In the past decades, transition met

In the past decades, transition metal oxide materials have
attracted great attention. Their specific physical and chemical
properties opened great perspectives for their applications in
environmental monitoring and catalysis [1–6]. Among different
transition oxides, ZnO, endowed of a wide direct band gap
(3.37 eV) high exciton energy (60 meV), is one of the most
studied materials due to its mixed covalent/ionic chemical bonds
[7]. Because of its thermal/chemical stability [1], ZnO has been
investigated for the fabrication of chemical sensors. The sensing
mechanism of ZnO conductometric gas sensors is based on the
variation of their electrical conductivity in presence of reducing
and oxidizing gases. At certain temperatures, oxygen adsorbs on
the surface of ZnO as O
ions extracting electrons from ZnO
conduction band and inducing a depletion layer, which leads to
a decrease in the conductivity of the material [7–9]. In the
presence of reducing gases in the atmosphere, they react with
adsorbed O
ions on the surface of ZnO crystals, acting as
donors. Consequently, the concentration of O
ions decreases,
enhancing the conductivity of ZnO [7,8]. The resistance change
mechanism for the detection of explosive, hazardous and toxic
gases is at the base of the working principle of metal oxide
chemical sensors [1]. To enhance the interaction between ZnO
and oxidizing or reducing gases and to improve its response, the
material is heated up to 500 1C [10,11]. Since the response of
the chemical sensor depends on the surface reaction between
structure and gas molecules, the structure shape and the size are
critical parameters for sensing materials [12–14]. Numerous
studies have been carried out to find the optimal morphology
and the crystallographic structure of ZnO-based chemical
sensors, using different preparation techniques [12,13,15–17].
Investigations showed that ZnO has a very high sensitivity,
mainly towards ethanol and acetone [18–25]. Due to this reason,
the enhancement of the sensitivity of ZnO towards H2, CH4,
H2S, NO2, etc. remains a big challenge. Literature showed that
the increase in the surface area the functionalization with noble
metals and the doping of nanostructured ZnO have proven to be
beneficial for the improvement of its sensitivity [13,22,26–32].
Herein, we report a new type of nanostructured ZnO
chemical sensor prepared through a simple and cost effective
technology. The structure consists of nanoparticles connected
to each other and forming chains with a few microns length.
Compared to other methods, the reported preparation process
is quite simple and efficient: only thin films of metallic zinc