Literature DB >> 19479912

Formic acid dehydrogenation on au-based catalysts at near-ambient temperatures.

Manuel Ojeda1, Enrique Iglesia.   

Abstract

Selective HCOOH decomposition to H(2)/CO(2) on Au: Au species catalyze HCOOH dehydrogenation at higher rates than on Pt, previously considered the most active metal. Dehydrogenation occurs through formate decomposition limited by H(2) desorption on Au species undetectable by TEM. CO did not form (<10 ppm), making products suitable for low-temperature fuel cells.

Entities:  

Year:  2009        PMID: 19479912     DOI: 10.1002/anie.200805723

Source DB:  PubMed          Journal:  Angew Chem Int Ed Engl        ISSN: 1433-7851            Impact factor:   15.336


  10 in total

1.  Hydrogen production from formic acid decomposition at room temperature using a Ag-Pd core-shell nanocatalyst.

Authors:  Karaked Tedsree; Tong Li; Simon Jones; Chun Wong Aaron Chan; Kai Man Kerry Yu; Paul A J Bagot; Emmanuelle A Marquis; George D W Smith; Shik Chi Edman Tsang
Journal:  Nat Nanotechnol       Date:  2011-04-10       Impact factor: 39.213

Review 2.  Catalytic valorisation of biomass levulinic acid into gamma valerolactone using formic acid as a H2 donor: a critical review.

Authors:  Ayman Hijazi; Nidal Khalaf; Witold Kwapinski; J J Leahy
Journal:  RSC Adv       Date:  2022-05-06       Impact factor: 4.036

3.  Structural analysis of transient reaction intermediate in formic acid dehydrogenation catalysis using two-dimensional IR spectroscopy.

Authors:  Yufan Zhang; Xin Chen; Bin Zheng; Xunmin Guo; Yupeng Pan; Hailong Chen; Huaifeng Li; Shixiong Min; Chao Guan; Kuo-Wei Huang; Junrong Zheng
Journal:  Proc Natl Acad Sci U S A       Date:  2018-11-19       Impact factor: 11.205

4.  Conformational twisting of a formate-bridged diiridium complex enables catalytic formic acid dehydrogenation.

Authors:  Paul J Lauridsen; Zhiyao Lu; Jeff J A Celaje; Elyse A Kedzie; Travis J Williams
Journal:  Dalton Trans       Date:  2018-10-02       Impact factor: 4.390

5.  Efficient dehydrogenation of a formic acid-ammonium formate mixture over Au3Pd1 catalyst.

Authors:  Xiao-Tong Guo; Juan Zhang; Jian-Chao Chi; Zhi-Hui Li; Yu-Chen Liu; Xin-Ru Liu; Shu-Yong Zhang
Journal:  RSC Adv       Date:  2019-02-18       Impact factor: 3.361

6.  Synergy and Anti-Synergy between Palladium and Gold in Nanoparticles Dispersed on a Reducible Support.

Authors:  James H Carter; Sultan Althahban; Ewa Nowicka; Simon J Freakley; David J Morgan; Parag M Shah; Stanislaw Golunski; Christopher J Kiely; Graham J Hutchings
Journal:  ACS Catal       Date:  2016-08-29       Impact factor: 13.084

7.  Controlled release of hydrogen isotope compounds and tunneling effect in the heterogeneously-catalyzed formic acid dehydrogenation.

Authors:  Kohsuke Mori; Yuya Futamura; Shinya Masuda; Hisayoshi Kobayashi; Hiromi Yamashita
Journal:  Nat Commun       Date:  2019-09-25       Impact factor: 14.919

8.  Amine-Functionalized Natural Halloysite Nanotubes Supported Metallic (Pd, Au, Ag) Nanoparticles and Their Catalytic Performance for Dehydrogenation of Formic Acid.

Authors:  Limin Song; Kaiyuan Tan; Yingyue Ye; Baolin Zhu; Shoumin Zhang; Weiping Huang
Journal:  Nanomaterials (Basel)       Date:  2022-07-14       Impact factor: 5.719

9.  Pd/C synthesized with citric acid: an efficient catalyst for hydrogen generation from formic acid/sodium formate.

Authors:  Zhi-Li Wang; Jun-Min Yan; Hong-Li Wang; Yun Ping; Qing Jiang
Journal:  Sci Rep       Date:  2012-08-23       Impact factor: 4.379

10.  Mesoporous Silica Supported Pd-MnOx Catalysts with Excellent Catalytic Activity in Room-Temperature Formic Acid Decomposition.

Authors:  Min-Ho Jin; Duckkyu Oh; Ju-Hyoung Park; Chun-Boo Lee; Sung-Wook Lee; Jong-Soo Park; Kwan-Young Lee; Dong-Wook Lee
Journal:  Sci Rep       Date:  2016-09-26       Impact factor: 4.379
  10 in total

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