SREL Reprint #3642

Calibration approach and range of observed sap flow influences transpiration estimates from thermal dissipation sensors

Mackenzie J. Dix1,2 and Doug P. Aubrey1,2

1Warnell School of Forestry and Natural Resources, University of Georgia, Athens, GA 30602, USA
2Savannah River Ecology Laboratory, University of Georgia, P.O. Drawer E, Aiken, SC 29802, USA

Abstract: Calibrating thermal dissipation (TD) sap flow sensors has become increasingly important to accurately estimate whole-tree transpiration, but it is unclear how the calibration approach itself influences the resulting coefficients and estimates. Here, we compare the two most common calibration approaches, gravimetric and potometric, using TD sensors inserted into Eucalyptus benthamii tree stems. The gravimetric approach uses an excised stem segment devoid of branches and leaves and pushes water through the stem using gravity, a positive force. The potometric approach uses a severed stem containing an intact canopy placed upright in a reservoir where water is pulled through the stem via transpiration, a negative force. We hypothesized that the positive pressure associated with gravimetric calibration would overestimate conductive sapwood area relative to that estimated from potometric calibration and that coefficients from these different approaches would result in different estimates of transpiration when applied to intact trees. We also predicted that calibrations could improve transpiration estimates by targeting the range of observed sap flow rates (i.e., K values) in intact trees. Conductive sapwood area was higher under gravimetric calibrations and resulting estimates of transpiration were lower compared to potometric calibrations. Segmented calibration curves, which fit two separate curves for the relationship between sap flux density (Fd) and sap flux index (K) based on the range of sap flow rates observed in intact trees, increased transpiration estimates from both gravimetric and potometric coefficients and diminished the magnitude of difference in transpiration estimates between approaches. Researchers should be aware that calibration approach and range of observed sap flow profoundly influences transpiration estimates from TD sensors and this likely applies to calibrations of other heat-based sap flow sensors.

Keywords: Ecohydrology, Gravimetric, Potometric, Power function, Segmented regression, Sap flux, Water use, Granier sensors

SREL Reprint #3642

Dix, M. J. and D. P. Aubrey. 2021. Calibration approach and range of observed sap flow influences transpiration estimates from thermal dissipation sensors. Agricultural and Forest Meteorology 307(2021): 108534.

This information was provided by the University of Georgia's Savannah River Ecology Laboratory (srel.uga.edu).