Facile water-assisted synthesis of cupric oxide nanourchins and their application as nonenzymatic glucose biosensor

Shaodong Sun; Xiaozhe Zhang; Yuexia Sun; Shengchun Yang; Xiaoping Song; Zhimao Yang

doi:10.1021/am400858j

Facile water-assisted synthesis of cupric oxide nanourchins and their application as nonenzymatic glucose biosensor

Shaodong Sun
, Xiaozhe Zhang
, Yuexia Sun
, Shengchun Yang
, Xiaoping Song
, Zhimao Yang

School of Physics

Xi'an Jiaotong University

Research output: Contribution to journal › Article › peer-review

123 Scopus citations

Abstract

We have demonstrated an interesting approach for the one-pot synthesis of cupric oxide (CuO) nanourchins with sub-100 nm through a sequential dissolution-precipitation process in a water/ethanol system. The first stage produces a precursory crystal [Cu₇Cl₄(OH) ₁₀H₂O] that is transformed into monoclinic CuO nanourchins during the following stage. Water is a required reactant for the morphology-controlled growth of different CuO nanostructures. When evaluated for their nonenzymatic glucose-sensing properties, these CuO nanourchins manifest higher sensitivity. Significantly, this water-dependent precursor transformation method may be widely used to effectively control the growth of other metal oxide nanostructures.

Original language	English
Pages (from-to)	4429-4437
Number of pages	9
Journal	ACS Applied Materials and Interfaces
Volume	5
Issue number	10
DOIs	https://doi.org/10.1021/am400858j
State	Published - 22 May 2013

Keywords

copper oxide
nanourchins
nonenzymatic glucose sensor
water/ethanol

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10.1021/am400858j

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title = "Facile water-assisted synthesis of cupric oxide nanourchins and their application as nonenzymatic glucose biosensor",

abstract = "We have demonstrated an interesting approach for the one-pot synthesis of cupric oxide (CuO) nanourchins with sub-100 nm through a sequential dissolution-precipitation process in a water/ethanol system. The first stage produces a precursory crystal [Cu7Cl4(OH) 10H2O] that is transformed into monoclinic CuO nanourchins during the following stage. Water is a required reactant for the morphology-controlled growth of different CuO nanostructures. When evaluated for their nonenzymatic glucose-sensing properties, these CuO nanourchins manifest higher sensitivity. Significantly, this water-dependent precursor transformation method may be widely used to effectively control the growth of other metal oxide nanostructures.",

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author = "Shaodong Sun and Xiaozhe Zhang and Yuexia Sun and Shengchun Yang and Xiaoping Song and Zhimao Yang",

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T1 - Facile water-assisted synthesis of cupric oxide nanourchins and their application as nonenzymatic glucose biosensor

AU - Sun, Shaodong

AU - Zhang, Xiaozhe

AU - Sun, Yuexia

AU - Yang, Shengchun

AU - Song, Xiaoping

AU - Yang, Zhimao

PY - 2013/5/22

Y1 - 2013/5/22

N2 - We have demonstrated an interesting approach for the one-pot synthesis of cupric oxide (CuO) nanourchins with sub-100 nm through a sequential dissolution-precipitation process in a water/ethanol system. The first stage produces a precursory crystal [Cu7Cl4(OH) 10H2O] that is transformed into monoclinic CuO nanourchins during the following stage. Water is a required reactant for the morphology-controlled growth of different CuO nanostructures. When evaluated for their nonenzymatic glucose-sensing properties, these CuO nanourchins manifest higher sensitivity. Significantly, this water-dependent precursor transformation method may be widely used to effectively control the growth of other metal oxide nanostructures.

AB - We have demonstrated an interesting approach for the one-pot synthesis of cupric oxide (CuO) nanourchins with sub-100 nm through a sequential dissolution-precipitation process in a water/ethanol system. The first stage produces a precursory crystal [Cu7Cl4(OH) 10H2O] that is transformed into monoclinic CuO nanourchins during the following stage. Water is a required reactant for the morphology-controlled growth of different CuO nanostructures. When evaluated for their nonenzymatic glucose-sensing properties, these CuO nanourchins manifest higher sensitivity. Significantly, this water-dependent precursor transformation method may be widely used to effectively control the growth of other metal oxide nanostructures.

KW - copper oxide

KW - nanourchins

KW - nonenzymatic glucose sensor

KW - water/ethanol

UR - https://www.scopus.com/pages/publications/84878284649

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DO - 10.1021/am400858j

M3 - 文章

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AN - SCOPUS:84878284649

SN - 1944-8244

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JO - ACS Applied Materials and Interfaces

JF - ACS Applied Materials and Interfaces

IS - 10

ER -

Facile water-assisted synthesis of cupric oxide nanourchins and their application as nonenzymatic glucose biosensor

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