Influence of operating parameters on aerosol characteristics of selected inductively coupled plasma optical emission spectrometry nebulizers

Wagner, Janet

12 1900

No description available.

Plasma spectroscopy

Fundamental studies of a graphite rod electrothermal vaporization device for sample introduction in atomic emission spectroscopy

Schmertmann, Susan Mace

08 1900

No description available.

Emission spectroscopy

A novel sample introduction device for inductively coupled plasma-optical emission spectrometry

Faske, Arthur Joseph

12 1900

No description available.

Emission spectroscopy

Studies of sample introduction for inductively coupled plasma emission spectrometry

Boorn, Andrew William

05 1900

No description available.

Plasma spectroscopy

Raman spectroscopic studies of (A) the Co-C bond in vitamin B## and model compounds, (B) inorganic matrices-encapsulated metallocomplexes, and (C) molecular hydrogen compounds

Chopra, Manu

05 1900

No description available.

Raman spectroscopy

A study of sample introduction for inductively coupled plasma atomic emission spectrometry using volatile metal chelate complexes

Black, Marilyn Shull

12 1900

No description available.

Plasma spectroscopy

A multimodal spectrometer for Raman scattering and near-infrared absorption measurement

Wang, Wenbo

05 September 2012

In food and pharmaceutical industries, the compositional complexity of raw materials and products promotes the use of multiple spectroscopic techniques. Availability of complementary methods, e.g., infrared absorption and Raman, is highly desirable. A multimodal Raman/NIR spectroscopic device was proposed. The device offered fast, non-destructive measurement, and remote sensing capability. A prototype was built. Spectral range covered 300-2600 cm-1 for Raman channel. Wavelength accuracy was better than 0.57 nm. Spectral resolution was better than 14.39 cm-1 (1 nm) for Raman (NIR) channel. Spectral response linearity was better than 0.998. Instrumental stability was better than 0.72% (0.39%) for Raman (NIR) channel. The device was applied to quantify ethanol aqueous solutions (2%-10% (v/v)). Quantitation results gave a root mean squared error of prediction (RMSEP) of 0.45% (v/v). Calibration using NIR absorbance spectra produced a RMSEP value of 0.49% (v/v). Raman technique offered the most succinct calibration model using peak height at 882.29 cm-1. Quantitation of ovalbumin (8%-16% (w/v)) in aqueous solutions and denatured states was also attempted. Stepwise multiple regression was performed using Raman peaks at 1243.35, 1448.68, 1662.66, and 1667.78 cm-1, which produced RMSEPs of 1.05 % (w/v) for ovalbumin solutions and 0.74 % (w/v) for ovalbumin gels. Conformational change of ovalbumin upon thermal denaturation was studied using the height and area ratios between peaks at 1243.35 and 1662.66 cm-1. Thermal denaturation of ovalbumin occurred at 70 °C and extensive formation of anti-parallel β-sheet structure was found at 90 °C. The unique capability of this multimodal device was proven by first performing data fusion of Raman and NIR spectra for quantitation. Using the same ethanol spectra set gave a more complicated model and a higher RMSEP of 0.73% (v/v). However, important variables in fused spectra corresponded well with the spectral signatures of ethanol and water. Two-dimensional correlation spectra were calculated using concentration as the external perturbation. The autopower spectra revealed features pertinent to those of the analytes. Heterospectral correlation analysis was carried out on Raman/NIR spectra of ethanol aqueous solution. Raman peaks at 882.29 and 1454.00 cm-1 agreed with the NIR absorption feature around 906.18 nm.

spectroscopy

instrumentation

Preliminary investigation of radiation phenomena in high pressure air and argon cascade arcs

Dodson, Daniel Powell

12 1900

No description available.

Plasma spectroscopy

A Moessbauer and #mu#SR study of the magnetic ordering of some antiferromagnet compounds

Attenborough, Michael

January 1997

No description available.

530.41

Spectroscopy

A multimodal spectrometer for Raman scattering and near-infrared absorption measurement

Wang, Wenbo

05 September 2012

In food and pharmaceutical industries, the compositional complexity of raw materials and products promotes the use of multiple spectroscopic techniques. Availability of complementary methods, e.g., infrared absorption and Raman, is highly desirable. A multimodal Raman/NIR spectroscopic device was proposed. The device offered fast, non-destructive measurement, and remote sensing capability. A prototype was built. Spectral range covered 300-2600 cm-1 for Raman channel. Wavelength accuracy was better than 0.57 nm. Spectral resolution was better than 14.39 cm-1 (1 nm) for Raman (NIR) channel. Spectral response linearity was better than 0.998. Instrumental stability was better than 0.72% (0.39%) for Raman (NIR) channel. The device was applied to quantify ethanol aqueous solutions (2%-10% (v/v)). Quantitation results gave a root mean squared error of prediction (RMSEP) of 0.45% (v/v). Calibration using NIR absorbance spectra produced a RMSEP value of 0.49% (v/v). Raman technique offered the most succinct calibration model using peak height at 882.29 cm-1. Quantitation of ovalbumin (8%-16% (w/v)) in aqueous solutions and denatured states was also attempted. Stepwise multiple regression was performed using Raman peaks at 1243.35, 1448.68, 1662.66, and 1667.78 cm-1, which produced RMSEPs of 1.05 % (w/v) for ovalbumin solutions and 0.74 % (w/v) for ovalbumin gels. Conformational change of ovalbumin upon thermal denaturation was studied using the height and area ratios between peaks at 1243.35 and 1662.66 cm-1. Thermal denaturation of ovalbumin occurred at 70 °C and extensive formation of anti-parallel β-sheet structure was found at 90 °C. The unique capability of this multimodal device was proven by first performing data fusion of Raman and NIR spectra for quantitation. Using the same ethanol spectra set gave a more complicated model and a higher RMSEP of 0.73% (v/v). However, important variables in fused spectra corresponded well with the spectral signatures of ethanol and water. Two-dimensional correlation spectra were calculated using concentration as the external perturbation. The autopower spectra revealed features pertinent to those of the analytes. Heterospectral correlation analysis was carried out on Raman/NIR spectra of ethanol aqueous solution. Raman peaks at 882.29 and 1454.00 cm-1 agreed with the NIR absorption feature around 906.18 nm.

spectroscopy

instrumentation