A key parameter in using plasma jets for biomedical applications is the transferred energy to the living tissues. The objective of this paper is to understand which parameters control the energy transfer from the plasma jet to a liquid or a dielectric surface. The plasma jet is own with helium and ignited by a 600 Hz ac high voltage (up to 15 kV). Capacitors are connected to two measurement electrodes placed in the plasma source region, and under the sample. Charge and energy transferred are estimated by plotting Lissajous cycles; the number of bullets and the charge probability density function are also calculated. It is shown that the applied voltage and the gap (distance between the end of the tube and the sample) have a dramatic in uence on the energy deposition on the sample as well as on the charge probability density function. Surprisingly, both gap distance and voltage have very little in uence on the number of bullets reaching the sample per cycle. It is also shown that the conductivity of the liquid sample has almost no in uence on the energy deposition and charge probability density function.