In-well saline fluid control

The invention claimed is: 1. A well tool for use within a wellbore, comprising: a body defining an enclosed fluid passage, the passage comprising at least two adjacent inlets and a plurality of outlet fluid passages; and a bipolar electrode changeable between a first, energized state, and a second, different state, the bipolar electrode in the first state produces an ion depletion zone that presents a flow restriction to saline fluids in the fluid passage; wherein the bipolar electrode is positioned at least partially within at least one of the at least two adjacent inlets, and where the bipolar electrode, when in the energized state, produces an ion depletion zone in fewer than all of the outlet fluid passages. 2. The well tool of claim 1 , where the body defines a fluid diode; and where the bipolar electrode, when in the energized state, produces the ion depletion zone in at least one of the at least two adjacent inlet fluid passages. 3. The well tool of claim 2 , where the fluid diode comprises a generally disk-shaped cavity having a central outlet in the cavity, where one of the two inlet fluid passages is directed more toward the central outlet than the other of the two inlet passages. 4. The well tool of claim 1 , where the well tool comprises a well screen assembly comprising a base pipe and a filtration screen encircling the base pipe, the filtration screen having filtration apertures sized to filter against particulate of a specified size and larger into an annular space between the filtration screen and the base pipe; and where the filtration screen comprises the body and the enclosed fluid passage comprises one or more filtration apertures in the filtration screen. 5. The well tool of claim 1 , where the well tool comprises a well screen assembly comprising a base pipe and a filtration screen encircling the base pipe, the filtration screen having filtration apertures sized to filter against particulate of a specified size and larger into an annular space between the filtration screen and the base pipe; and where the body is disposed so that the fluid passage is fluidically positioned between the annular space and a central bore of the base pipe. 6. The well tool of claim 5 , comprising a flow control device fluidically positioned between the body and the central bore of the base pipe. 7. The well tool of claim 1 , where the body comprises a plurality of enclosed fluid passages of which the first-mentioned enclosed fluid passage is a part, and the well tool comprises a plurality of bipolar electrodes associated with at least a subset of the enclosed fluid passages. 8. The well tool of claim 1 , where, in the second state, the bipolar electrode is not energized and produces no ion depletion zone in the fluid passage. 9. The well tool of claim 1 , comprising a second bipolar electrode changeable between a first, energized state, and a second, different state, where the second bipolar electrode in the first state produces an ion depletion zone that presents a flow restriction to saline fluids in the fluid passage. 10. The well tool of claim 1 , where the body defines a second enclosed fluid passage; and the well tool comprises a second bipolar electrode changeable between a first, energized state, and a second, different state, where the second bipolar electrode in the first state produces an ion depletion zone that presents a flow restriction to saline fluids in the second enclosed fluid passage. 11. A method, comprising: receiving fluids comprising saline fluids in an enclosed fluid passage in a subterranean well, the fluid passage comprising at least two adjacent inlets and a plurality of outlet fluid passages; and generating an ion depletion zone in fewer than all of the outlet fluid passages by energizing a bipolar electrode positioned at least partially within at least one of the two adjacent inlets in the enclosed fluid passage that restricts flow of the saline fluids through the enclosed fluid passage. 12. The method of claim 11 , where receiving fluids in an enclosed fluid passage in a subterranean well comprises receiving fluids into a central bore of a well screen assembly through the enclosed fluid passage, where the well screen assembly comprises the enclosed fluid passage. 13. The method of claim 12 , where the enclosed fluid passage comprises a plurality of filtration apertures in a filtration screen of the well screen assembly. 14. The method of claim 12 , where the well screen assembly comprises an end ring with a fluid passage between a filtration screen of the screen assembly and the central bore of the screen assembly, and the enclosed fluid passage resides in the end ring. 15. The method of claim 11 , where the received fluids comprise completion fluids comprising saline fluids, and where the method comprises removing non-saline fluids from the completion fluids. 16. The method of claim 11 , where the enclosed fluid passage comprises an inlet to a fluid diode. 17. The method of claim 11 , where generating an ion depletion zone further comprises energizing a second bipolar electrode. 18. The method of claim 11 , where energizing the bipolar electrode comprises energizing the bipolar electrode in on/off pulses having a duty cycle less than 1. 19. The method of claim 11 , comprising generating more than one ion depletion zone. 20. A system for controlling saline fluids in a wellbore, comprising: a body configured for use within the wellbore defining a flow passage, the body including two adjacent inlets and a plurality of outlet fluid passages; and an ion depletion zone generator positioned at least partially within at least one of the two adjacent inlets that, when energized, generates an ion depletion zone in fewer than all of the outlet fluid passages of the flow passage to present a flow restriction to saline fluids. 21. The system of claim 20 , where the ion depletion zone generator comprises a bipolar electrode. 22. The system of claim 20 , comprising a well screen comprising the body.