Polymerization-Induced Aggregation Approach toward Uniform Pd Nanoparticle-Decorated Mesoporous SiO₂/WO₃ Microspheres for Hydrogen Sensing

Abstract: Hydrogen as an important clean energy source with a high energy density has attracted extensive attention in fuel cell vehicles and industrial production. However, considering its flammable and explosive property, gas sensors are desperately desired to efficiently monitor H2 concentration in practical applications. Herein, a facile polymerization-induced aggregation strategy was proposed to synthesize uniform Si-doped mesoporous WO3 (Si-mWO3) microspheres with tunable sizes. The polymerization of the melamine–… Show more

“…The UV–vis diffuse reflectance spectroscopy (DRS) characterization (Figure S12a) shows that the Pd/mSnO 2 - n sample (e.g., Pd/mSnO 2 -0.5) presents a stronger visible light absorption than that of mSnO 2 . Calculation based on the Tauc/Davis–Mott model (Figure S12b) indicates that the band gap of Pd/mSnO 2 -0.5 (3.35 eV) is slightly lower than that for mSnO 2 (3.47 eV), implying that the surface modification of Pd NPs can efficiently influence the electronic structure of SnO 2 . After Pd modification, the decreased band gap results in an easier electron excitation process, thus leading to greater electron transfer efficiency.…”

“…In the Pd 3d spectrum (Figure S13c), the splitting of the peak reveals that the dominating Pd species are zero-valence states, and the peaks at 335.5 and 340.8 eV can be assigned to Pd 0 3d 5/2 and Pd 0 3d 3/2 , respectively. Meanwhile, the oxidized Pd species also exist, where the peaks at 337.6 and 342.9 eV correspond to Pd 2+ 3d 5/2 and Pd 2+ 3d 3/2 , respectively …”

“…First, the two-dimensional mesoporous nanostructures provide a large number of gas–solid interfaces with easily accessible active sites, thus facilitating gas diffusion. Second, the spillover effect of the exposed Pd NPs on the surface of SnO 2 can induce the formation of extra adsorbed oxygen species, which is beneficial for accelerating the surface oxidation reaction, thus increasing the sensitivity of the sensor . Third, the electron sensitization of Pd can induce the formation of a Schottky barrier, resulting in an increase of baseline resistance and sensing response .…”

“…Meanwhile, the oxidized Pd species also exist, where the peaks at 337.6 and 342.9 eV correspond to Pd 2+ 3d 5/2 and Pd 2+ 3d 3/2 , respectively. 49 Gas Sensing Performance of Pd/mSnO 2 . Acetone (CH 3 COCH 3 ) is identified as a biomarker molecule related to diabetes, and the acetone concentration in the exhaled breath of diabetics is over 1.8 ppm, much higher than healthy people.…”

“…Second, the spillover effect of the exposed Pd NPs on the surface of SnO 2 can induce the formation of extra adsorbed oxygen species, which is beneficial for accelerating the surface oxidation reaction, thus increasing the sensitivity of the sensor. 49 Third, the electron sensitization of Pd can induce the formation of a Schottky barrier, resulting in an increase of baseline resistance and sensing response. 47 Moreover, the p−n heterojunctions between PdO species and SnO 2 alter the band structure (Figure S17) and increase the EDL thickness of SnO 2 , thus accelerating the electron transfer during the sensing process and remarkably enhancing the sensitivity and response speed.…”

Maillard Reaction Inspired Microexplosion toward Fast Synthesis of Two-Dimensional Mesoporous Tin Oxides for Efficient Chemiresistive Gas Sensing

“…The UV–vis diffuse reflectance spectroscopy (DRS) characterization (Figure S12a) shows that the Pd/mSnO 2 - n sample (e.g., Pd/mSnO 2 -0.5) presents a stronger visible light absorption than that of mSnO 2 . Calculation based on the Tauc/Davis–Mott model (Figure S12b) indicates that the band gap of Pd/mSnO 2 -0.5 (3.35 eV) is slightly lower than that for mSnO 2 (3.47 eV), implying that the surface modification of Pd NPs can efficiently influence the electronic structure of SnO 2 . After Pd modification, the decreased band gap results in an easier electron excitation process, thus leading to greater electron transfer efficiency.…”

“…In the Pd 3d spectrum (Figure S13c), the splitting of the peak reveals that the dominating Pd species are zero-valence states, and the peaks at 335.5 and 340.8 eV can be assigned to Pd 0 3d 5/2 and Pd 0 3d 3/2 , respectively. Meanwhile, the oxidized Pd species also exist, where the peaks at 337.6 and 342.9 eV correspond to Pd 2+ 3d 5/2 and Pd 2+ 3d 3/2 , respectively …”

“…First, the two-dimensional mesoporous nanostructures provide a large number of gas–solid interfaces with easily accessible active sites, thus facilitating gas diffusion. Second, the spillover effect of the exposed Pd NPs on the surface of SnO 2 can induce the formation of extra adsorbed oxygen species, which is beneficial for accelerating the surface oxidation reaction, thus increasing the sensitivity of the sensor . Third, the electron sensitization of Pd can induce the formation of a Schottky barrier, resulting in an increase of baseline resistance and sensing response .…”

“…Meanwhile, the oxidized Pd species also exist, where the peaks at 337.6 and 342.9 eV correspond to Pd 2+ 3d 5/2 and Pd 2+ 3d 3/2 , respectively. 49 Gas Sensing Performance of Pd/mSnO 2 . Acetone (CH 3 COCH 3 ) is identified as a biomarker molecule related to diabetes, and the acetone concentration in the exhaled breath of diabetics is over 1.8 ppm, much higher than healthy people.…”

“…Second, the spillover effect of the exposed Pd NPs on the surface of SnO 2 can induce the formation of extra adsorbed oxygen species, which is beneficial for accelerating the surface oxidation reaction, thus increasing the sensitivity of the sensor. 49 Third, the electron sensitization of Pd can induce the formation of a Schottky barrier, resulting in an increase of baseline resistance and sensing response. 47 Moreover, the p−n heterojunctions between PdO species and SnO 2 alter the band structure (Figure S17) and increase the EDL thickness of SnO 2 , thus accelerating the electron transfer during the sensing process and remarkably enhancing the sensitivity and response speed.…”

Maillard Reaction Inspired Microexplosion toward Fast Synthesis of Two-Dimensional Mesoporous Tin Oxides for Efficient Chemiresistive Gas Sensing

In situ sulfur-doped mesoporous tungsten oxides for gas sensing toward benzene series

Long-term stability electrochromic electrodes based on porous tungsten trioxide and nickel oxide films via a facile triple pulse electrodeposition