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TECHNICAL REPORTS

Plant and Environment Interactions

Titanium as an Indicator of Residual Soil on Arid-Land Plants

^a Dep. of Biological Sci. and Center for Ecological Res. and Educ., Campus Box 8007, Idaho State Univ., Pocatello, ID, USA 83209
^b current address: Identity Sciences, LLC, c/o Idaho Natl. Lab. Res. Center, 2351 N. Boulevard, P.O. Box 1625, Idaho Falls, ID, USA 83415
^c current address: Dep. of Biology, Brandon Univ., 270-18th Street, Brandon, Manitoba, Canada R7A 6A9
^d current address: Div. of Environ. Biology, Natl. Sci. Foundation, Arlington, VA, USA 22230

^* Corresponding author (cooklawr{at}yahoo.com).

Received for publication January 18, 2007. Titanium (Ti) has been suggested as a soil contamination indicator for plant samples slated for trace element analysis because it is abundant in soil but not in plants. Based on results from our survey of regional soils and plants for cesium (Cs), we sought to confirm Ti as a valid soil contamination indicator reasoning that there are three sources of Ti associated with plant samples: (i) contamination during laboratory processing, (ii) vascular uptake via roots, and (iii) field soil residue on shoot surfaces. Our experiments showed that: (i) milling increased Ti by 4 mg·kg^–1, and Ti in reagents and on labware added another 5 to 6 mg·kg^–1; (ii) Ti in Crepis acuminata seedling shoots attributable to root uptake averaged 5 mg·kg^–1; (iii) soil-dusted seedlings showed elevenfold and eightfold increases in Ti and Cs, respectively. Further, investigation of shoot washing methods determined that (iv) none of seven washing agents removed all soil from any of two to seven plant species, and (v) Artemisia tridentata and Phlox hoodii specimens washed with water retained particles and displayed elemental signatures consistent with adhering soil. We conclude that Ti is a valid soil contamination indicator for arid-land plant samples, and that trace, soil-borne analytes measured in samples where Ti values are high and, hence, soil contaminated, should be described as plant associated. Furthermore, we give guidance on minimizing Ti contamination of samples during laboratory processing and on use of Ti together with washing to minimize yet gauge soil contamination during trace element analysis.

Abbreviations: SEM, scanning electron microscopy • EDS, energy dispersive spectrometry • ICP–MS, inductively coupled plasma–mass spectroscopy • ISU, Idaho State University • CAL, Calgon (0.1%) washing treatment • H₂O, deionized water washing treatment • NW, non-washed samples in washing study • SDS, sodium dodecyl sulfate (0.1%) washing treatment • EDTA, ethylenediaminetetra-acetic acid (0.1%) washing treatment • T20, Tween 20 (0.1%) washing treatment • T80, Tween 80 (0.1%) washing treatment • HCl, hydrochloric acid (0.1%) washing treatment • ANOVA, analysis of variance