Leaf-shaped geometry for heat exchanger core

The invention claimed is: 1. A core arrangement for a heat exchanger, the core arrangement comprising: a first core layer disposed along a first plane, and comprising: an inlet oriented along a first axis within the first plane; an outlet oriented along the first axis; a first core stage disposed in fluid communication between the inlet and the outlet, the first core stage comprising: a first upstream fluid intersection downstream of and adjacent the inlet, and comprising a first inlet continuation and a first bifurcation; a first downstream fluid intersection upstream of and adjacent the outlet, and comprising a first outlet continuation and a first recombination; and a plurality of independent first core tubes fluidly connecting the first bifurcation to the first recombination; and a second core stage disposed in fluid communication between the first inlet continuation and the first outlet continuation, the second core stage comprising: a second upstream fluid intersection downstream of the first inlet continuation, and comprising a second bifurcation; a second downstream fluid intersection upstream of the first outlet continuation, and comprising a second recombination; and a plurality of independent second core tubes fluidly connecting the second bifurcation to the second recombination. 2. The core arrangement of claim 1 , wherein the first inlet continuation and the first outlet continuation are oriented along the first axis. 3. The core arrangement of claim 2 , wherein the plurality of independent first and second core tubes are arcuate tubular members disposed within the first plane. 4. The core arrangement of claim 3 and further comprising a third core stage disposed in fluid communication between the first inlet continuation and the first outlet continuation, the first core stage comprising: a third upstream fluid intersection downstream of and adjacent the first inlet continuation, and comprising a third bifurcation and a second inlet continuation upstream of and fluidly connected to the second upstream fluid intersection; a third downstream fluid intersection upstream of and adjacent the first outlet continuation, and comprising a third recombination and a second outlet continuation downstream of and fluidly connected to the second downstream fluid intersection; and a plurality of independent third core tubes fluidly connecting the third bifurcation to the third recombination. 5. The core arrangement of claim 4 , wherein the plurality of independent first, second, and third core tubes are arranged substantially concentrically within the first plane. 6. The core arrangement of claim 5 , wherein the plurality of independent first core tubes have a first diameter, the plurality of independent second core tubes have a second diameter, and the plurality of independent third core tubes have a third diameter. 7. The core arrangement of claim 6 , wherein the first diameter is greater than the second and third diameters. 8. The core arrangement of claim 4 , wherein the first core layer is symmetrical about the first axis. 9. The core arrangement of claim 1 and further comprising: a second core layer disposed along a second plane adjacent and parallel to the first plane, the second core layer comprising: an second inlet oriented along the first axis within the second plane; a second outlet oriented along the first axis; a first core stage of the second core layer similar to the first core stage of the first core layer; and a second core stage of the second core layer similar to the second core stage of the first core layer. 10. The core arrangement of claim 9 , wherein the first and second core layers are formed from one of a metallic material and a plastic material. 11. The core arrangement of claim 9 and further comprising: a plurality of connecting elements disposed between and physically contacting each of the first a second core layers. 12. A heat exchanger comprising: a core having a core arrangement comprising a plurality of core layers in a stacked arrangement, each of the plurality of core layers disposed in a core layer plane, each of the plurality of core layers comprising: an inlet oriented along a first axis within the core layer plane; an outlet oriented along the first axis; a first core stage disposed in fluid communication between the inlet and the outlet, the first core stage comprising: a first upstream fluid intersection downstream of and adjacent the inlet, and comprising a first inlet continuation and a first bifurcation; a first downstream fluid intersection upstream of and adjacent the outlet, and comprising a first outlet continuation and a first recombination; and a plurality of independent first core tubes fluidly connecting the first bifurcation to the first recombination; and a second core stage disposed in fluid communication between the first inlet continuation and the first outlet continuation, the second core stage comprising: a second upstream fluid intersection downstream of the first inlet continuation, and comprising a second bifurcation; a second downstream fluid intersection upstream of the first outlet continuation, and comprising a second recombination; and a plurality of independent second core tubes fluidly connecting the second bifurcation to the second recombination. 13. The heat exchanger of claim 12 and further comprising a third core stage disposed in fluid communication between the first inlet continuation and the first outlet continuation, the third core stage comprising: a third upstream fluid intersection downstream of and adjacent the first inlet continuation, and comprising a third bifurcation and a second inlet continuation upstream of and fluidly connected to the second upstream fluid intersection; a third downstream fluid intersection upstream of and adjacent the first outlet continuation, and comprising a third recombination and a second outlet continuation downstream of and fluidly connected to the second downstream fluid intersection; and a plurality of independent third core tubes fluidly connecting the third bifurcation to the third recombination. 14. The heat exchanger of claim 13 , wherein the plurality of independent first, second, and third core tubes are arranged substantially concentrically within the core layer plane. 15. The heat exchanger of claim 12 and further comprising: a plurality of connecting elements disposed between and physically contacting one of the plurality of core layers and an adjacent one of the plurality of core layers. 16. The heat exchanger of claim 12 , wherein each of the plurality of core layers is configured to receive a first fluid along the first axis. 17. The heat exchanger of claim 16 , wherein each of the plurality of core layers is fluidly connected to a first fluid inlet header and a first fluid outlet header. 18. The heat exchanger of claim 17 , wherein each of the first fluid inlet header and the first fluid outlet header is a bifurcated header having fractal geometry. 19. The heat exchanger of claim 16 , wherein the core is configured to receive a flow of a second fluid along a second axis perpendicular to the first axis. 20. The heat exchanger of claim 19 , wherein a temperature of the second fluid is lower than a temperature of the first fluid.