Pressure compensated external gear machine

The invention claimed is: 1. A gear for use in an external gear machine, the gear comprising a plurality of gear teeth, each gear tooth comprising a lateral surface defining a first peripheral tooth profile between a first edge, a second edge, and a distal end of the gear tooth, the lateral surface comprising: a root surface in a first lateral plane, a step surface extending between the root surface, the distal end, and the first edge, and a shaped surface extending between the root surface, the distal end and the second edge, wherein at least a portion of the shaped surface extends away from the first lateral plane to form a first depth of between 0.1 microns and 500 microns between the first lateral plane and the portion of the shaped surface such that the first peripheral tooth profile along the second edge is below the first lateral plane of the gear tooth, wherein the first edge and the second edge do not have the same configuration. 2. The gear of claim 1 , wherein at least one gear tooth includes the shaped surface on each of its lateral surfaces. 3. The gear of claim 1 , wherein each step surface comprises a flat surface in the first lateral plane and extends a first length from the first edge of the gear tooth to a lateral profile line of the lateral surface. 4. The gear of claim 3 , wherein the shaped surface of each gear tooth extends from the lateral profile line to the second edge of the gear tooth and the step surface and the shaped surface form a pattern that repeats sequentially along the gear tooth. 5. The gear of claim 4 , wherein the shaped surface of each gear tooth extends away from the lateral profile line at a 90° angle. 6. The gear of claim 4 , wherein the first length comprises 50% or more of a width of the gear tooth. 7. The gear of claim 1 , wherein the shaped surface extends away from the first lateral plane surface at a lateral shaping angle to form a wedge and the first depth comprises a maximum wedge depth at or near a trailing the second edge of the gear tooth. 8. The gear of claim 7 , wherein the maximum wedge depth is within a range of 1-10 microns. 9. The gear of claim 7 , wherein the first depth decreases along the lateral shaping angle of each gear tooth. 10. The gear of claim 1 , wherein one or more dimensions of the shaped surface are calculated by dividing 360 by a total number of gear teeth of the gear. 11. An external gear machine comprising: a first gear comprising a plurality of gear teeth, each gear tooth of the plurality of gear teeth comprising: a lateral surface: having at least a portion thereof in a first lateral plane, defining a first peripheral tooth profile between a leading edge, a trailing edge, and a distal end of the gear tooth, comprising a root surface in the first lateral plane, a step surface extending between the root surface, the distal end, and the leading edge, and a shaped surface extending between the root surface, the distal end and the trailing edge, and comprising the shaped surface extending away from the first lateral plane to form a depth in at least a portion of the lateral surface of the gear tooth such that the first peripheral tooth profile along the trailing edge is below the first lateral plane; wherein the leading edge and the trailing edge do not have the same configuration and, in use, the leading edge is positioned in front of the trailing edge relative to a direction of rotation of the first gear; and a first lateral bushing comprising: at least one inner aperture formed therethrough, a bushing base surface surrounding the at least one inner aperture and extending radially to a shape distance from a center of the at least one inner aperture, wherein both the first gear and the first lateral bushing are positioned within a housing such that a lubricating gap is formed between the first gear and the first lateral bushing. 12. The external gear machine of claim 11 , wherein the first lateral bushing further comprises a bushing shaped surface surrounding the bushing base surface and extending to a perimeter of the first lateral bushing, wherein the bushing shaped surface includes at least one bushing feature having an axial feature depth and a feature angle that form a pattern that periodically repeats circumferentially around the at least one inner aperture at the shape distance. 13. The external gear machine of claim 11 , further comprising a second lateral bushing comprising: at least one inner aperture formed therethrough; a bushing base surface surrounding the at least one inner aperture and extending radially to a shape distance from a center of the at least one inner aperture; and a bushing shaped surface surrounding the bushing base surface and extending to a perimeter of the second lateral bushing; wherein the bushing shaped surface includes at least one bushing feature having an axial feature depth and a feature angle and the second lateral bushing is positioned within the housing such that a second lubricating gap is formed between the first gear and the second lateral bushing. 14. The external gear machine of claim 13 , wherein the at least one feature angle comprises at or near a 90° angle, and the axial feature depth and the at least one feature angle form a pattern that periodically repeats circumferentially around the at least one inner aperture at the shape distance to form a tooth-like configuration. 15. The external gear machine of claim 13 , wherein the at least one bushing feature of the second lateral bushing comprises a floor positioned at the axial feature depth. 16. The external gear machine of claim 11 , wherein no portion of the shaped surfaces of the plurality of gear teeth of the first gear are in the first lateral plane of the first gear. 17. The external gear machine of claim 11 , wherein the shaped surface of each gear tooth extends away from the lateral surface at a lateral shaping angle to form a wedge and the depth of each gear tooth comprises a maximum depth at or near the trailing edge of each gear tooth. 18. The external gear machine of claim 17 , wherein the depth of each gear tooth decreases along the lateral shaping angle of each gear tooth to the maximum depth. 19. The external gear machine of claim 18 , further comprising a second gear comprising a plurality of gear teeth, each gear tooth of the plurality of gear teeth comprising a lateral surface having at least a portion thereof in a first lateral plane, the lateral surface defining a first peripheral tooth profile extending between the leading edge and the trailing edge of the gear tooth and comprising a shaped surface extending away from the first lateral plane to form a depth below the first lateral plane on the trailing edge of the gear tooth, wherein the depth of each gear tooth of the second gear decreases along a lateral shaping angle of each gear tooth of the second gear; wherein the first and second gears are positioned relative to each other such that a direction such that the leading edge of each gear tooth is positioned, relative to the trailing edge, toward a direction of intended rotation of the first and second gears within the housing. 20. The external gear machine of claim 11 , further comprising a working fluid having a viscosity of at or greater than 0.5 cSt or at or greater than 1000 cSt. 21. A method for manufacturing an external gear machine comprising the steps of: forming a first gear and a second gear, each for placement within a housing, the first gear coupled with a shaft confi