Use of organic solvents in large research institutions in Japan

Nagasawa, Yasuhiro; Samoto, Hajime; Ukai, Hirohiko; Okamoto, Susumu; Itoh, Kenji; Hanada, Takaaki; Kanemaru, Ai; Fukui, Yoshinari; Kojima, Satoshi; Moriguchi, Jiro; Sakuragi, Sonoko; Ohashi, Fumiko; Takada, Shiro; Kawakami, Takuya; Ikeda, Masayuki

doi:10.1007/s12199-012-0327-1

Cited by 5 publications

(5 citation statements)

References 15 publications

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“…[65,66] The use of organic solvents, pesticides, and NACs is increasing continuously, and presents a major risk to living species and the environment. [67][68][69][70][71][72] Therefore, advanced study of the acute detection of these hazardous chemicals using analytical techniques will expand the research area and provide analytical devices. [73] In the last decade, various analytical techniques and materials have been developed for detecting these chemicals, including spectroscopic, spectrometric, and electrochemical techniques.…”

Section: Toxic Chemicals and Their Detectionmentioning

confidence: 99%

“…[ 65,66 ] The use of organic solvents, pesticides, and NACs is increasing continuously, and presents a major risk to living species and the environment. [ 67–72 ] Therefore, advanced study of the acute detection of these hazardous chemicals using analytical techniques will expand the research area and provide analytical devices. [ 73 ]…”

Section: Toxic Chemicals and Their Detectionmentioning

confidence: 99%

See 1 more Smart Citation

Mechanistic Insight into Charge and Energy Transfers of Luminescent Metal–Organic Frameworks Based Sensors for Toxic Chemicals

Mohan

Kumar

et al. 2021

Advanced Sustainable Systems

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The success of MOFs has driven their development as a new tool for sensing analytes including toxic chemicals. [19][20][21] The MOF sensors can be applied in both environmental and biological systems. [22] The MOF sensor field has been established with the development of sensors for different metal ions, anions, and molecules. [23,24] The potential application of MOF sensors to the detection of heavy metal ions, toxic anions, and other hazardous species is of great interest. [25,26] Specifically, luminescence technology has allowed the roles of various MOF sites in analyte capture to be easily studied. [27][28][29] The precise use of MOFs is potentially a good tool for analyte detection. Furthermore, MOFs have been established as potential materials for selective, fast, and portable tools for sensing toxic chemicals, with the advantage of light-emitting properties. [30,31] Interestingly, these sensing models can operate in water and are pH stable with high efficiency. [32] Furthermore, MOFs are wellknown materials for the degradation of toxic chemicals. [33,34] Several reports have been published on MOF sensors for toxicant chemicals, such as metal ions, anions, organic solvents, pesticides, nitroaromatic compounds (NACs), chemical warfare agents, [35] and others. [36][37][38] Some reviews have summarized applications of MOFs in sensing and detection probes for ions and volatile organic compounds, [39] and MOF sensors in pesticide detection and absorption with their classification. [40] Others have summarized and analyzed interactions between hazardous compound adsorbates and MOFs. [41,42] The stability and applications of MOFs have been summarized by the research groups of Ding and coworkers. [43] Pehlivan and et al. summarized the role of fluorescence resonance energy transfer in elucidating molecular interactions utilized in biosensing tools. [44,45] Besides luminescence sensing, the reviewers summarized the progress of MOFs relevance in the various area including environment and medical science. [46] Recently, Liu and coworkers summarized the progress of MOFs and discussed the remaining challenges in drug delivery, [47] Garcia and coworkers studied and compared the MOFs as photocatalysts with common inorganic photocatalysts, [48] and Manos and coworkers studied and summarized MOFs challenges and prospects for ion-exchange and sorption applications. [49] Despite these meaningful reviews, the factors responsible for signal changes, mechanisms, and limits of detection have Mechanistic studies of materials able to detect hazardous and toxic chemicals, such as common organic solvents, pesticides, and nitroaromatic compounds (NACs), are critically important owing to the threat they pose to humans and the environment. Recently, porous luminescent metal-organic frameworks (MOFs) with multifunctional sites, high surface areas, and structural tunability have emerged as sensory devices for the detection of hazardous and toxic chemicals. Herein, recent progress regarding the mechanistic behavior of MOF sensors in the det...

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Section: Toxic Chemicals and Their Detectionmentioning

confidence: 99%

Section: Toxic Chemicals and Their Detectionmentioning

confidence: 99%

Mechanistic Insight into Charge and Energy Transfers of Luminescent Metal–Organic Frameworks Based Sensors for Toxic Chemicals

Mohan

Kumar

et al. 2021

Advanced Sustainable Systems

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“…Liquid-phase microextraction (LPME), one of the miniaturized liquid-liquid extraction (or solvent extraction) techniques that are considered as an environment-friendly mi-croextraction approach, minimizes the use of organic solvents and/or highly toxic chemicals [63]. In general, LPME involves extracting and preconcentrating target analytes into a few microliters of extraction solvent [64]. Some notable advantages of LPME include easy operation, low solvent and sample consumption, being environmental-friendly (compared to liquid-liquid extraction) and provide high enrichment factor (high sample volume-to-extractant/acceptor volume ratios) for targeted analytes [65].…”

Section: Liquid-phase Microextraction Techniquesmentioning

confidence: 99%

Strategy for Sustainable and Green Chromatographic Separation Science: Innovation, Technology and Application

Mohammad

Azmir

Ademario

et al. 2020

CCHG

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: Green separation science involves extraction, pre-concentration and chromatographic analysis aiming at minimizing environmental impact by reducing energy and reagent usage and reducing or eliminating waste generation. However, the enrichment of trace analytes and/or the analysis of complex matrices most frequently require several steps before analysis, such as extraction, pre-concentration, clean up and preparative chromatography. Thus, alternative and greener separation techniques and solvents are replacing classical methods to diminish the carbon footprint and increase sustainability. Moreover, many innovations are also emerging to curtail the environmental impact of samples analysis; such as micro or nano analytical platforms, sensor-based systems and direct injection to high resolution mass spectrometry. The current review provides an updated account of the green and sustainable separation science techniques. The current innovations on greener separations and their application in different fields of study are discussed.

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“…Moreover, some gases can leak without smell or colour, creating a dangerous situation for the worker. [11][12][13] Carbon nanotubes (CNTs) are well-suited for creating gas sensors with structures and components that exhibit novel and signicantly enhanced physical and chemical properties due to their nanoscale size. CNTs, which have wall structures made from a single graphite sheet rolled into a tubular shape, are known as single-walled carbon nanotubes (SWCNTs).…”

Section: Introductionmentioning

confidence: 99%

Mechanism simulation of polar and nonpolar organic solvent vapor adsorption on a multiwall carbon nanotubes paper gas sensor

Zhang,

Inoue,

Matsumura

2024

RSC Adv.

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Use of organic solvents in large research institutions in Japan

Cited by 5 publications

References 15 publications

Mechanistic Insight into Charge and Energy Transfers of Luminescent Metal–Organic Frameworks Based Sensors for Toxic Chemicals

Mechanistic Insight into Charge and Energy Transfers of Luminescent Metal–Organic Frameworks Based Sensors for Toxic Chemicals

Strategy for Sustainable and Green Chromatographic Separation Science: Innovation, Technology and Application

Mechanism simulation of polar and nonpolar organic solvent vapor adsorption on a multiwall carbon nanotubes paper gas sensor

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