Ti in Quartz Standards

Information on Ti in Quartz standards for analysis.

A set of Ti in Quartz standards were synthesised at the Edinburgh Materials and Micro-Analysis Centre (EMMAC), University of Edinburgh. These standards followed the procedures of Biggar and O'Hara (1969) and Cairns (1983).

Ti occurs naturally in quartz as a trace element (Wark, 2006) and can be used to provide petrological information about the pressure and temperature (P-T) conditions of quartz crystallisation (Spears and Wark, 2009; Thomas et al., 2010). The result is that Ti can be used as a geothermometer and geobarometer as its solubility in quartz has a strong dependence on P-T. Therefore, it is important to have an accurate set of synthetic quartz standards with known trace Ti concentrations, which can be used to calibrate natural samples against when using a Secondary Ion Mass Spectrometry (SIMS) instrument.

Three silica glasses doped with Ti of different concentrations have been prepared, as well as a blank glass, as standard material for SIMS, electron microprobe and other micro-beam techniques. These were made by preparing gel starting mixtures from TEOS and 1000 Ti ca. AA solutions which were dried and then underwent fusion.

The set of four glasses contains:

  • Blank glass containing 100% SiO2
  • 100ppm Ti in 99.999% SiO2 glass
  • 500ppm Ti in 99.995% SiO2 glass
  • 1000ppm Ti in 99.99 SiO2 glass

The Ti is present in accurate trace concentrations that the silica was initially doped with and has been analysed independently by ICP OES, SIMS, as well as EMPA.

References

  • Biggar, G.M. and O'HaraO'Hara, M.J. 1969. A Comparison of gel starting materials for phase equilibrium studies. Mineralogical magazine, 37, pp 198-205
  • Cairnes, E. 1983. Preparation of rare earth glasses. Internal lab document.
  • Thomas, J.B., Watson, E.B, Spear, F.S., Shemella, P.T., Nayak, S.K., and Lanzirotti, A. 2010. TitaniQ under pressure: the effects of pressure and temperature on the solubility of Ti in quartz. Contributions to Mineral Petrology. 160. pp 743-759.
  • Spears, F.S. and Wark, D.A. 2009. Cathodoluminescence imaging and titanium thermometry in metamorphic quartz. Journal of Metamorphic Geology. 27. pp 187-205
  • Wark, D.A. and Watson, E.B. 2006. TitaniQ: a titanium-in-quartz geothermometer. Contributions to Mineral Petrology. 152. pp 743-754

Standard preparation

Information on the preparation Ti in quartz standards for SIMS and EPMA analysis, including a detailed description of the gel making process.

A set of 4 quartz glasses, each with a different concentration of Ti: 0% blank, 100ppm, 500ppm and 1000ppm were prepared from a synthetic gel.   Each of the 4 glasses are available on request, free of charge, to Universities and other educational establishments.

The synthetic gels were made from TEOS and Ti AA standard starting materials. Ethanol was used to ensure the miscibility of TEOS Si(OC2H5)4), the silica source. Nitric acid was added to the weighed out Ti AA standard before this new solution was mixed into the TEOS and ethanol. Concentrated ammonia (0.88vol NH4OH) was then added to the amalgamated solutions to form a gelatinous precipitate of hydroxides.

The gels were then slowly dried, starting at 70°C and increasing the temperature slowly over several days to 180°C in an oven. This was followed by a gradual heating to ~400°C and finally roasting at 900°C.  Again, this temperature was reached gradually to ensure the volatiles evaporated off slowly.

When dry and cooled to room temperature, the gels were grounded into a fine powder. A small crucible was filled 1/2 to 1/3 full with the ground gel powder and fused in a furnace at 1735°C. On removal they were quenched with water.

The doped values of 0ppm, 100ppm, 500ppm and 1000ppm Ti in a quartz glass have been verified separately by EMPA, SIMS and ICP OES instruments at the University of Edinburgh. Details of the exact values can be found in the glass composition section of this document.

A detailed description of the gel making procedure is available via PDF download:

Gel Making procedures (5.33 MB / PDF)

Titanium AA standard solution

A 1000ppm Ti AA standard in water with trace amounts of HCl was used as the titanium source for the gels. The latter was accurately weighed out for each standard to achieve the desired weight percentages of Ti for 100ppm, 500ppm and 1000ppm in the final total 10g gel yield. The calculated amounts for starting materials showed 1g of the AA solution added to 34.66973268g of TEOS gave the correct wt% of Ti for 100ppm in the final silica gel yield. 5g and 10g were added to 34.6558634g and 34.6385268g, respectively, of TEOS to achieve 500ppm Ti and 1000ppm Ti for the other two standards.

Tetraethyl Orthosilicate (TEOS)

TEOS is used to supply the silica component of the gels. It weighed out from the bottle to a Teflon beaker using a pipette and then made up more accurately with a syringe. The weight of TEOS needed to achieve a 99.99wt%, 99.95wt% and 99.9wt% of SiO2 was calculated using the molecular weight of TEOS using its chemical formula: Si(OC2H5)4 and the molecular weight ratio of the total value for TEOS and the value for just SiO2. This was altered for the amount of Ti which was being added for each gel, and was found to be 34.66973268g, 34.6558634g and 34.6385268g, of TEOS for corresponding Ti concentrations of 100ppm, 500ppm and 1000ppm, respectively, in the individual gels. A blank standard of pure silica was also made which required 34.6732g of TEOS for the desired 10g final gel yield.


The weight and volume of solutions required for each gel were calculated. These amounts were weighed into Teflon beakers using a pipette and making up the final decimal places with a syringe. A small amount of de-ionised water was added to the weighed Ti standard before 20ml of nitric acid was added whilst stirring. Next, 15ml of ethanol was added to the TEOS and mixed thoroughly before being combined with the Ti solution, the beaker which previously contained TEOS was swilled with de-ionised water, which was also added to the Ti solution to ensure as little of the starting components were lost. The combined TEOS and Ti solution was stirred vigorously to ensure complete homogenisation. As soon as possible after the addition of ethanol, 20ml of ammonia was added, again, with vigorous stirring, thereby forming the gel precipitates. The beakers were covered with loose-fitting Teflon lids to prevent loss of TEOS by evaporation and then left to stand overnight before the drying procedure could begin.

Drying the gels

The gels were transferred from Teflon beakers to Pyrex for heating. The beakers were placed over a hot plate at 70°C for 24 hours, and then the temperature gradually increased to 160°C at around 10 degrees every 2-3 hours. The gels were left at 160°C for 24hours. Any vapour crystals which formed on the side of the beaker were knocked back into the beaker by gently tapping the sides.

The gels were then transferred into Palladium-gold dishes with lids and dried in an open furnace to remove the last traces of NH4NO3. These dishes were placed in a furnace at 100°C, and the temperature gradually increased, over several hours, until a temperature of 400°C was achieved. The samples were left at this temperature overnight, and on removal, if necessary between drying and roasting, they were stored in a desiccator.

Next, the gel containers were loaded into a closed furnace at 400°C. The temperature was raised over several hours to 900°C, and the gels were roasted at this temperature overnight. On removal from the furnace, the gels were stored in a desiccator.  Once cooled to room temperature, they were then ground to a fine powder in an agate mortar and stored in bottles until required.


Small quantities of the dry gels were placed in platinum crucibles and fused in air at atmospheric pressure. The fusions took place at 1735°C for 10minutes, and on removal, were quenched in water. Three glasses were initially produced for each of the four gels, and for the three gels containing Ti, a fusion for 1 hour at 1735°C was produced, making a total of 15 samples.

After fusion, the glasses were checked for homogeneity by electron microprobe analysis (EMPA) to test if there was a difference in homogeneity between the 10minute and 1hour fusions, a very subtle difference was found, which wasn’t detrimental to the 10minute fusions. As a result, all 15 glasses were analysed on the Cameca ims-4f SIMS instrument at EMMAC, University of Edinburgh. Wet chemical analysis of 1 10minute fusion from each of the gels (0ppm, 100ppm, 500ppm and 1000ppm) was carried out using ICE OES again at the University of Edinburgh.


Ti in Quartz glass compositions

We have provided a compilation of data for SIMS, EPMA and ICP analysis of the Ti-Quartz standards.

 

0 Ti Quartz0ppm
100 Ti Quartz100ppm
500 Ti Quartz500ppm
1000 Ti Quartz1000ppm

Electron Probe Analysis (EPMA)

The data is available via Excel download:

EPMA of Ti standards, University of Edinburgh.
Ti-Qtz EPMA (40.01 KB / XLSX)
EPMA of Ti standards, University of Bristol. (S. Kearns)
Ti Quartz EPMA Bristol (xlsx) (14.45 KB Excel)
EPMA of Ti standards, University of Michigan. (Owen Neill)
Ti Quartz EPMA Michigan (xlsx) (21.03 KB Excel)

Secondary Ion Mass Spectrometry (SIMS) Analysis Relative to SRM610

The data is available via Excel download:

SIMS of Ti standards, University of Edinburgh. (C. Gallagher)
Ti-Qtz SIMS (15.58 KB / XLSX)
SIMS of Ti standards, Arizona State University. (R. Hervig)
Ti Quartz SIMS Arizona (xlsx) (20.1 KB Excel)

ICP Analysis

The data is available via Excel download:

ICP of Ti standards
Ti-QTZ ICPOES (21.54 KB / XLSX)

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