<title>Ground-based aircraft exhaust measurements of a Lufthansa Airbus A340 using FTIR emission spectrometry</title>

XRF and PIXE Analysis of light and Dark Adapted Ocular Tissue

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100053619 ◽

1982 ◽

Vol 40 ◽

pp. 190-191

Author(s):

B. J. Panessa ◽

H. W. Kraner ◽

J. B. Warren ◽

K. W. Jones

Keyword(s):

Trace Metals ◽

Pigment Epithelium ◽

Nerve Impulse ◽

Light Response ◽

Ocular Tissue ◽

Emission Spectrometry ◽

Retinol Dehydrogenase ◽

Pixe Analysis ◽

X Ray ◽

Optimal Function

During photoexcitation the retina requires specific electrolytes and trace metals for optimal function (Na, Mg, Cl, K, Ca, S, P, Cu and Zn). According to Hagins (1981), photoexcitation and generation of a nerve impulse involves the movement of Ca from the rhodopsin-ladened membranes of the rod outer segment (ROS) to the plasmalemma, which in turn decreases the in-flow of Na into the photoreceptor, resulting in hyperpolarization. In toad isolated retinas, the presence of Ba has been found to increase the amplitude and prolong the delay of the light response (Brown and Flaming, 1978). Trace metals such as Cu, Zn and Se are essential for the activity of the metalloenzymes of the retina and retina pigment epithelium (RPE) (i.e. carbonic anhydrase, retinol dehydrogenase, tyrosinase, glutathione peroxidase, superoxide dismutase...). Therefore the content and fluctuations of these elements in the retina and choroid are of fundamental importance for the maintenance of vision. This paper presents elemental data from light and dark adapted frog ocular tissues examined by electron beam induced x-ray microanalysis, x-ray fluorescence spectrometry (XRF) and proton induced x-ray emission spectrometry (PIXE).

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Determination of rare earth metals in magnesium alloys by atomic emission spectrometry with inductively coupled plasma

Izmeritel`naya Tekhnika ◽

10.32446/0368-1025it.2019-4-62-66 ◽

2019 ◽

pp. 62-66

Author(s):

R. M. Dvoretskov ◽

V. B. Baranovskaya ◽

F. N. Karachevtsev ◽

A. F. Letov

Keyword(s):

Rare Earth ◽

Magnesium Alloys ◽

Inductively Coupled Plasma ◽

Rare Earth Metals ◽

Atomic Emission ◽

Atomic Emission Spectrometry ◽

Emission Spectrometry ◽

Inductively Coupled

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NOBLE METALS IN BLACK SHALES OF THE SUKHOI LOG GOLD DEPOSIT (East Siberia): EVIDENCE FROM SCINTILLATION ARC ATOMIC-EMISSION SPECTROMETRY

Геология и геофизика ◽

10.15372/gig20180808 ◽

2018 ◽

Keyword(s):

Gold Deposit ◽

Noble Metals ◽

Atomic Emission ◽

Black Shales ◽

Atomic Emission Spectrometry ◽

Emission Spectrometry ◽

East Siberia

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Silicate analysis of carbonated rocks using ICP-AES with calibration by the concentration ratio

Industrial laboratory Diagnostics of materials ◽

10.26896/1028-6861-2020-86-5-16-21 ◽

2020 ◽

Vol 86 (5) ◽

pp. 16-21

Author(s):

T. A. Karimova ◽

G. L. Buchbinder ◽

S. V. Kachin

Keyword(s):

Inductively Coupled Plasma ◽

Concentration Ratio ◽

Total Error ◽

Atomic Emission ◽

Emission Spectrometry ◽

Calibration Error ◽

Plasma Atomic Emission Spectrometry ◽

Standard Samples ◽

Inductively Coupled ◽

Carbonate Materials

Calibration by the concentration ratio provides better metrological characteristics compared to other calibration modes when using the inductively coupled plasma atomic emission spectrometry (ICP-AES) for analysis of geological samples and technical materials on their base. The main reasons for the observed improvement are: i) elimination of the calibration error of measuring vessels and the error of weighing samples of the analyzed materials from the total error of the analysis; ii) high intensity of the lines of base element; and iii) higher accuracy of measuring the ratio of intensities compared to that of measuring the absolute intensities. Calcium oxide is better suited as a base when using calibration by the concentration ratio in analysis of carbonate rocks, technical materials, slags containing less than 20% SiO2 and more than 20% CaO. An equation is derived to calculate the content of components determined in carbonate materials when using calibration by the concentration ratio. A method of ICP-AES with calibration by the concentration ratio is developed for determination of CaO (in the range of contents 20 – 100%), SiO2 (2.0 – 35%), Al2O3 (0.1 – 30%), MgO (0.1 – 20%), Fe2O3 (0.5 – 40%), Na2O (0.1 – 15%), K2O (0.1 – 5%), P2O5 (0.001 – 2%), MnO (0.01 – 2%), TiO2 (0.01 – 2.0%) in various carbonate materials. Acid decomposition of the samples in closed vessels heated in a HotBlock 200 system is proposed. Correctness of the procedure is confirmed in analysis of standard samples of rocks. The developed procedure was used during the interlaboratory analysis of the standard sample of slag SH17 produced by ZAO ISO (Yekaterinburg, Russia).

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Determination of non-metallic inclusions in metal alloys by spark atomic emission spectrometry (review)

Industrial laboratory Diagnostics of materials ◽

10.26896/1028-6861-2018-84-12-5-19 ◽

2018 ◽

Vol 84 (12) ◽

pp. 5-19

Author(s):

D. N. Bock ◽

V. A. Labusov

Keyword(s):

Spectral Line ◽

Internal Standard ◽

Detection Limits ◽

Radiation Detectors ◽

Metal Alloys ◽

Emission Spectrometry ◽

Direct Production ◽

Metallic Inclusions ◽

Dissolved Form

A review of publications regarding detection of non-metallic inclusions in metal alloys using optical emission spectrometry with single-spark spectrum registration is presented. The main advantage of the method - an extremely short time of measurement (~1 min) – makes it useful for the purposes of direct production control. A spark-induced impact on a non-metallic inclusion results in a sharp increase (flashes) in the intensities of spectral lines of the elements that comprise the inclusion because their content in the metal matrix is usually rather small. The intensity distribution of the spectral line of the element obtained from several thousand of single-spark spectra consists of two parts: i) the Gaussian function corresponding to the content of the element in a dissolved form, and ii) an asymmetric additive in the region of high intensity values ??attributed to inclusions. Their quantitative determination is based on the assumption that the intensity of the spectral line in the single-spark spectrum is proportional to the content of the element in the matter ablated by the spark. Thus, according to the calibration dependence constructed using samples with a certified total element content, it is possible not only to determine the proportions of the dissolved and undissolved element, but also the dimensions of the individual inclusions. However, determination of the sizes is limited to a range of 1 – 20 µm. Moreover, only Al-containing inclusions can be determined quantitatively nowadays. Difficulties occur both with elements hardly dissolved in steels (O, Ca, Mg, S), and with the elements which exhibit rather high content in the dissolved form (Si, Mn). It is also still impossible to determine carbides and nitrides in steels using C and N lines. The use of time-resolved spectrometry can reduce the detection limits for inclusions containing Si and, possibly, Mn. The use of the internal standard in determination of the inclusions can also lower the detection limits, but may distort the results. Substitution of photomultipliers by solid-state linear radiation detectors provided development of more reliable internal standard, based on the background value in the vicinity of the spectral line. Verification of the results is difficult in the lack of standard samples of composition of the inclusions. Future studies can expand the range of inclusions to be determined by this method.

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