Method of fabricating memory array having divided apart bit lines and partially divided bit line selector switches

What is claimed is: 1. A method of fabricating a non-volatile data storage device comprising: providing a substrate having control elements monolithically integrated therein; providing above the substrate as a first structure, a three dimensional arrangement of non-volatile storage elements, and alternating horizontally extending layers of conductive word line layers and insulative layers; providing above the substrate and below the first structure, material layers for forming a three dimensional arrangement of vertically oriented, bit line selector devices, where the provided material layers can be patterned so that each of the formable, vertically oriented bit line selector devices has a respective output terminal and a respective control terminal; providing above the substrate and below the formable control terminals of the formable bit line selector devices, a plurality of spaced apart global bit lines; patterning the alternating layers of conductive word line layers and insulative layers so as to form spaced apart pillars each having the alternating layers of conductive word lines and insulation, the pillars having respective vertically extending sidewalls; depositing vertically extending films of memory cell forming material on the sidewalls of the pillars; depositing vertically extending films of bit line forming conductive material on sidewalls of the deposited films of memory cell forming material, the bit line forming films also extending horizontally at respective bottoms of the bit line forming films so as to continue one into the next, the respective bottoms of the bit line forming films making electrical coupling with the formable output terminals of corresponding ones of the formable, vertically oriented bit line selector devices respectively disposed below the respective films of memory cell forming material; creating electrically isolating separations between the deposited films of bit line forming conductive material so as to form vertically extending individual bit lines such that each individual bit line is electrically isolated from adjacent other individual bit lines extending vertically along adjacent vertically extending sidewalls of adjacent pillars; and creating electrically isolating separations in the material layers provided for forming the formable, vertically oriented bit line selector devices so as to thereby define individual output terminals for respective ones of the vertically oriented bit line selector devices, the defined individual output terminals respectively connecting to respective ones of the vertically extending individual bit lines formed above the defined individual output terminals. 2. The method of fabricating of claim 1 and further comprising: filling gaps between the adjacent and isolated from one another individual bit lines with an insulative gap filling material. 3. The method of fabricating of claim 1 wherein the memory cell forming material comprises a Hafnium Oxide. 4. The method of fabricating of claim 1 and further comprising: attaching respective vertically extending and resistance lowering layers to the respective deposited and vertically extending films of bit line forming conductive material, the resistance lowering layers comprising at least one of a conductive material having a lower resistivity than that of the bit line forming conductive material and a material that can react with the bit line forming conductive material to thereby form a vertically extending reaction product layer having a lower resistivity than that of the bit line forming conductive material. 5. The method of claim 4 wherein: the conductive material of the resistance lowering layers includes a metal. 6. The method of claim 4 wherein: the reaction product layer includes a silicide. 7. The method of claim 1 wherein: the memory cell forming material comprises a reversible resistance-switching material. 8. The method of claim 1 wherein: said patterning of the alternating layers to form spaced apart pillars causes the respective output terminals of pairs of successive bit line selector devices to be disposed in areas between successive ones of the pillars and causes the respective control terminals of such pairs of successive bit line selector devices to be disposed in areas under the successive ones of the pillars. 9. The method of claim 1 wherein: said patterning of the alternating layers to form spaced apart pillars is preceded by formation of conductive etch stops on top of the respective output terminals of the bit line selector devices, the etch stops functioning as stops for an anisotropic etch that forms said spaced apart pillars. 10. The method of claim 9 wherein: said conductive etch stops include TiN. 11. The method of claim 9 wherein: said depositing of the vertically extending films of bit line forming conductive material causes the films of bit line forming conductive material to contact corresponding ones of the conductive etch stops. 12. The method of claim 11 wherein: said creating of the electrically isolating separations between the deposited films of bit line forming conductive material is followed by an anisotropic deep etch that cuts through the conductive etch stops. 13. The method of claim 12 wherein: said anisotropic deep etch further cuts through a first material layer forming the respective output terminals of the vertically oriented, bit line selector devices; and said anisotropic deep etch further cuts into a second material layer, below the first material layer and forming respective channel regions of the vertically oriented, bit line selector devices. 14. The method of claim 13 wherein: said anisotropic deep etch does not cut through a third material layer, below the second material layer and forming respective input terminals of respective ones of the vertically oriented, bit line selector devices, whereby the respective input terminals of respective ones of the vertically oriented, bit line selector devices remain connected to one another. 15. The method of claim 14 wherein: the third material layer includes an N-type semiconductive material; the second material layer includes a P-type semiconductive material; and the first material layer includes an N-type semiconductive material. 16. The method of claim 14 wherein: said providing of the spaced apart global bit lines is followed by coupling of the third material layer of in line ones of the vertically oriented, bit line selector devices to a corresponding one of the global bit lines. 17. The method of claim 16 wherein: the global bit lines include a conductive metal and the third material layer includes an N+doped semiconductive material making ohmic contact with the conductive metal. 18. The method of claim 12 and further comprising: after said anisotropic deep etch, filling a deep trench formed by the anisotropic deep etch with a dielectric filler material. 19. A method of fabricating a non-volatile data storage device comprising: forming above a substrate, a first material layer for defining source regions of vertically oriented, bit line selector devices; forming above the first material layer, a plurality of spaced apart pillars each having alternating layers of conductive word lines and insulation, the pillars having respective vertically extending sidewalls; forming above the first material layer and under the pillars, spaced apart pairs of conductive selector lines that each function as a control terminal for a respective one of the bit line selecto