Highly Sensitive and Selective NiO/WO<sub>3</sub> Composite Nanoparticles in Detecting H<sub>2</sub>S Biomarker of Halitosis

Feng, Dongliang; Du, Lingling; Xing, Xiaxia; Wang, Chen; Chen, Jian; Zhu, Zengwei; Tian, Yongtao; Yang, Dachi

doi:10.1021/acssensors.0c01280

Cited by 83 publications

(53 citation statements)

References 46 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…It is usually produced from automobile exhaust, waste disposals, the petrochemical industry, natural gas exploitation industry, and coal mining industry, and other places. [ 1–5 ] Long‐term expose to certain amounts of H 2 S gas not only causes a sense of smell loss, but also causes neural paralysis. When the concentration of H 2 S surpasses the critical value of 250 ppm, human death will happen if inhaled accidentally.…”

Section: Introductionmentioning

confidence: 99%

Fe‐doped MOF‐derived N‐rich porous carbon nanoframe for H₂S cataluminescence sensing

2022

View full text Add to dashboard Cite

Metal-doped porous carbon matrix composites are considered as outstanding H 2 S cataluminescence sensing materials for their good sulfur tolerance and high cataluminescence activity. In this work, an Fe-doped MOF-derived N-rich porous carbon nanoframe was successfully fabricated using the pyrolysis of Fe-doped ZIF-8 in an Ar atmosphere at a temperature of 900 C, and used for H 2 S cataluminescence sensing.Along with zinc volatilization, the obtained porous carbon nanoframe not only had high specific surface area and abundant voids, but also had well dispersed Fe species doped in the skeleton. Compared with Fe 2 O 3 /ZnO composites derived from the same precursor but different pyrolysis terms, this as-prepared Fe-doped N-rich porous carbon presented a three times increase in the cataluminescence intensity towards H 2 S, attributed to the porous carbon skeleton that is indispensable for dispersing catalytic active sites and providing more absorptive surface and voids. Comparably, this proposed sensor demonstrated high sensitivity and good selectivity, with the detection range of 1.57-19.58 μgÁml À1 and detection limit of 0.13 μgÁml À1 towards H 2 S. This work may provide a new pathway for preparing catalysts for cataluminescence sensing with better metal distribution, higher specific surface area, and richer pores than ever before.

show abstract

Section: Introductionmentioning

confidence: 99%

Fe‐doped MOF‐derived N‐rich porous carbon nanoframe for H₂S cataluminescence sensing

2022

View full text Add to dashboard Cite

show abstract

“…Currently, several methods, including colorimetric assays, [8][9][10] chromatography, [11][12][13] uorometry, [14][15][16][17] electrochemical analysis, 18,19 and gas-sensing analysis, [20][21][22] have been applied for hydrogen sulde detection. As a typical gas-sensing material, metal oxide semiconductors, including ZnO, 23,24 CuO, 25,26 SnO 2 , 27,28 In 2 O 3 , 29,30 WO 3 , 31,32 Co 3 O 4 , 33,34 NiO, 35,36 Fe 2 O 3 , 37,38 and Cr 2 O 3 , 39 have been widely applied for the detection of various gaseous substances, like H 2 S, due to their thermal endurance, physical stability, and low cost. However, some drawbacks, such as high working temperature and low selectivity, restrict the practical applications of H 2 S gas sensors.…”

Section: Introductionmentioning

confidence: 99%

ZnO@CuO hollow nanosphere-based composites used for the sensitive detection of hydrogen sulfide with long-term stability

et al. 2022

View full text Add to dashboard Cite

show abstract

“…Contemporary technologies for H 2 S detection include gas chromatography, 8 , 9 metal oxide/nanoparticle chemiresistors, 10 − 13 electrochemical sensors, 14 , 15 and colorimetric and chemiluminescence-based probes. 6 , 16 − 22 Although high H 2 S sensitivities have been achieved in some instances, typical drawbacks of contemporary technologies include long response times, elevated operational temperatures, high power requirements, cross-selectivity issues with respect to volatile organic compounds (VOCs), bulky device enclosures, slow or sluggish signal reversibility, and short sensor lifetimes that hamper mobile deployment and real-time H 2 S monitoring.…”

Section: Introductionmentioning

confidence: 99%

“…Contemporary technologies for H 2 S detection include gas chromatography, , metal oxide/nanoparticle chemiresistors, − electrochemical sensors, , and colorimetric and chemiluminescence-based probes. ,− Although high H 2 S sensitivities have been achieved in some instances, typical drawbacks of contemporary technologies include long response times, elevated operational temperatures, high power requirements, cross-selectivity issues with respect to volatile organic compounds (VOCs), bulky device enclosures, slow or sluggish signal reversibility, and short sensor lifetimes that hamper mobile deployment and real-time H 2 S monitoring. Therefore, it is imperative to develop new H 2 S sensing technologies that satisfy a range of key criteria for in-field application such as fast room temperature operation, low power requirements, rapidly reversible H 2 S response, high selectivity, and consistent device performance over time.…”

Section: Introductionmentioning

confidence: 99%

Trace Hydrogen Sulfide Sensing Inspired by Polyoxometalate-Mediated Aerobic Oxidation

et al. 2021

View full text Add to dashboard Cite

A high-performance chemiresistive gas sensor is described for the detection of hydrogen sulfide (H 2 S), an acutely toxic and corrosive gas. The chemiresistor operates at room temperature with low power requirements potentially suitable for wearable sensors or for rapid in-field detection of H 2 S in settings such as pipelines and wastewater treatment plants. Specifically, we report chemiresistors based on single-walled carbon nanotubes (SWCNTs) containing highly oxidizing platinum-polyoxometalate (Pt-POM) selectors. We show that by tuning the vanadium content and thereby the oxidation reactivity of the constituent POMs, an efficient chemiresistive sensor is obtained that is proposed to operate by modulating CNT doping during aerobic H 2 S oxidation. The sensor shows exceptional sensitivity to trace H 2 S in air with a ppb-level detection limit, multimonth stability under ambient conditions, and high selectivity for H 2 S over a wide range of interferants, including thiols, thioethers, and thiophene. Finally, we demonstrate that the robust sensing material can be used to fabricate flexible devices by covalently immobilizing the SWCNT-P4VP network onto a polyimide substrate, further extending the potentially broad utility of the chemiresistors. The strategy presented herein highlights the applicability of concepts in molecular aerobic oxidation catalysis to the development of low-cost analyte detection technologies.

show abstract

Highly Sensitive and Selective NiO/WO₃ Composite Nanoparticles in Detecting H₂S Biomarker of Halitosis

Cited by 83 publications

References 46 publications

Fe‐doped MOF‐derived N‐rich porous carbon nanoframe for H₂S cataluminescence sensing

Fe‐doped MOF‐derived N‐rich porous carbon nanoframe for H₂S cataluminescence sensing

ZnO@CuO hollow nanosphere-based composites used for the sensitive detection of hydrogen sulfide with long-term stability

Trace Hydrogen Sulfide Sensing Inspired by Polyoxometalate-Mediated Aerobic Oxidation

Contact Info

Product

Resources

About

Highly Sensitive and Selective NiO/WO3 Composite Nanoparticles in Detecting H2S Biomarker of Halitosis

Cited by 83 publications

References 46 publications

Fe‐doped MOF‐derived N‐rich porous carbon nanoframe for H2S cataluminescence sensing

Fe‐doped MOF‐derived N‐rich porous carbon nanoframe for H2S cataluminescence sensing

ZnO@CuO hollow nanosphere-based composites used for the sensitive detection of hydrogen sulfide with long-term stability

Trace Hydrogen Sulfide Sensing Inspired by Polyoxometalate-Mediated Aerobic Oxidation

Contact Info

Product

Resources

About

Highly Sensitive and Selective NiO/WO₃ Composite Nanoparticles in Detecting H₂S Biomarker of Halitosis

Fe‐doped MOF‐derived N‐rich porous carbon nanoframe for H₂S cataluminescence sensing

Fe‐doped MOF‐derived N‐rich porous carbon nanoframe for H₂S cataluminescence sensing