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Применение термодинамического моделирования для оптимизации ИСП-АЭС определения германия в металлургических материалах. / Belozerova, A. A; Mayorova, A. V.; Bardina, M. N.
в: Журнал Сибирского Федерального университета. Серия: Химия, Том 17, № 1, 2024, стр. 116-125.

Результаты исследований: Вклад в журналСтатьяРецензирование

Harvard

Belozerova, AA, Mayorova, AV & Bardina, MN 2024, 'Применение термодинамического моделирования для оптимизации ИСП-АЭС определения германия в металлургических материалах', Журнал Сибирского Федерального университета. Серия: Химия, Том. 17, № 1, стр. 116-125.

APA

Belozerova, A. A., Mayorova, A. V., & Bardina, M. N. (2024). Применение термодинамического моделирования для оптимизации ИСП-АЭС определения германия в металлургических материалах. Журнал Сибирского Федерального университета. Серия: Химия, 17(1), 116-125.

Vancouver

Belozerova AA, Mayorova AV, Bardina MN. Применение термодинамического моделирования для оптимизации ИСП-АЭС определения германия в металлургических материалах. Журнал Сибирского Федерального университета. Серия: Химия. 2024;17(1):116-125.

Author

Belozerova, A. A ; Mayorova, A. V. ; Bardina, M. N. / Применение термодинамического моделирования для оптимизации ИСП-АЭС определения германия в металлургических материалах. в: Журнал Сибирского Федерального университета. Серия: Химия. 2024 ; Том 17, № 1. стр. 116-125.

BibTeX

@article{3879cc0c43e3476787b3f0b39e41df8f,
title = "Применение термодинамического моделирования для оптимизации ИСП-АЭС определения германия в металлургических материалах",
abstract = "Using thermodynamic modeling, non-spectral matrix interference from macrocomponents (iron, chromium, molybdenum, tungsten, nickel, cobalt) on the intensity of the spectral lines of germanium was studied when it was determined using inductively coupled plasma atomic emission spectrometry. Based on the results of thermodynamic modeling, it was established that in the low-temperature plasma region (4000–6000 K) matrix non-spectral interference from Fe, Cr, Mo, W, Ni and Co is observed, associated with an ionization shift in equilibrium, at a concentration of matrix elements above 20 mg/l. Matrix spectral interference on germanium emission lines has been studied experimentally. It has been established that spectral interference from nickel, chromium, molybdenum, cobalt, tungsten is observed on the Ge I spectral line 206.866 nm, on the Ge I 209.426 nm line from cobalt, on the Ge I 219.871 nm line from tungsten, on the Ge I 209.426, Ge I line 219.871 and Ge I 303.907 nm from molybdenum. If there is no tungsten in the analyzed solution (less than 1 mg/l), the spectral line Ge I 219.871 nm can be used to determine germanium. If the analyzed solution contains tungsten and molybdenum with a concentration of no more than 10 mg/l, it is recommended to use the spectral lines Ge I 265.118 and Ge I 303.907 nm. Since germanium emission lines are not free from spectral overlaps from macrocomponents, experimental study of non-spectral matrix interference is impossible. To reduce detection limits and increase the accuracy of atomic emission with inductively coupled plasma determination of germanium in metallurgical materials, preliminary separation of germanium and matrix components is necessary. {\textcopyright} Siberian Federal University. All rights reserved.",
author = "Belozerova, {A. A} and Mayorova, {A. V.} and Bardina, {M. N.}",
note = "Работа выполнена при финансовой поддержке РНФ (проект No 23–23–00138) с использованием оборудования ЦКП «Урал-М».",
year = "2024",
language = "Русский",
volume = "17",
pages = "116--125",
journal = "Журнал Сибирского Федерального университета. Серия: Химия",
issn = "1998-2836",
publisher = "Сибирский федеральный университет",
number = "1",

}

RIS

TY - JOUR

T1 - Применение термодинамического моделирования для оптимизации ИСП-АЭС определения германия в металлургических материалах

AU - Belozerova, A. A

AU - Mayorova, A. V.

AU - Bardina, M. N.

N1 - Работа выполнена при финансовой поддержке РНФ (проект No 23–23–00138) с использованием оборудования ЦКП «Урал-М».

PY - 2024

Y1 - 2024

N2 - Using thermodynamic modeling, non-spectral matrix interference from macrocomponents (iron, chromium, molybdenum, tungsten, nickel, cobalt) on the intensity of the spectral lines of germanium was studied when it was determined using inductively coupled plasma atomic emission spectrometry. Based on the results of thermodynamic modeling, it was established that in the low-temperature plasma region (4000–6000 K) matrix non-spectral interference from Fe, Cr, Mo, W, Ni and Co is observed, associated with an ionization shift in equilibrium, at a concentration of matrix elements above 20 mg/l. Matrix spectral interference on germanium emission lines has been studied experimentally. It has been established that spectral interference from nickel, chromium, molybdenum, cobalt, tungsten is observed on the Ge I spectral line 206.866 nm, on the Ge I 209.426 nm line from cobalt, on the Ge I 219.871 nm line from tungsten, on the Ge I 209.426, Ge I line 219.871 and Ge I 303.907 nm from molybdenum. If there is no tungsten in the analyzed solution (less than 1 mg/l), the spectral line Ge I 219.871 nm can be used to determine germanium. If the analyzed solution contains tungsten and molybdenum with a concentration of no more than 10 mg/l, it is recommended to use the spectral lines Ge I 265.118 and Ge I 303.907 nm. Since germanium emission lines are not free from spectral overlaps from macrocomponents, experimental study of non-spectral matrix interference is impossible. To reduce detection limits and increase the accuracy of atomic emission with inductively coupled plasma determination of germanium in metallurgical materials, preliminary separation of germanium and matrix components is necessary. © Siberian Federal University. All rights reserved.

AB - Using thermodynamic modeling, non-spectral matrix interference from macrocomponents (iron, chromium, molybdenum, tungsten, nickel, cobalt) on the intensity of the spectral lines of germanium was studied when it was determined using inductively coupled plasma atomic emission spectrometry. Based on the results of thermodynamic modeling, it was established that in the low-temperature plasma region (4000–6000 K) matrix non-spectral interference from Fe, Cr, Mo, W, Ni and Co is observed, associated with an ionization shift in equilibrium, at a concentration of matrix elements above 20 mg/l. Matrix spectral interference on germanium emission lines has been studied experimentally. It has been established that spectral interference from nickel, chromium, molybdenum, cobalt, tungsten is observed on the Ge I spectral line 206.866 nm, on the Ge I 209.426 nm line from cobalt, on the Ge I 219.871 nm line from tungsten, on the Ge I 209.426, Ge I line 219.871 and Ge I 303.907 nm from molybdenum. If there is no tungsten in the analyzed solution (less than 1 mg/l), the spectral line Ge I 219.871 nm can be used to determine germanium. If the analyzed solution contains tungsten and molybdenum with a concentration of no more than 10 mg/l, it is recommended to use the spectral lines Ge I 265.118 and Ge I 303.907 nm. Since germanium emission lines are not free from spectral overlaps from macrocomponents, experimental study of non-spectral matrix interference is impossible. To reduce detection limits and increase the accuracy of atomic emission with inductively coupled plasma determination of germanium in metallurgical materials, preliminary separation of germanium and matrix components is necessary. © Siberian Federal University. All rights reserved.

UR - http://www.scopus.com/inward/record.url?partnerID=8YFLogxK&scp=85190419792

M3 - Статья

VL - 17

SP - 116

EP - 125

JO - Журнал Сибирского Федерального университета. Серия: Химия

JF - Журнал Сибирского Федерального университета. Серия: Химия

SN - 1998-2836

IS - 1

ER -

ID: 55698322