NiO–ZnO Nanoheterojunction Networks for Room‐Temperature Volatile Organic Compounds Sensing

Chen, Hongjun; Bo, Renheng; Shrestha, Aabhash; Xin, Bobo; Nasiri, Noushin; Zhou, Jin; Bernardo, Iolanda Di; Dodd, Aaron; Saunders, Martin; Lipton‐Duffin, Josh; White, Thomas P.; Tsuzuki, Takuya; Tricoli, Antonio

doi:10.1002/adom.201800677

Cited by 60 publications

(81 citation statements)

References 43 publications

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“…Specifically, both samples conserve the highest sensitivity and goodness of sensor signal towards acetone molecules, rather than toluene gas. However, interestingly, the 32:1 TiO 2 /GO sample exhibits a "reversed" behavior in the case of small and polar molecules, such as acetone (Figure 5f), maybe caused by the interaction between the moisture adsorbed on the sensing material highly-hydrophilic surface [60] and the VOC molecules, and this is lost when the operating temperature is above the water condensation point, as reported by Tricoli et al [65]. Overall, the tailoring of titanium ions into tin dioxide matrix alongside with the integration of graphene oxide into the metal oxides could be exploited for the engineering of materials with higher sensing performances, especially in terms of selectivity to different VOC species.…”

Section: Vocs (Toluene and Acetone) Sensingsupporting

confidence: 58%

Exploring SnxTi1−xO2 Solid Solutions Grown onto Graphene Oxide (GO) as Selective Toluene Gas Sensors

et al. 2020

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The major drawback of oxide-based sensors is the lack of selectivity. In this context, Sn x Ti 1−x O 2 /graphene oxide (GO)-based materials were synthesized via a simple hydrothermal route, varying the titanium content in the tin dioxide matrix. Then, toluene and acetone gas sensing performances of the as-prepared sensors were systematically investigated. Specifically, by using 32:1 SnO 2 /GO and 32:1 TiO 2 /GO, a greater selectivity towards acetone analyte, also at room temperature, was obtained even at ppb level. However, solid solutions possessing a higher content of tin relative to titanium (as 32:1 Sn 0.55 Ti 0.45 O 2 /GO) exhibited higher selectivity towards bigger and non-polar molecules (such as toluene) at 350 • C, rather than acetone. A deep experimental investigation of structural (XRPD and Raman), morphological (SEM, TEM, BET surface area and pores volume) and surface (XPS analyses) properties allowed us to give a feasible explanation of the different selectivity. Moreover, by exploiting the UV light, the lowest operating temperature to obtain a significant and reliable signal was 250 • C, keeping the greater selectivity to the toluene analyte. Hence, the feasibility of tuning the chemical selectivity by engineering the relative amount of SnO 2 and TiO 2 is a promising feature that may guide the future development of miniaturized chemoresistors.

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Section: Vocs (Toluene and Acetone) Sensingsupporting

confidence: 58%

Exploring SnxTi1−xO2 Solid Solutions Grown onto Graphene Oxide (GO) as Selective Toluene Gas Sensors

et al. 2020

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“…Figure a–c depicts the X‐ray diffraction patterns of the ZnO thin films on glass substrates as a function of annealing temperatures. It is clear that the ZnO thin films are polycrystalline with diffraction peaks located at 31.9°, 34.5°, 36.3°, 56.7°, corresponding to the crystal planes of (100) (002) (101) (110), respectively . Obviously, the crystallinity was effectively enhanced with the increase of annealing temperature from 200 to 400 °C.…”

mentioning

confidence: 99%

ZnO‐Based Ultraviolet Photodetectors with Tunable Spectral Responses

Zheng

Wang

et al. 2019

Physica Rapid Research Ltrs

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Conventionally, wavelength‐selective ultraviolet photodetection is achieved by using broadband inorganic photodiodes coupled with optical filters, which significantly increases the complexity and fabricating cost of devices for high pixel density imaging systems. Here, a facile approach to achieve tunable spectral response without filters is demonstrated. The devices are based on ZnO heterojunctions, and the response spectra are effectively modulated by tuning the position of charge generation, which results in distinct charge‐collection efficiencies. After optimization, the ZnO/poly[bis(4‐phenyl)(2,4,6‐trimethylphenyl)amine] (PTAA) photodiodes exhibit narrowband ultraviolet (UV) response with a full width at half maximum (FWHM) of <25 nm, and the NiOx/ZnO devices reveal relatively broader photoresponse. All of these devices demonstrate relatively low dark currents and noises, high responsivities and detectivities, and fast response speeds. This work proves the great potential of ZnO thin films for UV detection and also first provides an alternative approach to effectively tune the spectral response.

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“…Up to now, many working groups tried to improve the gas sensing properties of ZnO-based gas sensors by construction p - n heterojunctions. For example, Chen et al reported the fabrication of ultraporous ZnO/NiO heterojunction networks using flame synthesis and aerosol self-assemble, and studied their gas sensitivity toward volatile organic compounds (VOC) gas [ 23 ]. The reported results demonstrated that the ZnO/NiO nanoparticle networks demonstrated excellent sensitivity to acetone and ethanol gas.…”

Section: Introductionmentioning

confidence: 99%

NH3 Sensor Based on 3D Hierarchical Flower-Shaped n-ZnO/p-NiO Heterostructures Yields Outstanding Sensing Capabilities at ppb Level

Zhao

Yang

Wei

et al. 2020

Sensors

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Hierarchical three-dimensional (3D) flower-like n-ZnO/p-NiO heterostructures with various ZnxNiy molar ratios (Zn5Ni1, Zn2Ni1, Zn1Ni1, Zn1Ni2 and Zn1Ni5) were synthesized by a facile hydrothermal method. Their crystal phase, surface morphology, elemental composition and chemical state were comprehensively investigated by XRD, SEM, EDS, TEM and XPS techniques. Gas sensing measurements were conducted on all the as-developed ZnxNiy-based sensors toward ammonia (NH3) detection under various working temperatures from 160 to 340 °C. In particular, the as-prepared Zn1Ni2 sensor exhibited superior NH3 sensing performance under optimum working temperature (280 °C) including high response (25 toward 100 ppm), fast response/recovery time (16 s/7 s), low detection limit (50 ppb), good selectivity and long-term stability. The enhanced NH3 sensing capabilities of Zn1Ni2 sensor could be attributed to both the specific hierarchical structure which facilitates the adsorption of NH3 molecules and produces much more contact sites, and the improved gas response characteristics of p-n heterojunctions. The obtained results clear demonstrated that the optimum n-ZnO/p-NiO heterostructure is indeed very promising sensing material toward NH3 detection for different applications.

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NiO–ZnO Nanoheterojunction Networks for Room‐Temperature Volatile Organic Compounds Sensing

Cited by 60 publications

References 43 publications

Exploring SnxTi1−xO2 Solid Solutions Grown onto Graphene Oxide (GO) as Selective Toluene Gas Sensors

Exploring SnxTi1−xO2 Solid Solutions Grown onto Graphene Oxide (GO) as Selective Toluene Gas Sensors

ZnO‐Based Ultraviolet Photodetectors with Tunable Spectral Responses

NH3 Sensor Based on 3D Hierarchical Flower-Shaped n-ZnO/p-NiO Heterostructures Yields Outstanding Sensing Capabilities at ppb Level

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