Progress in Effects of Microenvironment of Carbon‐based Catalysts on Hydrodeoxygenation of Biomass

Li, Tong; Li, Hao; Li, Chunli

doi:10.1002/cctc.202001369

Cited by 37 publications

(18 citation statements)

References 143 publications

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“…Hydrodeoxygenation (HDO) of biobased ketones and aldehydes, such as acetophenone, benzophenone, 4-hydroxyacetophenone, vanillin, and furfural, can efficiently improve the stability of the bio-oil. Moreover, the selective HDO of the ketones and aldehydes to generate the corresponding alcohols and hydrocarbons has attracted considerable attention, , because the products have been extensively used in industry. As an example of vanillin HDO over 5% Rh/C catalyst, a below 60% yield of vanillyl alcohol was obtained under 0.69 MPa H 2 and 318 K, while the yield of vanillyl alcohol is greater than 70% under extreme conditions (3 MPa H 2 and 373 K) .…”

Section: Introductionmentioning

confidence: 99%

Controlled Hydrodeoxygenation of Biobased Ketones and Aldehydes over an Alloyed Pd–Zr Catalyst under Mild Conditions

Ding

Zong

et al. 2021

ACS Sustainable Chem. Eng.

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The substitution of green hydrogen donors for replacing high-pressure H 2 to achieve biomass derived ketone and aldehyde hydrodeoxygenation (HDO) under mild conditions has attracted widespread attention. However, it remains a considerable challenge to get rid of acid additives and control product selectivity. Herein, a series of bimetallic Pd−M/HZSM-5 catalysts (M = Zr, Mn, Zn, or La) were fabricated for controlled hydrodeoxygenation of biobased ketones and aldehydes (acetophenone, benzophenone, 4-hydroxyacetophenone, vanillin, furfural) using polymethylhydrosiloxane (PMHS) as the green H-donor, in which >99% conversion and >99% selectivity to ethylbenzene were achieved for hydrodeoxygenation of acetophenone as the probe within 3 h at 35 °C over the as-prepared 0.5%Pd−2.0%Zr/HZSM-5 catalyst with a Pd/ Zr mass ratio of 1:4. According to characterizations of TEM-HAADF, XPS, ESR, and H 2 -TPR, the Pd−Zr alloy structure was formed on the bimetallic Pd−Zr/HZSM-5 catalyst, promoting the transform of Pd−O−Zr solid solution to PdO−ZrO 2 and the generation of oxygen vacancy. Moreover, the abundant of oxygen vacancies on the alloyed Pd−Zr/HZSM-5 catalysts enhance the dissociation of silanes to provide the abundance of hydrogen protons, greatly accelerating the hydrogenation of biobased ketones and aldehydes, and then the acid site of the Pd−Zr/HZSM-5 catalyst promotes the dehydration of the intermediates (alcohols) to hydrocarbons. Furthermore, the as-fabricated Pd−Zr/HZSM-5 alloy catalyst can achieve an excellent recycling capability after six uses and exhibits universality toward various biobased ketones and aldehydes at 35 °C. The present findings provide new insights into the design of selective HDO of biomass in a green process.

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Section: Introductionmentioning

confidence: 99%

Controlled Hydrodeoxygenation of Biobased Ketones and Aldehydes over an Alloyed Pd–Zr Catalyst under Mild Conditions

Ding

Zong

et al. 2021

ACS Sustainable Chem. Eng.

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“…Currently, HDO is considered to be the better upgrading technology for biofuels in water-oil biphasic systems, mainly because: (1) during deoxygenation, the oxygen atoms are mostly removed in the form of water, which is friendly to the environment; (2) the reaction process increases the C/H ratio and decreases the O/C ratio, resulting in an increase in the stability and calorific value of the compound; and (3) the hydrodeoxygenation products are easily isolated from the reactants to different phases, effectively improving product selectivity. 102,103 For the HDO of biomass in water-oil biphasic systems, model compounds are often chosen to simplify the reaction system and facilitate the detection of intermediates and products to understand the reaction pattern and mechanism. But it is difficult to elucidate the complex reaction mechanism of the HDO of biomass in water-oil biphasic systems through the catalytic study of only one model compound, since biomass contains a great number of ethers, aldehydes, phenols, ketones and other oxygenated compounds.…”

Section: Application Of Water-oil Biphasic Systems To Biomassmentioning

confidence: 99%

Sustainable biomass hydrodeoxygenation in biphasic systems

Wei

Wang

2022

Green Chem.

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“…[138] Moreover, apart from introducing oxygen functional groups, N-doped carbon (NC) materials are considered as promising materials for use as support in multiphase catalysis. [139] Among others, N doping improves the catalytic performance, which can be attributed to (1) the improved hydrophilicity and basicity of support, [140] which enhances the interaction between substrate and support in the reaction systems; (2) the lower dissociation energy of H 2 activation, which is due to the altered electronic structure of the carbon substrate and the modulating activity of the sp 2 carbon and metal particles; [141] and (3) N doping in the carbon structure, which can be considered as a favorable anchor point or defect for enhanced particle nucleation and particle size reduction and improved the dispersion of metal NPs, as well as enhanced support-active sites interactions. [142] The effect of N doping with CB-loaded Ni catalyst (Ni/NCB) on the catalytic activity in water-solvent-based vanillin HDO was investigated, as shown in Figure 19d.…”

Section: Surface Functional Groupsmentioning

confidence: 99%

“…The introduction of oxygen functional groups into carbon support can significantly increase the hydrogen storage capacity caused by spilled hydrogen on metal‐doped carbon, and the oxygen‐containing functional group promotion is attributed as follows: (1) serving as direct adsorption sites; (2) promoting the formation of spillover H atoms island structures around oxygen functional groups; [48] and (3) facilitating the diffusion and adsorption of hydrogen atoms on the support surface, [137] as shown in Figure 19c [138] . Moreover, apart from introducing oxygen functional groups, N‐doped carbon (NC) materials are considered as promising materials for use as support in multiphase catalysis [139] . Among others, N doping improves the catalytic performance, which can be attributed to (1) the improved hydrophilicity and basicity of support, [140] which enhances the interaction between substrate and support in the reaction systems; (2) the lower dissociation energy of H 2 activation, which is due to the altered electronic structure of the carbon substrate and the modulating activity of the sp 2 carbon and metal particles; [141] and (3) N doping in the carbon structure, which can be considered as a favorable anchor point or defect for enhanced particle nucleation and particle size reduction and improved the dispersion of metal NPs, as well as enhanced support‐active sites interactions [142] .…”

Section: Hydrogen Spillover‐enhanced Mechanism In Biomass Hydrodeoxyg...mentioning

confidence: 99%

Hydrogen Spillover‐Enhanced Heterogeneously Catalyzed Hydrodeoxygenation for Biomass Upgrading

Geng

2022

ChemSusChem

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Hydrodeoxygenation (HDO) is regarded as a promising technology for biomass upgrading to obtain sustainable and competitive chemicals and fuels. In fact, biomass HDO over heterogeneous solid catalysts is often accompanied by the phenomenon of hydrogen spillover, which further affects the catalytic performance. Thus, it is necessary to gain in‐depth understand the promoting effect of hydrogen spillover in the biomass HDO process to obtain desired conversion and selectivity. This Review summarized the extensive research on hydrogen spillover in biomass refining and discussed in detail the regulation mechanism of hydrogen spillover in biomass HDO process, mainly by regulating different active center sites on catalyst supports, such as metal sites, acid sites, surface functional groups, and defective sites, which exhibit independent and synergistic characteristics promoting catalyst activity, selectivity, and stability. Finally, the prospective of hydrogen spillover in biomass HDO applications was critically evaluated, and the key technical challenges in developing “hydrogen‐free” HDO and upgrading biofuels were highlighted. The presentation of hydrogen spillover‐enhanced catalytic biomass HDO in this Review will hopefully provide insight and guidance for further development of efficient catalysts and preparation of high‐value chemicals in the future.

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Progress in Effects of Microenvironment of Carbon‐based Catalysts on Hydrodeoxygenation of Biomass

Cited by 37 publications

References 143 publications

Controlled Hydrodeoxygenation of Biobased Ketones and Aldehydes over an Alloyed Pd–Zr Catalyst under Mild Conditions

Controlled Hydrodeoxygenation of Biobased Ketones and Aldehydes over an Alloyed Pd–Zr Catalyst under Mild Conditions

Sustainable biomass hydrodeoxygenation in biphasic systems

Hydrogen Spillover‐Enhanced Heterogeneously Catalyzed Hydrodeoxygenation for Biomass Upgrading

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