NASICON-type Na3Fe2(PO4)3 material for an excellent room temperature CO sensor

Tiwari, Manish Kumar; Kanwade, Archana; Yadav, Subhash Chand; Srivastava, Abhishek; Satrughna, Jena Akash Kumar; Shirage, Parasharam M.

doi:10.1039/d3tc00300k

Cited by 7 publications

(3 citation statements)

References 65 publications

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“…This unique approach allows exact control over the size and morphology of the synthesized nanomaterials, thus enabling the development of desirable properties for diverse applications. 63,91–94…”

Section: Role Of Sn In the Etlmentioning

confidence: 99%

Dynamic synergy of tin in the electron-transfer layer and absorber layer for advancing perovskite solar cells: a comprehensive review

Shaikh,

Yadav,

Srivastava

et al. 2024

Energy Adv.

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Section: Role Of Sn In the Etlmentioning

confidence: 99%

Dynamic synergy of tin in the electron-transfer layer and absorber layer for advancing perovskite solar cells: a comprehensive review

Shaikh,

Yadav,

Srivastava

et al. 2024

Energy Adv.

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“…In recent decades, various techniques, such as gas chromatography, electrochemical methods, − and Raman spectrometry, have been developed for CO detection. However, these methods are usually not suitable for in situ detection of physiological levels of CO in living cells for the complexity and destructiveness of biological samples. , Fluorescence sensing and imaging techniques have attracted considerable attention as powerful candidates to detect CO in living organisms, due to their superiority of rapidness, sensitivity, easy procedure, and relatively minor biodamage. ,, In recent years, works on fluorescent probes for imaging of CO have made great progress.…”

Section: Introductionmentioning

confidence: 99%

Fe(III)-Based Fluorescent Probe for High-Performance Recognition, Test Strip Analysis, and Cell Imaging of Carbon Monoxide

Fang,

Cui,

et al. 2024

Anal. Chem.

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Fluorescence sensing and imaging techniques are being widely studied for detecting carbon monoxide (CO) in living organisms due to their speed, sensitivity, and ease of use to biological systems. Most fluorescent probes used for this purpose are based on heavy metal ions like Pd, with a few using elements like Ru, Rh, Ir, Os, Tb, and Eu. However, these metals can be expensive and toxic to cells. There is a need for more affordable and biologically safe fluorescent probes for CO detection. Drawing inspiration from the robust affinity exhibited by heme iron toward CO, in this work, a rhodamine derivative called RBF was developed for imaging CO in living cells by binding to Fe(III) and could be used for CO sensing. A Fe(III)-based fluorescent probe for CO imaging in living cells offers advantages of cost effectiveness, low toxicity, and ease of use. The fluorescence detection using the RBF-Fe system showed a direct correlation with increasing levels of CORM-3 (LOD = 146 nM) or the exposure time of CO gas, displaying reduced fluorescence. A CO test paper based on RBF-Fe was created for simple on-site CO detection, where fluorescence would diminish in response to CO exposure, allowing rapid (2 min) visual identification. Imaging of CO in living cells was successfully conducted using the probe system, showing a decrease in fluorescence intensity as CORM-3 concentrations increased, indicating its effectiveness in monitoring CO levels accurately within living cells.

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“…For example, carbon monoxide (CO), an odourless, tasteless and colourless gas (difficult to detect by human sensory organs) produced by the burning of fossil fuels, can be particularly deadly due to its high affinity for haemoglobin, forms carboxyhemoglobin reducing oxygen delivery to tissues and can cause tissue hypoxia. 2,3 Additionally, carbon monoxide gas very easily attaches to cytochrome oxidase and causes diseases such as lactic acidosis, apoptosis, and hypoxia. 4,5 Nitrogen dioxide (NO 2 ), oxidizing and volatile in nature, contributes to lung inammation, silo-ller's disease, bronchiolitis brosis obliterans, and harmful acid rain.…”

Section: Introductionmentioning

confidence: 99%

Advancements in lanthanide-based perovskite oxide semiconductors for gas sensing applications: a focus on doping effects and development

Tiwari,

Chand Yadav,

Kanwade

et al. 2023

Anal. Methods

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NASICON-type Na₃Fe₂(PO₄)₃ material for an excellent room temperature CO sensor

Abstract: Here we report an ultra-sensitive room temperature carbon monoxide (CO) gas sensor based on Na3Fe2(PO4)3 (NFP, NASICON-type monoclinic structure material) for the first time. The NFP powder with plate-like morphology...

Cited by 7 publications

References 65 publications

Dynamic synergy of tin in the electron-transfer layer and absorber layer for advancing perovskite solar cells: a comprehensive review

Dynamic synergy of tin in the electron-transfer layer and absorber layer for advancing perovskite solar cells: a comprehensive review

Fe(III)-Based Fluorescent Probe for High-Performance Recognition, Test Strip Analysis, and Cell Imaging of Carbon Monoxide

Advancements in lanthanide-based perovskite oxide semiconductors for gas sensing applications: a focus on doping effects and development

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