Underwater spark discharges are used in multiple practical applications including plasma closing switches, water treatment, plasma channel drilling and mineral processing, waste recycling, treatment of metals, and medical lithotripsy. Spark discharges in water have been studied for several decades, however, despite significant research efforts and progress in this area, further investigation into the efficiency of plasma-acoustic sources and their optimisation is required in order to expand their practical application. This paper is aimed at investigation of the electrical and hydrodynamic parameters of underwater plasma-generated cavities, including plasma resistance, energy delivered into the plasma cavity, period of cavity oscillations and characteristics of pressure impulses. Different energy levels, breakdown voltages and gap distances were used in the present study to allow systematic analysis of these electrical and hydrodynamic parameters. Empirical scaling relations which link the maximum acoustic pressure and the period of cavity oscillations with the energisation parameters and the resistance of plasma have been obtained. These empirical functions can be used for optimisation of the plasma-acoustic sources and for tailoring their parameters for specific practical applications. Index Terms-Underwater spark discharges, plasma resistance, hydrodynamic parameters of period of cavity, acoustic impulses I. INTRODUCTION N recent years, significant research efforts have been focused on investigation of high-voltage spark discharges in water. Such discharges have found practical application in different technological areas, including water-filled plasma closing switches used in high-voltage, pulsed-power systems [1], medical lithotripters [2], minerals engineering [3], recycling of solid materials [4, 5, 6], in water cleaning and remediation operations, and water-well cleaning operations [7]. An important area of potential practical applications of underwater spark discharges is generation of wide-band ultrasound impulses [8, 9]. Underwater, high-voltage spark discharges
