Pressure-compensated sources

What is claimed is: 1. A sound source for marine geophysical surveys, comprising: an outer flextensional shell containing a first gas at a first gas pressure, wherein the outer flextensional shell is operable to vibrate and flex to generate acoustic energy: a compliance chamber in indirect fluid communication with the first gas such that the first gas does not intermix with second gas in the compliance chamber, wherein the second gas is at a second gas pressure, wherein the second gas pressure is lower than the first gas pressure, wherein the compliance chamber is operable to adjust a resonance frequency of the sound source to compensate for changes in the first gas pressure through a volume change in the compliance chamber; and a driver separate from the compliance chamber, wherein the driver is operable to cause vibration and flexing of the outer flextensional shell. 2. The sound source of claim 1 , wherein sound source is a flextensional-shell type source. 3. The sound source of claim 1 , wherein the sound source has at least one resonance frequency of about 10 Hz or lower. 4. The sound source of claim 1 , wherein the compliance chamber is disposed in the outer flextensional shell. 5. The sound source of claim 1 , further comprising one or more additional compliance chambers in indirect fluid communication with the first gas. 6. The sound source of claim 1 , wherein the compliance chamber comprises a tube, a piston slidable in the tube, and a spring element that exerts a biasing force against the piston. 7. The sound source of claim 6 , wherein the tube and piston define a sealed volume that contains the second gas, wherein the spring element is disposed in the sealed volume. 8. The sound source of claim 6 , wherein the spring element comprises a nonlinear spring. 9. The sound source of claim 6 , wherein the spring element comprises a stack of Belleville spring washers. 10. The sound source of claim 9 , wherein the stack of Belleville spring washers is arranged in a series stack, and wherein adjacent pairs of the Belleville spring washers in the series stack are arranged in parallel. 11. The sound source of claim 1 , wherein the compliance chamber comprises a flexible plate that together with a container defines a sealed internal volume that contains the second gas. 12. The sound source of claim 1 , wherein the compliance chamber comprises a flexible bellows that defines a sealed internal volume that contains the second gas. 13. The sound source of claim 1 , wherein the outer flextensional shell further comprises an added mass. 14. The sound source of claim 1 , wherein the sound source comprises a pressure compensation system operable to introduce a gas into the outer shell to increase the first gas pressure, wherein the compliance chamber is operable due a change in differential pressure between the first gas pressure and the second gas pressure to effect a change in volume of the compliance chamber. 15. The sound source of claim 1 , wherein the compliance chamber is operable due to a change in differential pressure between the first gas pressure and the second gas pressure to effect a volume change of the compliance chamber, wherein the compliance chamber includes a spring element to provide a biasing action to counteract increases in the first gas pressure. 16. The sound source of claim 1 , wherein the second gas pressure is less than 1 atmosphere. 17. A sound source for marine geophysical surveys, comprising: an outer shell containing a first gas at a first gas pressure; a mass coupled to the outer shell; a compliance chamber containing a second gas at a second gas pressure, wherein the second gas pressure is lower than the first gas pressure, wherein the compliance chamber is in indirect fluid communication with the first gas such that the second gas does not intermix with the first gas, wherein the compliance chamber comprises a tube, a piston slidable in the tube, and a spring element that exerts a biasing force against the piston; wherein the compliance chamber is configured to operate due to a change in a pressure differential across the piston; and a driver separate from the compliance chamber and coupled to the outer shell, wherein the driver is operable to cause vibration and flexing of the outer shell. 18. The sound source of claim 17 wherein sound source is a flextensional-shell type source. 19. The sound source of claim 17 wherein the mass is added to an outside surface of the sound source. 20. The sound source of claim 17 , wherein the second gas pressure is less than 1 atmosphere. 21. A method, comprising: disposing a sound source in a body of water, the sound source comprising: an outer shell containing a first gas at a first gas pressure; a compliance chamber in indirect fluid communication with the first gas such that a second gas in the compliance chamber does not intermix with the first gas, wherein the second gas is at a second gas pressure, wherein the second gas pressure is lower than the first gas pressure; and a driver separate from the compliance chamber, wherein the driver is operable to cause vibration and flexing of the outer shell; and operating the sound source to generate acoustic energy; and changing an internal volume of the compliance chamber in response to a pressure differential between the first gas pressure and the second gas pressure caused by the operating the sound source to adjust a resonance frequency of the sound source and thus compensate for pressure changes in the first gas pressure. 22. The method of claim 21 , wherein the compliance chamber comprises a tube, a piston slidable in the tube, and a spring element that exerts a biasing force against the piston, wherein adjusting the second gas pressure comprises displacing the piston in the tube. 23. The method of claim 22 , wherein the spring element comprises a stack of Belleville spring washers such that displacing the piston in the tube comprises compressing the stack of the Belleville spring washers. 24. The method of claim 21 , further comprising triggering the sound source to generate acoustic energy; and detecting some of the acoustic energy after it has interacted with one or more rock formations below a bottom of the body of water. 25. The method of claim 21 , wherein the resonance frequency is less about 10 Hz or less. 26. The method of claim 21 , wherein the second gas pressure is less than 1 atmosphere when the sounds source is at a depth of less than about 1 meter. 27. A method, comprising: disposing a sound source at a depth in a body of water, the sound source comprising: an outer shell containing a first gas at a first gas pressure; a compliance chamber in indirect fluid communication with the first gas, the compliance chamber comprising a sealed internal volume, wherein the second gas does not intermix with the first gas, wherein the compliance chamber comprises a tube, a piston slidable in the tube, and a spring element that exerts a biasing force against the piston; and a driver separate from the compliance chamber, wherein the driver is operable to cause vibration and flexing of the outer shell; changing the depth of the sound source in the body of water; changing the first gas pressure in response to changing the depth of the sound source; and changing the sealed internal volume of the compliance chamber in response to changing the firs