Hierarchical tin oxide(SnO2) architectures were synthesized with a facile hydrothermal method. In the hydrothermal synthesis, sodium dodecyl benzene sulfonate(SDBS) surfactant plays an important role as struc- ture-directing reagent. The synthesized samples were characterized by powder X-ray diffraction(XRD), field emis- sion scanning electron microscopy(FESEM), transmission electron microscopy(TEM) and high-resolution transmis- sion electron microscopy(HRTEM). The results clearly reveal that the hierarchical architectures of SnO2 were com- posed of aggregated nanosheets with a thickness of about 100 nm. A possible mechanism for the formation of the SnO2 hierarchical architectures was proposed. In addition, the gas sensing properties of the as-prepared products were investigated and it was found that the sensor based on the special SnO2 hierarchical architectures exhibited a high re- sponse and good selectivity to NO2 at the optimal working temperature of 160 ℃.
This work focuses on the H2 sensing performance of the sensor with buried Au sensing electrode and spi- nel-type oxide CoCrMnO4 insensitive reference electrode within sodium super ionic conductor(NASICON) film. The sensor showed the highest response to H2 gas on the insensitive material sintering at 800 ~C. Compared with those of the traditional structure device, the sensitivity and selectivity of the sensor using buried sensing electrode were greatly improved, giving a response of-177 mV in 9x10 5 g/L H2, which was about 3.5 times higher than that of sensors with traditional structure. Moreover, the AV value of the sensing device exhibited linear relationship to the logarithm of H2 concentration and the sensitivity(slope) was -135 mV/decade. A sensing mechanism related to the mixed potential was proposed for the present sensor.
ZHANG Han SUN Ruize SUN Peng LIANG Xishuang LU Geyu
SnO2-ln2O3 hierarchical microspheres were prepared by the hydrothermal and solvothermal method. The morphology, phase crystallinity of the obtained SnO2-In203 were measured by X-ray diffraetion(XRD), scan electron microscopy(SEM), respectively. A room temperature ozone sensor based on SnO2-In2O3 hierarchical microspheres was fabricated and investigated. The gas sensing properties of the sensor using SnO2-In2O3 strongly depended on the proportion of SnO2 and In2O3. The sensitivity and response/recovery speed were greatly enhanced by UV illumination. A gas sensing mechanism related to oxygen defect was suggested.
SUN Jian-boXU JingWANG BiaoSUN PengLIU Feng-minLU Ge-yu
Cuprous oxide(Cu2O),as an important p-type semiconductor,has been widely investigated due to its high electron transmission and facile preparation.However,the electrode made of only Cu2O has been rarely investigated.In order to demonstrate the possibility that material Cu2O can be applied to the electrode of p-type dye sensitized solar cells(DSSCs),the photo-electrodes made of prepared Cu2O powder and commercial Cu2O particles have been fabricated.The results show that the electrode based on as-prepared Cu2O(Cu2O-2) powder exhibits higher performance than that based on commercial Cu2O(Cu2O-1) particle.The device based on Cu2O-2 electrode reaches into an open-circuit voltage of 0.71 V,a short-circuit current density of 1.3 mA/cm^2,a fill factor(FF) of 46%,and a conversion efficiency of 0.42% measured under AM 1.5G(100 mW/cm^2) illumination.The enhancement performance of Cu2O-2 is attributed to the high dye adsorption of Cu2O-2 compared with that of Cu2O-1.To the best of our knowledge,this is the highest conversion efficiency value reported for solar cells based on Cu2O-DSSC.This work provides that Cu2O is also a candidate for constructing the electrode of p-type dye sensitized solar cells.
DU Sisi CHENG Pengfei SUN Peng WANG Biao CAI Yaxin LIU Fengmin ZHENG Jie LU Geyu
