The impact of surface Cu2+ of ZnO/(Cu1−xZnx)O heterostructured nanowires on the adsorption and chemical transformation of carbonyl compounds

The impact of surface Cu2+ of ZnO/(Cu1−xZnx)O heterostructured nanowires on the adsorption and chemical transformation of carbonyl compounds

The surface cation composition of nanoscale metal oxides critically determines the properties of various functional chemical processes including inhomogeneous catalysts and molecular sensors. Here we employ a gradual modulation of cation composition on a ZnO/(Cu1−xZnx)O heterostructured nanowire sur...

Full description

Saved in:
Bibliographic Details
Published in:Chemical science (Cambridge) Vol. 12; no. 14; pp. 5073 - 5081
Main Authors: Liu, Jiangyang, Nagashima, Kazuki, Nagamatsu, Yuki, Hosomi, Takuro, Saito, Hikaru, Wang, Chen, Mizukami, Wataru, Zhang, Guozhu, Samransuksamer, Benjarong, Takahashi, Tsunaki, Kanai, Masaki, Yasui, Takao, Baba, Yoshinobu, Yanagida, Takeshi
Format: Journal Article
Language:English
Published: Cambridge Royal Society of Chemistry 01-01-2021
The Royal Society of Chemistry
Subjects:
Adsorption
Aldehydes
Biomarkers
Carbonyl compounds
Carbonyls
Cations
Chemical compounds
Chemical reactions
Chemistry
Composition effects
Control surfaces
Copper
Metal oxides
Nanowires
Recovery time
Surface chemistry
Zinc oxide
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The surface cation composition of nanoscale metal oxides critically determines the properties of various functional chemical processes including inhomogeneous catalysts and molecular sensors. Here we employ a gradual modulation of cation composition on a ZnO/(Cu1−xZnx)O heterostructured nanowire surface to study the effect of surface cation composition (Cu/Zn) on the adsorption and chemical transformation behaviors of volatile carbonyl compounds (nonanal: biomarker). Controlling cation diffusion at the ZnO(core)/CuO(shell) nanowire interface allows us to continuously manipulate the surface Cu/Zn ratio of ZnO/(Cu1−xZnx)O heterostructured nanowires, while keeping the nanowire morphology. We found that surface exposed copper significantly suppresses the adsorption of nonanal, which is not consistent with our initial expectation since the Lewis acidity of Cu2+ is strong enough and comparable to that of Zn2+. In addition, an increase of the Cu/Zn ratio on the nanowire surface suppresses the aldol condensation reaction of nonanal. Surface spectroscopic analysis and theoretical simulations reveal that the nonanal molecules adsorbed at surface Cu2+ sites are not activated, and a coordination-saturated in-plane square geometry of surface Cu2+ is responsible for the observed weak molecular adsorption behaviors. This inactive surface Cu2+ well explains the mechanism of suppressed surface aldol condensation reactions by preventing the neighboring of activated nonanal molecules. We apply this tailored cation composition surface for electrical molecular sensing of nonanal and successfully demonstrate the improvements of durability and recovery time as a consequence of controlled surface molecular behaviors.
Bibliography:ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:2041-6520
2041-6539
DOI:10.1039/d1sc00729g