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Method for quantification of analytes in a titanium, tin or silcon tetrachloride sample

a technology of titanium and silcon tetrachloride, which is applied in the field of method for quantification of analytes in titanium, tin or silcon tetrachloride samples, can solve the problems of difficult analysis using, corrosion and water-sensitive nature of certain compositions such as titanium, tin and silicon tetrachloride pose challenges in icp-ms analysis

Inactive Publication Date: 2007-12-20
EI DU PONT DE NEMOURS & CO
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Benefits of technology

The patent describes a method for detecting analytes in samples containing titanium, tin, or silicon tetrachloride using an inductively coupled mass spectrometer. The method involves contacting the sample with an aqueous solution of a stabilizing acid and forming a solution of the sample and the acid by agitating the sample. The resulting solution is then introduced into the inductively coupled mass spectrometer and detected using a gas. The method can detect multiple impurities in the sample and is compatible with the analysis of samples containing high levels of interference. It can also be used with a collision / reaction cell-equipped inductively coupled mass spectrometer. The method can be used with samples containing major proportions of titanium tetrachloride and can detect additional elements such as arsenic, antimony, aluminum, silicon, calcium, vanadium, tin, iron, chromium, copper, cadmium, lead, magnesium, manganese, nickel, niobium, zirconium, zinc, barium, cobalt, and mercury. The method can also be used to make an aqueous sample suitable for analysis by inductively coupled plasma mass spectrometry.

Problems solved by technology

However, certain compositions such as titanium, tin and silicon tetrachloride pose challenges in the ICP-MS analysis.
Neat titanium tetrachloride for example made by the chlorination of titanium-bearing ores, such as ilmenite or rutile, can be challenging to analyze using ICP-MS because it is known to be corrosive and water-sensitive.
Tin and silicon tetrachloride are also known to be corrosive and water-sensitive.
Several problems exist with the hydride-generation method, however.
The hydride-generation method does not work for all elements of interest, especially including vanadium, iron, copper, niobium, and mercury, among others, thereby requiring a second instrumental method for their determination.
Also, undesirable hydride gases such as AsH3 can be produced in the hydride-generation method.
Moreover, the additional pretreatment steps for converting TiCl4 to titanium dioxide then digesting the titanium dioxide significantly increase the time required to complete the analysis and add additional opportunities for sample preparation error and contamination.
When in collision mode, larger polyatomic ions will undergo more collisions than monoatomic ions of the same nominal mass, causing them to lose more energy.
Using ICP-MS for detecting impurities in titanium tetrachloride poses a problem because the liquid titanium tetrachloride must be formed into a solution that is safe to handle and compatible with the elemental analysis instrumentation.
Tin and silicon tetrachloride pose similar challenges.
This technique cannot prevent the loss of the more volatile impurities in making up the solution.
Also, with this method it is difficult to have tight control over the specific gravity of the final solution making reproducibility difficult.
It is also more difficult to know the exact masses of the analytes of interest in the starting solution compared to the final composition.
This method has the same problems as the addition directly to water described in Wang et al., where control of the resulting concentration is difficult.
The titanate solution can be sensitive to precipitation when reacted with water which can make the preparation of the baseline standards problematic.
This procedure is not quantitative for all potential elements of interest.
It also leaves residual chlorides present, has difficulty in reproducibility, can result in the formation of insoluble sulfates, and can impact sensitivity.
All these techniques add steps for analysis and pose problems associated with converting the titanium tetrachloride composition.
Methods that remove chloride interferences by converting the titanium tetrachloride into a solid compound such as titanium dioxide or titanyl sulfate add additional steps which can cause quantitative errors, increase the potential for measurement errors and add to the processing time.

Method used

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  • Method for quantification of analytes in a titanium, tin or silcon tetrachloride sample
  • Method for quantification of analytes in a titanium, tin or silcon tetrachloride sample

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example 1

Detection and Measurement of Inorganic Impurities in TiCl4

[0084]A 10 mL (17.28 g) aliquot of a TiCl4 sample was transferred into a 100 mL volumetric flask. The flask was placed into a tray filled with ice water. The tray was fitted with a lid that allows the top portion of the volumetric flask to be accessed while still holding the flask in place. The tray was placed on top of a shaker plate. In a separate ice bath, a 20% HCl solution was chilled to less than 10° C. After the TiCl4 aliquot was chilled to below 10° C., one drop of 20% HCl was added to the volumetric flask. The resulting reaction is exothermic. The shaker plate was turned on low and allowed to swirl the solution until it was recooled to less than 10° C. Additions of the 20% HCl were continued in this fashion until a mixture of thick yellow liquid and porous yellow solids were obtained. At this point, the rate of addition of HCl solution was increased with continued mixing of the solution. After the volumetric flask w...

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Abstract

This disclosure relates to a method for detecting at least one analyte in a tetrachloride sample comprising titanium, tin or silicon tetrachloride; comprising,(a) adding a mixture of water and acid, typically hydrochloric acid, to the sample under conditions effective for forming an aqueous solution of the sample;(b) introducing the aqueous solution of the sample into an inductively coupled mass spectrometer having a cell selected from the group of a reactive cell and a collision cell or both and producing an analyte ion comprising an interfering species;(c) contacting the analyte ion with a gas to produce a product which is substantially free from the interfering species; and(d) detecting and measuring at least one signal from the analyte in the solution. This disclosure further relates to a method for making an aqueous titanium, tin or silicon tetrachloride sample suitable for analysis in using inductively coupled plasma mass spectroscopy.

Description

BACKGROUND OF THE DISCLOSURE[0001]1. Field of the Disclosure[0002]The disclosure relates to a method for quantification of analytes in a sample comprising titanium, tin and / or silicon tetrachloride using inductively coupled plasma mass spectrometry (ICP-MS), particularly the quantification of inorganic analytes such as lead, arsenic and antimony. This disclosure also relates to a method for forming a stable aqueous solution of a sample comprising titanium, tin and / or silicon tetrachloride.[0003]2. Description of the Related Art[0004]Arsenic and antimony can be present in ores from which a titanium, tin or silicon tetrachloride composition useful as a starting material is derived. Most ores contain a variety of impurities that can end up in the compounds produced from them, such as the production of titanium tetrachloride from carbochlorination. Metals can also be useful in producing chlorides such as in the chlorination of tin to form tin tetrachloride. Tin is produced from tin-cont...

Claims

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Application Information

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Patent Type & Authority Applications(United States)
IPC IPC(8): H01L21/00
CPCB01J8/1809C01G23/024C01G19/04
Inventor HELBERG, LISA EDITHMARSH, JANE RAMSEYWESTPHAL, CRAIG STEVEN
Owner EI DU PONT DE NEMOURS & CO
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