Abstract

Oak savannas, once common in the Midwest, are now isolated remnants within agricultural landscapes. Savanna remnants are frequently encroached by invasive trees to become woodlands. Thinning and prescribed burning can restore savanna structure, but the ecohydrological effects of managing these remnants are poorly understood. In this study, we measured sap flow ( J s) to quantify transpiration in an Iowa bur oak ( Quercus macrocarpa) savanna woodland encroached by elms ( Ulmus americana), and in an adjacent restored savanna after thinning to remove elms, during summer 2004. Savanna oaks had greater mean daily J s (35.9 L dm −2 day −1) than woodland oaks (20.7 L dm −2 day −1) and elms (12.4 L dm −2 day −1). The response of J s to vapor pressure deficit ( D) was unexpectedly weak, although oaks in both stands showed negative correlation between daily J s and D for D > 0.4 kPa. An earlier daily peak in J s in the elm trees showed a possible advantage for water uptake. As anticipated, the woodland's stand transpiration was greater (1.23 mm day −1) than the savanna's (0.35 mm day −1), yet the savanna achieved 30% of the woodland's transpiration with only 11% of its sapwood area. The difference in transpiration influenced water table depths, which were 2 m in the savanna and 6.5 m in the woodland. Regionally, row-crop agriculture has increased groundwater recharge and raised water tables, providing surplus water that perhaps facilitated elm encroachment. This has implications for restoration of savanna remnants. If achieving a savanna ecohydrology is an aim of restoration, then restoration strategies may require buffers, or targeting of large or hydrologically isolated remnants.

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