Xylem cavitation resistance can be estimated based on time-dependent rate of acoustic emissions

In this study, we focused on the use of acoustic activity as a function of time, rather than absolute cumulative emission counts. We hypothesized that the highest acoustic activity should occur near the steepest part of a typical vulnerability curve, that is, near its inflection point (P50), when most embolism is forming within a narrow range of water potential (Ψ). Therefore, the Ψ at maximum AE activity should be correlated to a species’ hydraulically measured P50

Xylem cavitation resistance can be estimated based on time‐dependent rate of acoustic emissions

Acoustic emission (AE) analysis allows nondestructive monitoring of embolism formation in plant xylem, but signal interpretation and agreement of acoustically measured hydraulic vulnerability with reference hydraulic techniques remain under debate. We compared the hydraulic vulnerability of 16 species and three crop tree cultivars using hydraulic flow measurements and acoustic emission monitoring, proposing the use of time‐dependent AE rates as a novel parameter for AE analysis. There was a linear correlation between the water potential (Ψ) at 50% loss of hydraulic conductivity (P(50)) and the Ψ at maximum AE activity (P(maxrate)), where species with lower P(50) also had lower P(maxrate) (P < 0.001, R (2) = 0.76). Using AE rates instead of cumulative counts for AE analysis allows more efficient estimation of P(50), while excluding problematic AE at late stages of dehydration