Interlayer chip cooling apparatus

What is claimed is: 1 . A structure for use with an integrated circuit (IC), the structure comprising: a first element having a first surface; a second element in a stacked arrangement with the first element, the second element having a second surface disposed opposite to the first surface; a set of discrete connecting structures disposed between the first surface and the second surface; and a first fluidic channel boundary formed by a structured arrangement of a first portion of the set of discrete connecting structures, the structured arrangement resulting in a first internal fluidic impedance within the first fluidic channel boundary that is greater than an external fluidic impedance outside of the first fluid channel boundary. 2 . The structure of claim 1 , wherein the structured arrangement of a first portion of the set of discrete connecting structures includes a spacing between adjacent discrete connecting structures. 3 . The structure of claim 1 , wherein the structured arrangement of a first portion of the set of discrete connecting structures includes, between adjacent discrete connecting structures, a first spacing, at a first location, and a second spacing, at a second location. 4 . The structure of claim 1 , wherein the first element includes the IC. 5 . The structure of claim 1 , wherein the first surface is in thermally conductive contact with the IC. 6 . The structure of claim 1 further comprising a first set of attachment sites on the first surface and a second set of attachment sites on the second surface, the second set of attachment sites corresponding to the first set of attachment sites, wherein the set of discrete connecting structures is attached to the first set of attachment sites and to the second set of attachment sites. 7 . The structure of claim 6 , wherein the first set of attachment sites and the second set of attachment sites are metallic pads, and wherein the set of discrete connecting structures includes metallic posts, and wherein the set of discrete connecting structures creates, between the first element and the second element, at least one connection type of a group consisting of: an electrical connection, a mechanical connection and a thermal connection. 8 . The structure of claim 1 , wherein the set of discrete connecting structures includes a group of discrete connecting structures in a fine-pitch arrangement, having a pitch between 5 μm and 50 μm. 9 . The structure of claim 1 , wherein the set of discrete connecting structures includes a group of discrete connecting structures in a coarse-pitch arrangement, having a pitch greater than 50 μm. 10 . The structure of claim 1 , wherein the set of discrete connecting structures includes a first group of discrete connecting structures in a fine-pitch arrangement, the first group of discrete connecting structures having a first height that is different than a second height of a second group of discrete connecting structures in a coarse-pitch arrangement. 11 . The structure of claim 1 , the structure further comprising: a second fluidic channel boundary formed by a structured arrangement of a second portion of the set of discrete connecting structures, wherein the structured arrangement resulting in, within the second fluidic channel boundary, a second internal fluidic impedance that is greater than the external fluidic impedance outside of the second fluidic channel boundary; and a fluidic channel, defined by the first and second fluidic channel boundaries and the first and second surfaces, wherein the first internal fluidic impedance and the second internal fluidic impedance are each greater than the external fluidic impedance outside of the first and second fluidic channel boundaries, within the fluidic channel. 12 . The structure of claim 11 , wherein members of at least one fluidic boundary pair of a group consisting of: the first and second fluidic channel boundaries, and the first and second surfaces are positioned in a divergent orientation, to cause the fluidic channel to be tapered. 13 . The structure of claim 11 , wherein at least one of a group consisting of: a structured arrangement of a first portion of the set of discrete connecting structures and a structured arrangement of a second portion of the set of discrete connecting structures is one of a group consisting of: a substantially linear inline arrangement and a substantially linear staggered arrangement. 14 . A system for removing heat from an integrated circuit (IC), the system comprising: a structure, the structure including: the IC, in thermally conductive contact with a first surface of the structure; a first element, the first element having the first surface; a second element in a stacked arrangement with the first element, the second element having a second surface disposed opposite to the first surface; a first fluidic channel boundary including a first portion of a set of discrete connecting structures, the first fluidic channel boundary disposed between the first surface and the second surface; a second fluidic channel boundary including a second portion of the set of discrete connecting structures, the second fluidic channel boundary disposed between the first surface and the second surface, the first and second fluidic channel boundaries, and the first and second surfaces defining a fluidic channel; an inlet port, the inlet port disposed adjacent to a first end of the fluidic channel; and an outlet port, the outlet port disposed adjacent to a second end of the fluidic channel; and a primary cooling loop, the primary cooling loop coupled to the outlet port and to the inlet port, the primary cooling loop including: a condenser, the condenser having an inlet port coupled to the outlet port of the structure, the condenser further having an outlet port coupled to an inlet port of a first pump; and the first pump, the first pump having an outlet port coupled to the inlet port of the structure, the first pump configured to pump coolant through the structure. 15 . The system of claim 14 , further comprising an enclosure, the enclosure having an inlet port coupled to the inlet port of the structure, the enclosure further having an outlet port coupled to the outlet port of the structure. 16 . The system of claim 14 , the system further comprising a secondary cooling loop, the secondary cooling loop including a second pump coupled to a dry/wet cooler, the second pump further coupled to a coolant reservoir associated with the condenser. 17 . A method of operating a structure for cooling an integrated circuit (IC), the method comprising: pumping a coolant from a coolant reservoir into the structure, wherein a first surface of the structure is in thermally conductive contact with the IC, the structure including: a first element, the first element having the first surface; a second element in a stacked arrangement with the first element, the second element having a second surface disposed opposite to the first surface; a first fluidic channel boundary including a first portion of a set of discrete connecting structures, the first fluidic channel boundary disposed between the first surface and the second surface; and a second fluidic channel boundary including a second portion of the set of discrete connecting structures, the second fluidic channel boundary disposed between the first surface and the second surface, wherein the first and second fluidic channel boundaries and the first and second surfaces define a fluidic channel; an inlet port, the inlet port disposed adjacent