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M. Lopes et al.
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Qingbin Wu et al.
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Kazuya Yamaguchi et al.
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Harishchandra Jadhav et al.
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Navneet Kumar Gupta et al.
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Kiyotaka Nakajima et al.
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Nanosheets as highly active solid acid catalysts for green chemical syntheses
Atsushi Takagaki et al.
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Caio Tagusagawa et al.
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Evaluation of strong acid properties of layered HNbMoO6 and catalytic activity for Friedel-Crafts alkylation
Caio Tagusagawa et al.
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Glucose to Value-added Chemicals: Anhydroglucose Formation by Selective Dehydration over Solid Acid Catalysts
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Metal chlorides in ionic liquid solvents convert sugars to 5-hydroxymethylfurfural
Haibo Zhao et al.
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Ana S. Dias et al.
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Exfoliated HNb3O8 nanosheets as a strong protonic solid acid
A Takagaki et al.
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A Takagaki et al.
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Water-tolerant solid acid catalysts
T Okuhara
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Discernment and quantification of internal and external acid sites on zeolites
Q Zhao et al.
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