Synthesis of CuO/ZnWO₄ Heterojunction Structure for H₂S Gas Sensor with Ultra-High Response Value at Room Temperature

Abstract

H₂S detection is critical for personal and industrial safety. Generally, metal oxide-based H₂S sensors exhibit no response at room temperature (RT). In this study, CuO/ZnWO₄ (C-ZWO) nanocomposites were prepared via a two-step hydrothermal process and applied to RT H₂S sensing. The results show that the C-ZWO sensors exhibit an elevated response value at RT and balanced gas-sensing properties at 100 °C. Significantly, the response value of a 10% C-ZWO sensor to 25 ppm of H₂S at RT is 651.6 with a response time of 78 s, which is 310.3 times that of the ZnWO₄ sensor (2.1). The systemic characterization results suggest that the enhanced RT H₂S-sensing properties are ascribed to the synergistic effects of the growth-specific surface area and oxygen vacancy occupancy, the enhanced oxygen reduction ability, and the formation of the p–n heterojunction structure between CuO and ZnWO₄. The C-ZWO nanocomposites possess added active sites for H₂S adsorption and dissociation, with the p–n heterojunction giving rise to higher electrical resistance, and thus, the follow-up produces a high response value even at RT.

1. Introduction

H₂S, a significant chemical, is used in metal refining, pesticides, pharmaceuticals, and catalyst regeneration [1]. However, H₂S is a flammable, hazardous gas, i.e., it can form an explosive mixture with air, and lead to combustion and explosion with an open flame, high heat, or an electric spark [2]. Also, H₂S is incredibly toxic, and human inhalation of H₂S gas can cause headaches, anxiety, memory loss, olfactory paralysis, respiratory failure, and even death [2,3]. The Immediately Dangerous To Life or Health (IDLH) concentration of H₂S is 100 ppm. The industry-recommended exposure limit for H₂S gas is 10 ppm [4,5]. As a hazardous gas, H₂S is generated in large amounts during various industrial production processes. Additionally, H₂S is present in environments such as mines, ship holds, and septic tanks [6]. Therefore, real-time detection of H₂S leaks and concentrations is necessary to ensure personal safety and reduce property damage. The most commonly used methods for detecting H₂S include fluorescent probes [7,8], indicator paper [9], etc. Their drawbacks are the complexity of the detection method, the long detection time, and the inaccurate detection of concentration values. Therefore, developing low-cost and straightforward H₂S sensors is imperative.

Gas sensors have broad applications in industrial production and daily life, including the detection of explosives [10] and toxic gases [11], volatile chemicals [12], medical detection [13,14], and environmental pollution monitoring [15,16]. Among a wide variety of materials, metal oxide semiconductors (MOSs) are considered an ideal candidate for gas-sensing materials due to their unique strengths, such as fast response, good stability, simplicity, lightness, low cost, and simple integration [17,18]. CuO is a p-type semiconductor (bandgap, E_g~1.2–1.5 eV) [19], which has been reported to have excellent selectivity for H₂S, but it has some limitations in its development and application due to its drawbacks, such as slow response [20] and low sensitivity [21]. However, it was found that the H₂S sensitivity of the material can be increased substantially by doping CuO in MOSs with a wide bandgap to construct heterojunctions, and it has excellent selectivity for H₂S. Zhang et al. [22] prepared Cu-doped In₂O₃ hollow nanofibers via electrospinning. The response value to 50 ppm H₂S at 250 °C increased by more than 20 times, reaching 350.7. Of note, the response value (S) is the ratio of the resistance of the sensor in the air (R_g) to the resistance in the target gas (R_g); S = R_a/R_g [10,12,23,24]. A high response value indicates a good gas-sensing property. Wang et al. [25] synthesized CuO/WO₃ hollow microspheres; the response value to 10 ppm H₂S at 70 °C increased by more than 10³ times compared with that of WO₃. The materials doped with CuO exhibit excellent selectivity, in addition to a substantial increase in sensitivity; one of the reasons for this is related to the formation of the metallic phase of CuS upon contact between CuO and H₂S [10,22,25].

ZnWO₄, a scheelite n-type semiconductor with a unique ABO₄ structure [26,27,28], is a metallic tungstate with a low crystallographic symmetry monoclinic wolframite structure (E_g~3.37 eV) that poses a considerable obstacle to electron mobility [29]. However, because of its low cost, high chemical stability, non-toxicity, relatively high catalytic activity, scintillation, and magnetic and luminescent properties [30], ZnWO₄ has been widely reported in the last few years in the fields of photocatalysis [31], photoelectrodes [32], capacitors [33], and electrochemistry [34]. The reported ZnWO₄ sensors have only been used for the detection of acetone [30] and triethylamine [35,36]. Zang et al. [37] synthesized the ZnO@ZnWO₄ heterojunction H₂S sensor, exhibiting a response of 127.31 to 5 ppm H₂S at 200 °C. Hu et al. [38] reported the ZnWO₄/WO₃ heterojunction for trace H₂S detection with 0.0783 ppm at 310 °C. However, a high operating temperature poses an extra risk for the stability of H₂S-sensing materials and sensors. There are few reports on the construction of p–n anisotype junctions (heterostructures) of CuO and ZnWO₄ for H₂S detection, especially at RT, which holds promise for research and application prospects. Herein, a combined hydrothermal-calcination process was carried out to construct CuO and ZnWO₄ heterostructures, and the RT and low-temperature H₂S gas-sensing properties and H₂S-sensing mechanisms of CuO-ZnWO₄ (C-ZWO) nanocomposites were studied for the first time. The results show that the construction of CuO-ZnWO₄ heterojunctions can significantly improve H₂S-sensing performances, and the selectivity is effectively improved.

2. Materials and Methods

2.1. Material

All chemical reagents (analytical-grade purity) involved in the experiments were used directly without further purification. CuO-ZnWO₄ composite materials were prepared by a combined hydrothermal-calcination method, the details of which are provided in the Supplementary Materials. The four materials with specific molar percentages (0, 5, 10, and 15 mol%) of CuO were named 0% C-ZWO, 5% C-ZWO, 10% C-ZWO, and 15% C-ZWO, respectively (Table S1).

2.2. Characterization

The samples were characterized by X-ray diffraction (XRD), Scanning electron microscopy (SEM), Energy-dispersive X-ray spectroscopy (EDS), Transmission electron microscopy (TEM), X-ray photoelectron spectroscopy (XPS), Ultraviolet photoelectron spectroscopy (UPS), the Micromeritics ASAP 2460 specific surface and porosity analyzer, and Oxygen Reduction Reaction (ORR) measurements. The details are provided in the Supplementary Materials.

2.3. Fabrication and Measurement of the C-ZWO Gas Sensors

The details of the preparation and measurement of the C-ZWO H₂S sensors are provided in the Supplementary Materials, as reported in our previous work [39]. The sensor response value is defined as the ratio of the resistance of the sensor in air to the resistance in the target gas (S = R_a/R_g) [10,12,23,24], which corresponds to the output voltage (U_out) changes in the H₂S-sensing measurement process (Figure 1). The response time and recovery time are defined as the time taken by the sensor to reach 90% of the total resistance change [40,41] in the case of adsorption and desorption, respectively. The working temperature is defined and obtained by adjusting the heating voltage (U_h) (Figure 1).

3. Results and Discussion

3.1. Structural and Morphological Analysis

3.1.1. Phase and Microstructure Analysis

Figure 2a shows the XRD patterns of the prepared C-ZWO composites and the CuO sample. The diffraction peaks at 18.90°, 23.81°, 24.52°, 30.45°, 30.70°, 48.74°, 53.64°, and 64.76° correspond to the (100), (011), (110), (−111), (111), (022), (−202), and (−132) crystal planes of monoclinic ZnWO₄ (JCPDS card No. 89-0447) [31,42], respectively. The other weak peaks between 42° and 52° can also be indexed to ZnWO₄, compared with the standard diffraction peaks of ZnWO₄ (JCPDS card No. 89-0447). Generally, the firm diffraction peaks suggest that the prepared ZnWO₄ and CuO-ZnWO₄ samples are highly crystalline [29,36,43]. Meanwhile, the diffraction peaks of the obtained CuO sample correspond to CuO (JCPDS card No. 80-0076). It was proved that CuO was successfully prepared by this experimental process, as provided in the Supplementary Materials. However, the indeterminate peaks belonging to CuO within the C-ZWO composites may be attributed to the low amount and low diffraction intensity of CuO.

However, as Figure 2b shows, with an increase in the amount of CuO, the (111) peaks shift slightly to the right compared with 0% C-ZWO. One possible reason is that the ionic radius of Cu (0.72 Å (Cu²⁺)) is slightly smaller than that of Zn (0.74 Å (Zn²⁺)). Thus, the crystal interplanar spacing will be smaller when Cu²⁺ is mixed into the lattice of Zn²⁺, leading to the right shift of the diffraction angle based on the Bragg Equation [44,45]. Basically, the shift of (111) peaks indicates that the compound degree of the Cu-based compound and ZnWO₄ changes, which may be due to the impurities in the C-ZWO composites. In addition, compared with the 0% C-ZWO sample, the peaks between 60° and 70° of the 5%, 10%, and 15% C-ZWO composites broaden slightly, which may be due to the impurities in the C-ZWO composites mentioned above. Further analysis needs to follow to distinguish the existence form of the Cu-based compound.

As can be observed in the SEM and TEM images in Figure S1 and Figure 3a, the synthesized samples are mainly composed of irregular particles with particle sizes less than 50 nm, and the smallest can reach 20–30 nm. Basically, a smaller grain size implies a larger surface area and, thus, more active sites for H₂S adsorption, which improves the sensitivity [10]. The HRTEM images (Figure 3b and insets) exhibit the crystal plane spacings of 0.293 and 0.228 nm, attributed to the (−111) crystal plane of ZnWO₄ and the (200) crystal plane of CuO, respectively, confirming the CuO and ZnWO₄ in the 10% C-ZWO sample.

3.1.2. Elemental and Valence Analysis

The elemental and valence were analyzed by EDS and XPS measurements. The atomic number ratio obtained for Zn and W is close to 1:1 according to the EDS results (Figure S2 and Table S2). Meanwhile, the elemental mapping analysis of 10% C-ZWO from Figure S2b,f confirms that the elements of W, O, Zn, and Cu are homogeneously distributed in the material. Combined with the HRTEM results, it can be preliminarily confirmed that we successfully synthesized pure ZnWO₄ and CuO-ZnWO₄ composites via the hydrothermal-calcination method.

As shown in Figure 4a, the full XPS spectra exhibit that Zn, W, and O existed in the 0%C-ZWO sample, while Zn, W, O, and Cu existed in the 10%C-ZWO sample. The representative peaks at 1018 and 1041 eV correspond to Zn 2p_3/2 and Zn 2p_1/2 [31], respectively (Figure 4b). Two binding energy peaks appear at 32.9 and 34.8 eV for W 4f_7/2 and W 4f_5/2, respectively (Figure 4c), which determines the existence of W [46]. The two peaks located at 931.0 and 951.1 eV are related to Cu 2p_3/2 and Cu 2p_1/2 (Figure 4d), respectively, indicating the Cu (II) oxidation state of CuO [10,47].

As exhibited in Figure 4e,f, the peaks of the 0% and 10% C-ZWO samples located at 527.5, 529.0 ± 0.1, and 530.6 ± 0.1 eV of O 1s correspond to lattice oxygen (O_L) (light brown in Figure 4e,f), oxygen vacancies (O_V) (light blue in Figure 4e,f), and chemisorbed oxygen species (O_C) (light green in Figure 4e,f) [48], correspondingly. The relative percentages of O_L, O_V, and O_C in the 0% C-ZWO were 51.0%, 28.5%, and 20.5%, respectively, while the relative percentages were 49.6%, 33.5%, and 19.9% in 10% C-ZWO. Notably, the increased O_V of the 10% C-ZWO sample implies growing potential sites for gas adsorption and chemical reactions, thus enhancing its sensing performance [49].

3.1.3. Specific Surface Areas and Porosity Analysis

The significant effects of the porous structures on the H₂S-sensing property based on CuO-ZnWO₄ nanocomposites were studied, as exhibited in Figure 5. When the relative pressure varies from 0.8 to 1.0, the hysteresis loops are associated with typical IV-type curves with mesoporous structures [50]. All the samples show a broad pore size distribution, ranging from 1 to 70 nm. The average pore width of 0%, 5%, 10%, and 15% C-ZWO was 33.6, 32.2, 33.4, and 32.1 nm, respectively. The specific surface areas (S_BET) calculated from the BET method were 12.08, 13.47, 12.41, and 12.27 m²g⁻¹, respectively. The results show an increase in the S_BET of the prepared nanoparticle composites compared to 0% C-ZWO after introducing CuO. Moreover, the large S_BET and porous nanostructure may facilitate the adsorption and transport of the reaction medium [51], which is consistent with the increased O_V results in the XPS analysis.

3.2. H₂S-Sensing Properties

3.2.1. Effects of Temperature and Composite Ratios on H₂S-Sensing Response Properties

Figure 6 shows the response of the C-ZWO sensors tested at temperatures ranging from 25 °C to 100 °C. The response of the 0% C-ZWO sensor to 25 ppm H₂S at 25 °C is 2.1, while the responses of the 5%, 10%, and 15% C-ZWO sensors are 426.9, 651.6, and 161.6, respectively. It is demonstrated that ZnWO₄ substantially improves the gas-sensing response of ZnWO₄ for H₂S after being combined with CuO. The enhancement in the response may be due to the increase in the active sites of the C-ZWO composite materials and the construction of the p-n heterojunction of CuO with ZnWO₄. With the increasing CuO contents, the response of the C-ZWO composites increased dramatically, and the response of the material to H₂S reached a maximum of 310.3 times that of the pristine ZnWO₄ when the molar proportion of CuO was 10%. However, when the molar proportion of CuO was 15%, the response of the C-ZWO composite to H₂S became lower, which might be the result of the excess CuO covering the H₂S active sites on the surface of the C-ZWO composites. More importantly, H₂S can interact with CuO, producing CuS in accordance with the reaction CuO + H₂S = H₂O + CuS, with the excess consumption of CuO leading to the lower response of the 15% C-ZWO sensor.

When the temperature increased from 25 °C to 100 °C, the response of the three composite C-ZWO sensors showed a significant decrease. The responses of the 0%, 5%, 10% and 15% C-ZWO sensors are 3.5, 13.5, 22.9, and 17.7, respectively. This is attributed to the fact that the adsorption capacity of the H₂S molecules was lower than the desorption capacity at high temperatures, resulting in reduced amounts of test molecules involved in the surface reaction. Although the sensitivity of the 0% C-ZWO sensor increases slightly, it is still lower than the sensitivity of the C-ZWO composite sensors. The excellent room temperature sensing performances of the C-ZWO composite sensors, especially the 10% C-ZWO sample, indicate their significant application potential in the field of H₂S room temperature sensing.

3.2.2. Effects of Temperature and Composite Ratios on Gas-Sensing Response and Recovery Performances

The dynamic sensing transients of materials towards H₂S detection are further investigated to verify the response and recovery times. Typical response–recovery curves of the composite gas sensors towards 25 ppm H₂S at RT and 100 °C are shown in Figure 7 and Figure 8 (the shaded area is their response time or recovery time), respectively. The response time of 0%, 5%, 10% and 15% C-ZWO sensors at RT is 82, 114, 78, and 62 s, respectively. The response time of 0%, 5%, 10% and 15% C-ZWO sensors at 100 °C is 91, 80, 60, and 23 s, respectively. The C-ZWO composite sensors at RT and 100 °C both exhibit a faster response with the increase in the CuO contents.

However, most of the sensors at both RT and 100 °C recover slowly (Figure 7 and Figure 8). Notably, at 100 °C, the 0% C-ZWO and 5% C-ZWO sensing recovered 90% in 180 and 138 s (Figure 8a,b), which fulfils the sensor recovery time criteria. The poor recovery of the sensors is mainly due to the low temperature and slow desorption of the gas. To solve the problem of the recoverability of C-ZWO sensors, a method of autonomous recovery and then heating was adopted in the testing process (Figure 7a–d and Figure 8c,d). As shown in Figure 1, the heating voltage (U_h) works as the working heating power supply of the sensing measure system. By adjusting the U_h as 4.58 V, the sensors reached 300 °C and fully recovered in a short period (as indicated by the arrows in Figure 7a–d and Figure 8c,d). We concluded that in the actual application of the process, we applied a 4.58 V short voltage pulse to recover the sensor. The reason for the fluctuation under the voltage/heating pulse may need further study in the future.

In summary, the 10% C-ZWO sensor at RT exhibits a balanced response of 651.6 and a response time of 78 s, while the 5% C-ZWO sensor at 100 °C shows potential with a response of 13.5 and a response and recovery time of 80 and 138 s, respectively. Notably, applying a 4.58 V short voltage pulse, i.e., heating it at 300 °C, could help to recover the other sensors quickly in potential applications (Table S3).

3.2.3. Effects of H₂S Concentration on Gas-Sensing Properties at 100 °C

The effects of H₂S concentration on H₂S-sensing properties operating in a continuous cycle at 100 °C are shown in Figure 9 and Figure 10, respectively. As shown in Figure 8, compared with the 0% C-ZWO sensor, the three C-ZWO composite sensors all show increased responses as the gas concentration increases. It is noted that the 10% C-ZWO sample exhibits the highest response. The sensors also exhibited good recovery at low H₂S concentrations (10 ppm and lower), as exhibited in Figure 9.

Notably, the sensitivity of the sensors does not increase by a factor of the H₂S concentration, stemming from the fact that the active sites on the surface of gas-sensitive materials are limited. Thus, the adsorption and decomposition of H₂S on the surface of the C-ZWO composites are also limited. As shown in Figure 10b, the 5% C-ZWO sensor exhibits the best stability and recovery. The 10% C-ZWO sensor, despite slightly fluctuating, exhibits the best response to different concentrations of H₂S, as shown in Figure 10c, and its lowest limit detection is 1 ppm.

3.2.4. The Stability and Repeatability of the Sensors at 100 °C

To explore the stability and repeatability of the sensors, the response curves for five consecutive cycles to 25 ppm H₂S at 100 °C were tested. As exhibited in Figure 11, the 0%, 5%, and 10% C-ZWO sensors show smooth dynamic responses. In particular, the 5% C-ZWO sensor has the best stability and recovery, making its application at 100 °C promising. Meanwhile, the recovery of the sensors deteriorates with the increase in CuO content within the same recovery time, and the repeated curve of the 15% C-ZWO sensor shows noticeable fluctuation and attenuation, which may primarily be because it takes a long time for the CuS to recover to CuO in the air at 100 °C [52].

In addition to the short-term multiple response tests, we also tested the sensor performance over four weeks. A set of results was measured every 7 days (Figure 12). After four weeks (at optimum operation temperature), the sensors based on the 5% C-ZWO and 10% C-ZWO samples have good, acceptable long-term stability, which shows good potential for further applications.

3.2.5. The Selectivity of the Typical C-ZWO Sensors

The selectivity study was performed using typical C-ZWO sensors with optimal H₂S-sensing performance at RT and 100 °C, respectively. To evaluate the selectivity performance of the 10% C-ZWO, we tested its response to five gases or vapors in addition to H₂S, i.e., NH₃, ethylene glycol, ethanol, methanol, and acetone (Figure 13). As exhibited in Figure 12a, the response of 10% C-ZWO to 25 ppm H₂S gas is 651.61, while the response to 100 ppm NH₃, ethylene glycol, ethanol, methanol, and acetone gas is 13.32, 3.22, 1.91, 1.50, and 1.40, respectively. The 10% C-ZWO sensor has a far smaller response to other gases than to H₂S gas. Meanwhile, as exhibited in Figure 12b, the response of 5% C-ZWO to 25 ppm H₂S at 100 °C is 13.50, while the response to 100 ppm ethylene glycol, ethanol, methanol, and acetone gas is 3.33, 1.67, 1.65, and 1.64, respectively. Both sensors exhibit the highest selectivity and response to H₂S.

3.3. H₂S-Sensing Mechanism

3.3.1. H₂S-Sensing Process of the C-ZWO Sensors

In n-type MOSs, the potential barrier depends on the depletion layer formed due to the dissociation and adsorption of oxygen molecules and electron transport [37,53,54]. That is, electrons are released back into the conduction band (CB) and the conductance of the ZnWO₄ increases. However, it has been found that the sensing performance of the ZnWO₄ sample is not outstanding, i.e., a single sensing mechanism has little influence on the resistance of the C-ZWO composite sensing materials. More details are shown in the Supplementary Materials (Figure S3). When CuO was loaded onto ZnWO₄, the gas-sensing properties of the composites were substantially enhanced, and the proposed H₂S-sensing response mechanism diagram is shown in Figure S4.

Regarding the H₂S gas composite surface, in addition to reacting with adsorbed Oⁿ⁻ (O₂⁻, O²⁻, and O⁻), it has been demonstrated that when the sensor is exposed to H₂S, a CuS layer may form on the CuO surface [55], with a spontaneous chemical reaction as in Equation (S6). When H₂S is removed by introducing air, CuS is unstable and can be slowly oxidized by O₂ in air (Equation (S7)). Therefore, recovery of the resistance will occur.

The chemical molecular change from CuO to metallic CuS affects the depletion region at the CuO/ZnWO₄ boundary, smothering the conductive channel within the particles [56]. The fracture of p/n junctions in the nanostructures after exposure to H₂S effectively broadened the conducting portion, leading to a significant increase in conductivity [56]. ZnWO₄ loaded with CuO improves the sensitivity and also enhances the selectivity of the material to H₂S gas.

3.3.2. Oxygen Reduction Reaction Analysis

The ORR test explored the effect of CuO loading on the oxygen reduction capacity of ZnWO₄, and the oxygen reduction curves obtained are shown in Figure S5. The oxygen reduction ability of the material was investigated by exploring the change in the initial potential of the material before and after the recombination of ZnWO₄ and CuO. The starting potential is an important indicator to characterize the strength of the material’s oxygen reduction ability; that is, the higher the initial potential, the stronger the oxygen reduction ability of the C-ZWO composites, and the lower the initial potential, the weaker the oxygen reduction ability of the C-ZWO composites.

The starting potentials of 0%, 5%, 10%, and 15% C-ZWO nanocomposites are 0.728, 0.736, 0.746, and 0.752 eV, respectively, and the initial potentials increase gradually. The results indicate that the recombination of CuO enhances the oxygen reduction ability of ZnWO₄, i.e., the ability of the material to turn the O₂ adsorbed on its surface into Oⁿ⁻ (O₂⁻, O²⁻, and O⁻) is enhanced. It can consume more e⁻ in the CB of the C-ZWO nanocomposites and improve the change in the resistance of the materials. Therefore, the oxygen reduction performance of the material is improved after the composite CuO, which means that the reaction between H₂S and Oⁿ⁻ on the surface of the material is enhanced, which improves their H₂S sensitivities.

3.3.3. Bandgap Analysis and H₂S-Sensing Mechanism

To explore the influence of heterojunction nanostructure on H₂S-sensing performance, UPS measurements were carried out on ZnWO₄ and CuO, as shown in Figure 14. The cut-off edge energies (E_cut-off) of ZnWO₄ and CuO are 18.39 and 17.01 eV, respectively; the Fermi edge energy values (E_F) are 2.40 and 0.53 eV, respectively; the work functions (Φ) of ZnWO₄ and CuO are 5.23 and 4.74 eV, respectively; and the band gaps of ZnWO₄ (inset in Figure 13b) and CuO (inset in Figure 14d) are 3.20 and 1.20 eV, respectively. The obtained band structure of ZnWO₄ and CuO is shown in Figure 15.

As shown in Figure 15, the electrons in ZnWO₄ and holes in CuO flow in opposite directions due to the large inhomogeneous gradient in carrier concentration, leading to the formation of an internal electric field between the ZnWO₄ and CuO interface [57]. When two materials are combined, the energy bands of the ZnWO₄ and CuO are bent, and the electrons are transferred until the Fermi level reaches equilibrium, and the material directly forms a large depletion region. The formation of the p–n heterojunction hinders the transfer of electrons, leading to a higher electrical resistance of the C-ZWO nanocomposite [57]. That is, before the C-ZWO nanocomposite sample explodes into the H₂S gas, the material possesses high resistance (R_a) (Figure S4a).

When the CuO-ZnWO₄ composites are exposed to H₂S, the H₂S molecules react with the oxygen anion ions on the surface. Firstly, the H₂S molecules are oxidized by O₂⁻ following the reaction of 2H₂S (g) + 3O₂⁻ (ads) → 2H₂O (g) + 2SO₂ (g) + 3e⁻. Then, the forming electrons are released into the C-ZWO nanocomposites, which narrows the depletion region mentioned above, leading to a reduction in the resistance (R_g) [58].

In addition, the p–n heterojunction between CuO and ZnWO₄ (Figure S4a) will also be destroyed, as some of the CuO reacts with H₂S to form CuS (Figure S4b), following the reaction of CuO (s) + H₂S (g) → CuS (s) + H₂O (g) [55] (Figure S4b). As a result of this phase transition, the p–n junction barrier of the CuO and ZnWO₄ (Figure S4a) transforms into a metal-n-type semiconductor contact with a lower barrier between CuS and ZnWO₄ (Figure S4b), making the resistance of the C-ZWO material (R_g) even smaller, i.e., exhibiting a high response value (S = R_a/R_g) to H₂S gas.

Meanwhile, with the increase in the CuO contents, the response time of the C-ZWO sensors decreases gradually both at RT and 100 °C, as shown in Table S3. The short response time of the C-ZWO sensors with higher CuO contents may be due to the reaction of CuO (s) + H₂S (g) → CuS (s) + H₂O (g), which occurs fast and exhibits a shorter response time. However, when H₂S is removed by introducing air, CuS is unstable and can be slowly oxidized by oxygen in the air, following the reaction 2CuS (s) + 3O₂ (g) → 2CuO (s) + 2SO₂ (g). At 100 °C, the 0% C-ZWO and 5% C-ZWO sensing recovered 90% in 180 and 138 s (Figure 8a,b). However, the recovery of the resistance of the other C-ZWO samples occurs with difficulty, especially for the high-CuO-content C-ZWO samples. Notably, by applying a 4.58 V short voltage pulse, i.e., heating it at 300 °C, the reaction 2CuS (s) + 3O₂ (g) → 2CuO (s) + 2SO₂ (g) can occur much more easily, which helps to recover the other sensors quickly in potential applications.

Furthermore, the composite CuO/ZnWO₄ material has a larger S_BET and more active sites, which can promote the surface reaction and increase its gas-sensing responses. XPS analysis further verified the increase in the proportion of O_V. The presence of abundant O_V on the surface of 10% C-ZWO can provide abundant unpaired electrons as electron donors, providing active sites for materials sensitive to the chemoadsorption of oxygen, thereby enhancing the ability of materials to ionize oxygen [35]. Meanwhile, the increase in the starting potential of the composite material in the ORR test also supports this conclusion. In conclusion, the formation of the p–n heterojunction, the increased specific surface area and active sites, and the enhanced oxygen reduction ability significantly improve the gas sensitivity of the C-ZWO sensors.

4. Conclusions

In conclusion, C-ZWO composites were synthesized by a two-step hydrothermal process, which led to a substantial improvement in H₂S gas-sensing performance at RT and low temperatures (≤100 °C). The 10% C-ZWO sensor at RT exhibits a balanced response value of 651.6 and a response time of 78 s, while the 5% C-ZWO sensor at 100 °C shows potential with a response value of 13.5 and response and recovery times of 78 and 138 s, respectively. Meanwhile, the sensors show the advantages of good selectivity and stability. The H₂S-sensing mechanism was studied by systematic characterization. The enhancement of the gas-sensitive properties of composite C-ZWO sensors mainly depends on the construction of p–n heterojunctions and the enhancement of surface adsorption and oxygen reduction capabilities of the materials. This study applies ZnWO₄ in the direction of H₂S gas detection; the construction of CuO/ZnWO₄ heterojunction materials shows excellent potential for further study and practical applications.