Point Discharge Microplasma Optical Emission Spectrometer: Hollow Electrode for Efficient Volatile Hydride/Mercury Sample Introduction and 3D-Printing for Compact Instrumentation

Li, Mengtian; Li, Kai; He, Lin; Zeng, Xiaoliang; Wu, Xi; Hou, Xiandeng; Jiang, Xiaoming

doi:10.1021/acs.analchem.9b00045

Cited by 36 publications

(15 citation statements)

References 28 publications

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“…However, as typical excitation sources, ICP and MP are well known for large size and high energy consumption and are thereby incompetent for elemental field analysis. By contrast, microplasma excitation sources, such as dielectric barrier discharge (DBD), 8,9 point discharge (PD), 10,11 solution cathode/anode glow discharge (SCGD/SAGD), 12,13 and atmospheric pressure glow discharge (APGD), 14,15 are characterized by low cost, small size and low power consumption. Up to date, miniature OES instruments using various kinds of microplasma as excitation sources have frequently been developed, demonstrating great potential for field analysis of toxic elements in environmental water.…”

Section: Introductionmentioning

confidence: 99%

High-sensitivity and field analysis of lead by portable optical emission spectrometry using a microplasma trap

Zhang

Liu

Mao

et al. 2022

J. Anal. At. Spectrom.

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Section: Introductionmentioning

confidence: 99%

High-sensitivity and field analysis of lead by portable optical emission spectrometry using a microplasma trap

Zhang

Liu

Mao

et al. 2022

J. Anal. At. Spectrom.

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“…To the best of our knowledge, there are only a few applications of 3D printing in atomic spectrometry. 26 According to previous works, 27,28 nonhyphenated techniques based on chemical vapor generation were conducive to realize simple elemental speciation analysis via the selective determination of one species of the tested element. 29,30 The purpose of this work is to utilize the advantages of 3D printing, microplasma-OES, and chemical vapor generation to fabricate a miniaturized and compact dual-mode chemical vapor generation (CVG and PVG) point discharge (μPD) optical emission spectrometer for field elemental speciation analysis.…”

mentioning

confidence: 99%

“…As a typical additive manufacturing technology, three-dimensional (3D) printing has driven innovation in the manufacturing industry and brought countless applications in a large variety of fields. , Compared to the traditional manufacturing techniques, 3D printing technologies provide a more unified and standardized platform for ordinary people to facilely and cost-effectively fabricate the parts of analytical devices, even some complex devices that cannot be fabricated by conventional techniques. − Importantly, the design files for the 3D printed devices can be shared online to make other laboratories produce analytical devices in a reproducible manner. To the best of our knowledge, there are only a few applications of 3D printing in atomic spectrometry …”

mentioning

confidence: 99%

Three-Dimensional Printed Dual-Mode Chemical Vapor Generation Point Discharge Optical Emission Spectrometer for Field Speciation Analyses of Mercury and Inorganic Selenium

Yang

Lin

et al. 2021

Anal. Chem.

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Due to the large size and high energy consumption of instruments, field elemental speciation analysis is still challenging so far. In this work, a portable and compact system device (230 mm length × 38 mm width × 84 mm height) was fabricated by using three-dimensional (3D) printing technology for the field speciation analyses of mercury and inorganic selenium. The device comprises a cold vapor generator, photochemical vapor generator, and miniaturized point discharge optical emission spectrometer (μPD-OES). For mercury, inorganic mercury (IHg) was selectively reduced to Hg 0 by cold vapor generation, whereas the reductions of both IHg and methylmercury (MeHg) were obtained by photochemical vapor generation (PVG) in the presence of formic acid. For selenium, Se(IV) and total inorganic selenium were converted to their volatile species by PVG in the presence and the absence of nano-TiO 2 , respectively. The generated volatile species were consequently detected by μPD-OES. Limits of detection of MeHg, IHg, Se(IV), and Se(VI) were 0.1, 0.1, 5.2, and 3.5 μg L −1 , respectively. Precision expressed as the relative standard deviations (n = 11) were better than 4.5%. The accuracy and practicality of the proposed method were evaluated by the analyses of Certified Reference Materials (DORM-4, DOLT-5, and GBW(E)080395) and several environmental water samples with satisfactory recoveries (95−103%). This work confirms that 3D printing has great potential to fabricate a simple, miniaturized, easy-to-operate, and low gas and power consuming atomic spectrometer for field elemental speciation analysis.

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“…The use of polymer filament 3D printers to manufacture small-scale custom parts has become popular in recent years and has shown promising results in optical applications. , Several studies regarding polymer filament 3D printers associated with spectroscopy/optics are available in the literature. − However, the extent of how trustworthy these 3D-printed parts are according to the 3D project and printer limitations in the building of complete spectrometers is hardly brought up, also if fine adjustments or compensations in optics were made before the instrument or accessory use. Furthermore, some of these works apply 3D printing only as a complementary resource for building customized accessories to be coupled with commercial instruments and, even so, adjustments are made to the printed part …”

mentioning

confidence: 99%

Reconsidering the Need for Empirical Alignment and Wavelength Calibration Steps in the Building of a Dispersive NIR Spectrometer with an Application for Ethanol Quantification Using a Polymer Filament 3D Printer

et al. 2021

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The construction of a dispersive optical spectrometer using three-dimensional (3D) design software and printing, without applying any optical adjustments, its validation, and application to quantification of ethanol in multiproduct liquids, is the objective of this work. A 3D design software was used to design a near-infrared (NIR) spectrometer in the region from 800 to 1600 nm from the dimensions of commercially available optical components. The project was printed on a polymer filament 3D printer, and the components were fitted to the printed part. Software calculations using the model design parameters were applied to attribute the wavelength values to the abscissa axis in the spectra and estimate errors due to 3D printing limitations. The alignment of the spectrum was proven using the chloroform absorbance spectrum, which presented a maximum mispositioning of 4.1 nm concerning the literature data and effective bandwidths equivalent to commercial instruments. The 3D-printed instrument was applied to quantify ethanol in samples of cachaça, rum, beer, brandy, whiskey, vodka, mouth wash, alcohol gel, and commercial alcohol solutions. Partial least-squares regression models were built for the 3D-printed instrument and two commercial NIR instruments, the MPA II (Bruker) and the NIR DLP NIRscan (Texas Instruments), using a group of 180 standards. The three instruments reached excellent predictive capability with similar root mean square error of cross-validation (2.36–2.68) and prediction (2.31–2.87). The correlation coefficient of cross-validation and prediction for all models were between 0.97 and 0.98. The results show the feasibility of building a 3D-printed dispersive spectrometer ready for application with the simple docking of the optics, presenting acceptable accuracy to the project design concerning the printing limitations.

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Point Discharge Microplasma Optical Emission Spectrometer: Hollow Electrode for Efficient Volatile Hydride/Mercury Sample Introduction and 3D-Printing for Compact Instrumentation

Cited by 36 publications

References 28 publications

High-sensitivity and field analysis of lead by portable optical emission spectrometry using a microplasma trap

High-sensitivity and field analysis of lead by portable optical emission spectrometry using a microplasma trap

Three-Dimensional Printed Dual-Mode Chemical Vapor Generation Point Discharge Optical Emission Spectrometer for Field Speciation Analyses of Mercury and Inorganic Selenium

Reconsidering the Need for Empirical Alignment and Wavelength Calibration Steps in the Building of a Dispersive NIR Spectrometer with an Application for Ethanol Quantification Using a Polymer Filament 3D Printer

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