2 emissions. Here we identify the most likely active sites over CeO2-supported NiFe catalysts by using combined in situ characterization with density-functional theory (DFT) calculations. The experimental and theoretical results reveal that the Ni-FeOx interfacial sites can selectively break the C-H bonds and preserve the C-C bond of C2H6 to produce ethylene, while the Ni-CeOx interfacial sites efficiently cleave all of the C-H and C-C bonds to produce synthesis gas. Controlled synthesis of the two distinct active sites enables rational enhancement of the ethylene selectivity for the CO2-assisted dehydrogenation of ethane. [ABSTRACT FROM AUTHOR]

Published

2018

19. Combining CO2 reduction with propane oxidative dehydrogenation over bimetallic catalysts.

Author

Gomez, Elaine, Chen, Jingguang G., Kattel, Shyam, Binhang Yan, Siyu Yao, and Ping Liu

Subjects

PROPYLENE oxide, POLYPROPYLENE carbonate, EPOXY compounds, DEHYDROGENATION, ELIMINATION reactions

Abstract

The inherent variability and insufficiencies in the co-production of propylene from steam crackers has raised concerns regarding the global propylene production gap and has directed industry to develop more on-purpose propylene technologies. The oxidative dehydrogenation of propane by CO2 (CO2-ODHP) can potentially fill this gap while consuming a greenhouse gas. Non-precious FeNi and precious NiPt catalysts supported on CeO2 have been identified as promising catalysts for CO2-ODHP and dry reforming, respectively, in flow reactor studies conducted at 823 K. In-situ X-ray absorption spectroscopy measurements revealed the oxidation states of metals under reaction conditions and density functional theory calculations were utilized to identify the most favorable reaction pathways over the two types of catalysts. [ABSTRACT FROM AUTHOR]

Published

2018

20. Growth of Nanoparticles with Desired Catalytic Functions by Controlled Doping-Segregation of Metal in Oxide.

Author

Qiyuan Wu, Binhang Yan, Jiajie Cen, Timoshenko, Janis, Zakharov, Dmitri N., Xianyin Chen, Xin, Huolin L., Siyu Yao, Parise, John B., Frenkel, Anatoly I., Stach, Eric A., Chen, Jingguang G., and Orlov, Alexander

Subjects

*METAL nanoparticles, *CATALYTIC activity, *HYDROGENATION, *DOPING agents (Chemistry), *MORPHOLOGY

Abstract

The size and morphology of metal nanoparticles (NPs) often play a critical role in defining the catalytic performance of supported metal nanocatalysts. However, common synthetic methods struggle to produce metal NPs of appropriate size and morphological control. Thus, facile synthetic methods that offer controlled catalytic functions are highly desired. Here we have identified a new pathway to synthesize supported Rh nanocatalysts with finely tuned spatial dimensions and controlled morphology using a doping-segregation method. We have analyzed their structure evolutions during both the segregation process and catalytic reaction using a variety of in situ spectroscopic and microscopic techniques. A correlation between the catalytic functional sites and activity in CO2 hydrogenation over supported Rh nanocatalysts is then established. This study demonstrates a facile strategy to design and synthesize nanocatalysts with desired catalytic functions. [ABSTRACT FROM AUTHOR]

Published

2018

21. Comparison of Methodologies of Activation Barrier Measurements for Reactions with Deactivation.

Author

Zhenhua Xie, Binhang Yan, Li Zhang, and Chen, Jingguang G.

Subjects

*ETHANES, *CATALYTIC reforming, *CATALYST poisoning, *MASS transfer, *HEAT transfer

Abstract

Methodologies of activation barrier measurements for reactions with deactivation were theoretically analyzed. Reforming of ethane with CO2 was introduced as an example for reactions with deactivation to experimentally evaluate these methodologies. Both the theoretical and experimental results showed that due to catalyst deactivation, the conventional method would inevitably lead to a much lower activation barrier, compared to the intrinsic value, even though heat and mass transport limitations were excluded. In this work, an optimal method was identified in order to provide a reliable and efficient activation barrier measurement for reactions with deactivation. [ABSTRACT FROM AUTHOR]

Published

2017

22. Optimizing Binding Energies of Key Intermediates for CO2 Hydrogenation to Methanol over Oxide-Supported Copper.

Author

Kattel, Shyam, Binhang Yan, Yixiong Yang, Chen, Jingguang G., and Ping Liu

Subjects

*ZIRCONIUM oxide, *INTERMEDIATES (Chemistry), *METHANOL, *CHEMICAL synthesis, *BINDING energy, *COPPER catalysts, *CARBON dioxide, *CATALYTIC hydrogenation

Abstract

Rational optimization of catalytic performance has been one of the major challenges in catalysis. Here we report a bottom-up study on the ability of TiO2 and ZrO2 to optimize the CO2 conversion to methanol on Cu, using combined density functional theory (DFT) calculations, kinetic Monte Carlo (KMC) simulations, in situ diffuse reflectance infrared Fourier transform spectroscopy (DRIFTS) measurements, and steady-state flow reactor tests. The theoretical results from DFT and KMC agree with in situ DRIFTS measurements, showing that both TiO2 and ZrO2 help to promote methanol synthesis on Cu via carboxyl intermediates and the reverse water-gas-shift (RWGS) pathway; the formate intermediates, on the other hand, likely act as a spectator eventually. The origin of the superior promoting effect of ZrO2 is associated with the fine-tuning capability of reduced Zr3+ at the interface, being able to bind the key reaction intermediates, e.g. *CO2, *CO, *HCO, and *H2CO, moderately to facilitate methanol formation. This study demonstrates the importance of synergy between theory and experiments to elucidate the complex reaction mechanisms of CO2 hydrogenation for the realization of a better catalyst by design. [ABSTRACT FROM AUTHOR]

Published

2016