Improvement of the analytical performance in RF-GD-OES for non-conductive materials by means of thin conductive layer deposition and the presence of a magnetic field

Alberts, Deborah; Thérèse, L.; Guillot, Philippe; Pereiro, Rosario; Sanz‐Medel, Alfredo; Belenguer, Philippe; Ganciu, M.

doi:10.1039/c002999h

Cited by 9 publications

(14 citation statements)

References 20 publications

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“…17,18,22 Here, we demonstrate the effects of the magnetic field strength under different experiment conditions, namely, the discharge pressure and the rfpower.…”

Section: Optimization Of Parameters For Signal Enhancement Of the Stamentioning

confidence: 99%

“…10,16 For a mass spectrometry, the sputtering rate and ionization efficiency play important roles in achieving the optimum analytical performance, 16 which could also be influenced by other factors such as gas pressure, rf-power, sample thickness, lattice binding energy of sample and so on. 17,18 With radio frequency (rf) discharges, nonconducting materials can be analyzed directly. However, the generator power is usually coupled capacitive to the plasma, so that the plasma power decreases with increasing thickness, thus sputtering rates, sensitivities and signal intensity decrease at the same time.…”

Section: Introductionmentioning

confidence: 99%

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Signal Enhancement with Stacked Magnets for High-Resolution Radio Frequency Glow Discharge Mass Spectrometry

et al. 2017

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ABSTRACT:A method for signal enhancement utilizing stacked magnets was introduced into high-resolution radio frequency glow discharge-mass spectrometry (rf-GD-MS) for significantly improved analysis of inorganic materials. Compared to the block magnet, the stacked magnets method was able to achieve 50−59% signal enhancement for typical elements in Y2O3, BSO, and BTN samples. The results indicated that signal was enhanced as the increase of discharge pressure from 1.3 to 8.0 mPa, the increase of rf-power from 10 to 50 W with a frequency of 13.56 MHz, the decrease of sample thickness, and the increase of number of stacked magnets. The possible mechanism for the signal enhancement was further probed using the software "Mechanical APDL (ANSYS) 14.0". It was found that the distinct oscillated magnetic field distribution from the stacked magnets was responsible for signal enhancement, which could extend the movement trajectories of electrons and increase the collisions between the electrons and neutral particles to increase the ionization efficiency. Two NIST samples were used for the validation of the method, and the results suggested that relative errors were within 13% and detection limit for six transverse stacked magnets could reach as low as 0.0082 μg g −1 . Additionally, the stability of the method was also studied. RSD within 15% of the elements in three nonconducting samples could be obtained during the sputtering process. Together, the results showed that the signal enhancement method with stacked magnets could offer great promises in providing a sensitive, stable, and facile solution for analyzing the nonconducting materials.

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“…17,18,22 Here, we demonstrate the effects of the magnetic field strength under different experiment conditions, namely, the discharge pressure and the rfpower.…”

Section: Optimization Of Parameters For Signal Enhancement Of the Stamentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Signal Enhancement with Stacked Magnets for High-Resolution Radio Frequency Glow Discharge Mass Spectrometry

et al. 2017

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“…In one, they discussed the use of pulsed RF-GD-OES for depth-profile quantification of metallic coatings. 303 In addition, the authors determined the effect of applying a magnetic field during the GD analysis and found that it offered the advantages of increased sputtering rates, better ionisation and better excitation efficiencies and, hence, an overall improvement in emission intensity was achieved. A comparison of emission intensities and emission yield parameters was made with the continuous mode of operation.…”

Section: 253mentioning

confidence: 99%

Atomic spectrometry update. Industrial analysis: metals, chemicals and advanced materials

Carter

Fisher

Goodall

et al. 2011

J. Anal. At. Spectrom.

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Metals 1.1 Ferrous metals and alloys 1.2 Non-ferrous metals and alloys 2 Chemicals 2.1 Petroleum and petroleum products 2.1.1 Petroleum products -gasoline, diesels, gasohol, exhaust particulates 2.1.2 Fuel -coal, fly ash, particulates/emissions 2.1.3 Oils -crude oil, lubricants 2.1.4 Alternative fuels 2.2 Organic chemicals and solvents 2.2.1 The analysis of archaeological and art objects 2.2.2 LIBS and other laser techniques 2.2.3 Mass spectrometric techniques 2.2.4 Ion beam techniques 2.2.5 Speciation 2.2.6 Extraction, preconcentration and sample introduction 2.3 Inorganic chemicals and acids 2.3.1 Reviews, overviews and CRMs 2.3.2 Cements, concretes and plasters 2.3.3 Matrix modifiers 2.3.4 Forensic applications 2.3.5 Other applications 2.3.6 The analysis of nano-structures 2.3.6.1 Reviews and CRMs 2.3.6.2 Methods of analysis 2.4 Nuclear materials 2.4.1 Reviews and overviews 2.4.2 Nuclear forensic and safeguards applications 2.4.3 Other nuclear applications 3 Advanced materials 3.1 Polymeric materials and composites

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“…[5][6][7][8][9][10] Additionally, several methodological strategies, such as use of plasma gas mixtures, deposition of conductive thin layers, or magnetically boosted glow discharges, have been investigated using rf-GD spectroscopy to further enhance the analytical capabilities of this technique. [11][12][13][14][15] Particularly, in magnetically boosted GD, the combination of an external magnetic field and the electric field, applied between the anode and the cathode, causes modifications in the charged particle motion within the GD plasma. At the relatively low magnetic fields employed in glow discharge spectroscopy, only electron trajectories are significantly affected as ions are much heavier and their paths more difficult to alter.…”

Section: Introductionmentioning

confidence: 99%

“…26,27 The magnetic field is usually applied by means of permanent magnets placed behind the sample, which implies that the magnetic field strength generated in the GD plasma is a function of the sample thickness. 11,26 Additionally, the application of axial magnetic fields with this experimental configuration significantly affects the produced crater shapes, which are more crowned, in detriment to the achieved depth resolution. 23,27 On the other hand, in transverse configuration the magnetic field is applied parallel to the sample surface and perpendicular to the axis along the cylindrical anode.…”

Section: Introductionmentioning

confidence: 99%

An improved analytical performance of magnetically boosted radiofrequency glow discharge

Vega

Valledor

Pisonero

et al. 2012

J. Anal. At. Spectrom.

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Improvement of the analytical performance in RF-GD-OES for non-conductive materials by means of thin conductive layer deposition and the presence of a magnetic field

Cited by 9 publications

References 20 publications

Signal Enhancement with Stacked Magnets for High-Resolution Radio Frequency Glow Discharge Mass Spectrometry

Signal Enhancement with Stacked Magnets for High-Resolution Radio Frequency Glow Discharge Mass Spectrometry

Atomic spectrometry update. Industrial analysis: metals, chemicals and advanced materials

An improved analytical performance of magnetically boosted radiofrequency glow discharge

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