Ultrasound ablation apparatus with discrete staggered ablation zones

What is claimed is: 1. An ablation apparatus comprising an ultrasonic transducer which includes: a piezoelectric element having a cylindrical shape with a longitudinal axis, an inner surface facing inwardly toward the longitudinal axis, and an outer surface facing outwardly away from the longitudinal axis, wherein the piezoelectric element is housed inside a bore formed within a tubular wall of a non-compliant and non-porous cap; a plurality of external electrodes disposed on the outer surface of the piezoelectric element; and at least one internal electrode disposed on the inner surface of the piezoelectric element; wherein the at least one internal electrode provides corresponding internal electrode portions that are disposed opposite the plurality of external electrodes with respect to the piezoelectric element, the external electrodes and the at least one internal electrode to be energized to apply an electric field across the piezoelectric element between the external electrodes and the corresponding internal electrode portions, so as to produce ultrasonic ablation zones extending from the energized external electrodes outwardly away from the longitudinal axis; and wherein the ultrasonic ablation zones of the external electrodes are distributed in a staggered configuration so as to span one or more open arc segments around the longitudinal axis, and the ultrasound ablation zones of all the external electrodes projected longitudinally onto any lateral plane which is perpendicular to the longitudinal axis span a substantially closed loop around the longitudinal axis. 2. The ablation apparatus of claim 1 , wherein the external electrodes are discretely spaced from each other at least one of longitudinally or laterally, and at least two of the external electrodes are spaced from one another longitudinally. 3. The ablation apparatus of claim 1 , wherein the external electrodes span one or more open arc segments around the longitudinal axis, and all the external electrodes projected longitudinally onto any lateral plane which is perpendicular to the longitudinal axis span a substantially closed loop around the longitudinal axis. 4. The ablation apparatus of claim 1 , wherein the external electrodes and the at least one internal electrode are independently controlled to be energized in one of simultaneous manner, sequential manner, and arbitrary manner to produce the ultrasonic ablation zones. 5. The ablation apparatus of claim 1 , wherein the external electrodes and the at least one internal electrode are energized by radiofrequency (RF) energy. 6. The ablation apparatus of claim 1 , wherein the cap contains a fluid therein for transmitting ultrasonic energy. 7. The ablation apparatus of claim 6 , wherein the cap has a fluid inlet for fluid flow into the cap and a fluid outlet for fluid flow out of the cap. 8. The ablation apparatus of claim 1 , further comprising: a handle assembly; a shaft having a main lumen, a proximal end coupled to the handle assembly, and a distal end; a distal tip section comprising the cap and coupled to the distal end of the shaft; and an irrigation tube extending through the main lumen and having a distal end that terminates in the bore, the irrigation tube to supply irrigation fluid to the bore; wherein the ultrasonic transducer is spaced apart from the wall of the cap. 9. The ablation apparatus of claim 8 , further comprising: a plurality of thermocouple wires that are connected to the cap. 10. The ablation apparatus of claim 8 , further comprising: a plurality of ring electrodes provided in a spaced-apart manner about the outer surface of the shaft adjacent the distal tip section. 11. The ablation apparatus of claim 8 , further comprising: an inner sleeve secured in the main lumen at the distal end of the shaft. 12. The ablation apparatus of claim 8 , further comprising: an inner supporting member that extends through the main lumen of the shaft and the bore of the cap. 13. The ablation apparatus of claim 1 , further comprising: a handle assembly; a shaft having a main lumen, a proximal end coupled to the handle assembly, and a distal end; an inner sleeve secured in the main lumen; a distal tip section comprising the cap and coupled to the distal end of the shaft; an inner supporting member that extends through the main lumen of the shaft and the bore of the cap; and an outer supporting member that extends through the inner sleeve and into the bore, with the inner supporting member housed in the outer supporting member; wherein the ultrasonic transducer is spaced apart from the wall of the cap. 14. The ablation apparatus of claim 13 , wherein the inner supporting member is selected from the group consisting of a coil, and a flat wire, and is made of a material selected from the group consisting of a metal, an alloy, and a polymer. 15. An ablation apparatus comprising a body having an axis and an ultrasonic transducer connected to the body, the ultrasonic transducer including: a piezoelectric element coupled to the body, the piezoelectric element having a hollow interior, an inner surface facing the hollow interior, and an outer surface facing outwardly away from the hollow interior, wherein the piezoelectric element is housed inside a bore formed within a tubular wall of a non-compliant and non-porous cap; a plurality of external electrodes disposed on the outer surface of the piezoelectric element; and at least one internal electrode disposed on the inner surface of the piezoelectric element; wherein the at least one internal electrode provides corresponding internal electrode portions that correspond to the plurality of external electrodes, the external electrodes and the at least one internal electrode to be energized to apply an electric field across the piezoelectric element between the external electrodes and the corresponding internal electrode portions, so as to produce ultrasonic ablation zones extending from the energized external electrodes outwardly away from the hollow interior; and wherein the ultrasonic ablation zones of the external electrodes are distributed in a staggered configuration so as to span one or more open arc segments around the axis of the body, and the ultrasound ablation zones of all the external electrodes projected longitudinally onto any lateral plane which is perpendicular to the axis of the body span a substantially closed loop around the axis of the body. 16. The ablation apparatus of claim 15 , wherein the external electrodes span one or more open arc segments around the axis of the body, and all the external electrodes projected longitudinally onto any lateral plane which is perpendicular to the axis of the body span a substantially closed loop around the axis of the body. 17. The ablation apparatus of claim 15 , wherein the cap contains a fluid therein for transmitting ultrasonic energy. 18. An ablation apparatus comprising an ultrasonic transducer which includes: a piezoelectric element having a cylindrical shape with a longitudinal axis, an inner surface facing inwardly toward the longitudinal axis, and an outer surface facing outwardly away from the longitudinal axis, wherein the piezoelectric element is housed inside an expandable element sized and configured with a predetermined fully expanded diameter that is less than a diameter of an area where ablation is to occur; a plurality of external electrodes disposed on the outer surface of the piezoelectric element; and at least one internal electrode disposed on the inner su