Literature DB >> 11778042

A one-step conversion of benzene to phenol with a palladium membrane.

Shu-ichi Niwa Si1, Muthusamy Eswaramoorthy, Jalajakumari Nair, Anuj Raj, Naotsugu Itoh, Hiroshi Shoji, Takemi Namba, Fujio Mizukami.   

Abstract

Existing phenol production processes tend to be energy-consuming and produce unwanted by-products. We report an efficient process using a shell-and-tube reactor, in which a gaseous mixture of benzene and oxygen is fed into a porous alumina tube coated with a palladium thin layer and hydrogen is fed into the shell. Hydrogen dissociated on the palladium layer surface permeates onto the back and reacts with oxygen to give active oxygen species, which attack benzene to produce phenol. This one-step process attained phenol formation selectivities of 80 to 97% at benzene conversions of 2 to 16% below 250 degrees C (phenol yield: 1.5 kilograms per kilogram of catalyst per hour at 150 degrees C).

Entities:  

Year:  2002        PMID: 11778042     DOI: 10.1126/science.1066527

Source DB:  PubMed          Journal:  Science        ISSN: 0036-8075            Impact factor:   47.728


  19 in total

1.  Vibrational spectroscopy of intermediates in benzene-to-pheno conversion by FeO+.

Authors:  Gokhan Altinay; Ricardo B Metz
Journal:  J Am Soc Mass Spectrom       Date:  2010-01-25       Impact factor: 3.109

2.  Role of boric acid in nickel nanotube electrodeposition: a surface-directed growth mechanism.

Authors:  Lauren M Graham; Seungil Cho; Sung Kyoung Kim; Malachi Noked; Sang Bok Lee
Journal:  Chem Commun (Camb)       Date:  2013-11-22       Impact factor: 6.222

3.  Electrophotocatalytic C-H Heterofunctionalization of Arenes.

Authors:  He Huang; Tristan H Lambert
Journal:  Angew Chem Int Ed Engl       Date:  2021-04-12       Impact factor: 15.336

4.  Homocoupling of aryl halides in flow: Space integration of lithiation and FeCl(3) promoted homocoupling.

Authors:  Aiichiro Nagaki; Yuki Uesugi; Yutaka Tomida; Jun-Ichi Yoshida
Journal:  Beilstein J Org Chem       Date:  2011-08-02       Impact factor: 2.883

5.  C3N4-H5PMo10V2O40: a dual-catalysis system for reductant-free aerobic oxidation of benzene to phenol.

Authors:  Zhouyang Long; Yu Zhou; Guojian Chen; Weilin Ge; Jun Wang
Journal:  Sci Rep       Date:  2014-01-13       Impact factor: 4.379

6.  Photocatalytic oxidation of benzene to phenol using dioxygen as an oxygen source and water as an electron source in the presence of a cobalt catalyst.

Authors:  Ji Won Han; Jieun Jung; Yong-Min Lee; Wonwoo Nam; Shunichi Fukuzumi
Journal:  Chem Sci       Date:  2017-08-21       Impact factor: 9.825

7.  Immediate hydroxylation of arenes to phenols via V-containing all-silica ZSM-22 zeolite triggered non-radical mechanism.

Authors:  Yu Zhou; Zhipan Ma; Junjie Tang; Ning Yan; Yonghua Du; Shibo Xi; Kai Wang; Wei Zhang; Haimeng Wen; Jun Wang
Journal:  Nat Commun       Date:  2018-07-26       Impact factor: 14.919

8.  A single iron site confined in a graphene matrix for the catalytic oxidation of benzene at room temperature.

Authors:  Dehui Deng; Xiaoqi Chen; Liang Yu; Xing Wu; Qingfei Liu; Yun Liu; Huaixin Yang; Huanfang Tian; Yongfeng Hu; Peipei Du; Rui Si; Junhu Wang; Xiaoju Cui; Haobo Li; Jianping Xiao; Tao Xu; Jiao Deng; Fan Yang; Paul N Duchesne; Peng Zhang; Jigang Zhou; Litao Sun; Jianqi Li; Xiulian Pan; Xinhe Bao
Journal:  Sci Adv       Date:  2015-12-04       Impact factor: 14.136

9.  Observation of replacement of carbon in benzene with nitrogen in a low-temperature plasma.

Authors:  Zhiping Zhang; Xiaoyun Gong; Sichun Zhang; Haijun Yang; Youmin Shi; Chengdui Yang; Xinrong Zhang; Xingchuang Xiong; Xiang Fang; Zheng Ouyang
Journal:  Sci Rep       Date:  2013-12-11       Impact factor: 4.379

10.  A competing, dual mechanism for catalytic direct benzene hydroxylation from combined experimental-DFT studies.

Authors:  Laia Vilella; Ana Conde; David Balcells; M Mar Díaz-Requejo; Agustí Lledós; Pedro J Pérez
Journal:  Chem Sci       Date:  2017-10-05       Impact factor: 9.825
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