In situ nanoscale wet imaging of the heterogeneous catalyzation of nitriles in a solution phase: novel hydrogenation chemistry through nanocatalysts on nanosupports

P L  Gai; K  Kourtakis; E D  Boyes

doi:10.1007/s10562-005-5195-5

In situ nanoscale wet imaging of the heterogeneous catalyzation of nitriles in a solution phase: novel hydrogenation chemistry through nanocatalysts on nanosupports

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Abstract

Wet- environmental transmission electron microscopy studies of heterogeneous hydrogenation of complex nitriles in a liquid phase over new mesoporous cobalt- promoted ruthenium nanocatalysts on reducible nanotitania supports are presented. The desorbed organic products in the dynamic liquid phase hydrogenation are imaged situ on the nanoscale. The direct studies on the "nanocomposite" catalysts are correlated with parallel reaction chemistry measurements. They demonstrate high hydrogenation activity at low operating temperatures in the presence of atomic scale anion vacancy defects associated with Lewis acid sites at the nanosupport surface and an electronic and synergistic contribution to the promoter mechanism. The combined synergistic effect between the two metals and the interaction with the reduced nanosupport leading to an electronic modi. cation lead to highly reactive site for the hydrogenation catalysis. The results illustrate novel selective hydrogenation chemistry with mesoporous nanocatalyst systems on nanosupports.

Original language	English
Pages (from-to)	1-7
Number of pages	7
Journal	Catalysis Letters
Volume	102
Issue number	1-2
DOIs	https://doi.org/10.1007/s10562-005-5195-5
Publication status	Published - Jul 2005

Keywords

hydrogenation
nitriles in solution phase
wet in situ imaging
nanocatalysts
RESOLUTION ELECTRON-MICROSCOPY
CATALYTIC-HYDROGENATION
NICKEL
OXYGEN
LIQUID
NYLON

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10.1007/s10562-005-5195-5

http://dx.doi.org/10.1007/s10562-005-5195-5

Cite this

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title = "In situ nanoscale wet imaging of the heterogeneous catalyzation of nitriles in a solution phase: novel hydrogenation chemistry through nanocatalysts on nanosupports",

abstract = "Wet- environmental transmission electron microscopy studies of heterogeneous hydrogenation of complex nitriles in a liquid phase over new mesoporous cobalt- promoted ruthenium nanocatalysts on reducible nanotitania supports are presented. The desorbed organic products in the dynamic liquid phase hydrogenation are imaged situ on the nanoscale. The direct studies on the {"}nanocomposite{"} catalysts are correlated with parallel reaction chemistry measurements. They demonstrate high hydrogenation activity at low operating temperatures in the presence of atomic scale anion vacancy defects associated with Lewis acid sites at the nanosupport surface and an electronic and synergistic contribution to the promoter mechanism. The combined synergistic effect between the two metals and the interaction with the reduced nanosupport leading to an electronic modi. cation lead to highly reactive site for the hydrogenation catalysis. The results illustrate novel selective hydrogenation chemistry with mesoporous nanocatalyst systems on nanosupports.",

keywords = "hydrogenation, nitriles in solution phase, wet in situ imaging, nanocatalysts, RESOLUTION ELECTRON-MICROSCOPY, CATALYTIC-HYDROGENATION, NICKEL, OXYGEN, LIQUID, NYLON",

author = "Gai, {P L} and K Kourtakis and Boyes, {E D}",

year = "2005",

month = jul,

doi = "10.1007/s10562-005-5195-5",

language = "English",

volume = "102",

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journal = "Catalysis Letters",

issn = "1011-372X",

publisher = "Springer",

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AU - Gai, P L

AU - Kourtakis, K

AU - Boyes, E D

PY - 2005/7

Y1 - 2005/7

N2 - Wet- environmental transmission electron microscopy studies of heterogeneous hydrogenation of complex nitriles in a liquid phase over new mesoporous cobalt- promoted ruthenium nanocatalysts on reducible nanotitania supports are presented. The desorbed organic products in the dynamic liquid phase hydrogenation are imaged situ on the nanoscale. The direct studies on the "nanocomposite" catalysts are correlated with parallel reaction chemistry measurements. They demonstrate high hydrogenation activity at low operating temperatures in the presence of atomic scale anion vacancy defects associated with Lewis acid sites at the nanosupport surface and an electronic and synergistic contribution to the promoter mechanism. The combined synergistic effect between the two metals and the interaction with the reduced nanosupport leading to an electronic modi. cation lead to highly reactive site for the hydrogenation catalysis. The results illustrate novel selective hydrogenation chemistry with mesoporous nanocatalyst systems on nanosupports.

AB - Wet- environmental transmission electron microscopy studies of heterogeneous hydrogenation of complex nitriles in a liquid phase over new mesoporous cobalt- promoted ruthenium nanocatalysts on reducible nanotitania supports are presented. The desorbed organic products in the dynamic liquid phase hydrogenation are imaged situ on the nanoscale. The direct studies on the "nanocomposite" catalysts are correlated with parallel reaction chemistry measurements. They demonstrate high hydrogenation activity at low operating temperatures in the presence of atomic scale anion vacancy defects associated with Lewis acid sites at the nanosupport surface and an electronic and synergistic contribution to the promoter mechanism. The combined synergistic effect between the two metals and the interaction with the reduced nanosupport leading to an electronic modi. cation lead to highly reactive site for the hydrogenation catalysis. The results illustrate novel selective hydrogenation chemistry with mesoporous nanocatalyst systems on nanosupports.

KW - hydrogenation

KW - nitriles in solution phase

KW - wet in situ imaging

KW - nanocatalysts

KW - RESOLUTION ELECTRON-MICROSCOPY

KW - CATALYTIC-HYDROGENATION

KW - NICKEL

KW - OXYGEN

KW - LIQUID

KW - NYLON

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DO - 10.1007/s10562-005-5195-5

M3 - Article

SN - 1011-372X

VL - 102

SP - 1

EP - 7

JO - Catalysis Letters

JF - Catalysis Letters

IS - 1-2

ER -