Direct metal electrophotography additive manufacturing methods

What is claimed is: 1. A method for printing a three-dimensional part using a photoreceptor drum that sequentially prints in alternating clockwise and counterclockwise rotational directions, the method comprising: applying a first metal print layer, wherein applying the first metal print layer comprises: charging at least a first portion of an outer surface of a rotating photoreceptor drum with an electrostatic charge; neutralizing the electrostatic charge on the at least a first portion of the outer surface of the rotating photoreceptor drum to form a first layer definition corresponding to the neutralized at least a first portion; transferring a first plurality of charged metal powder particles from a first powder roller onto the outer surface of the rotating photoreceptor drum corresponding to the neutralized at least a first portion; transferring the first plurality of charged metal powder particles from the outer surface of the rotating photoreceptor drum onto a workpart to form a first metal print layer, the rotating photoreceptor drum rotating clockwise and the workpart having been preheated by a first microwave emitter and/or a first induction coil, the first microwave emitter and/or the first induction coil located upstream from the photoreceptor drum relative to the workpart when the photoreceptor drum rotates clockwise; and fusing the first metal print layer to the workpart using a second microwave emitter, the second microwave emitter located downstream from the photoreceptor drum relative to the workpart when the photoreceptor drum rotates clockwise; applying a second metal print layer, wherein applying the second metal print layer comprises: charging at least a second portion of the outer surface of the rotating photoreceptor drum with an electrostatic charge; neutralizing the electrostatic charge on the at least a second portion of the outer surface of the rotating photoreceptor drum to form a second layer definition corresponding to the neutralized at least a second portion; transferring a second plurality of charged metal powder particles from a second powder roller onto the outer surface of the rotating photoreceptor drum corresponding to the neutralized at least a second portion; transferring the second plurality of charged metal powder particles from the outer surface of the rotating photoreceptor drum onto the workpart to form a second metal print layer, the rotating photoreceptor drum rotating counter-clockwise and the workpart having been preheated by the second microwave emitter and/or a second induction coil, the second microwave emitter and/or the second induction coil located upstream from the photoreceptor drum relative to the workpart when the photoreceptor drum rotates counter-clockwise; and fusing the second metal print layer to the workpart using the first microwave emitter, the first microwave emitter located downstream from the photoreceptor drum relative to the workpart when the photoreceptor drum rotates counter-clockwise. 2. The method as in claim 1 , wherein: applying the first metal print layer further comprises: prior to transferring the first plurality of charged metal powder particles from the outer surface of the rotating photoreceptor drum onto the workpart, preheating the workpart using the first induction coil; and/or applying the second metal print layer further comprises: prior to transferring the second plurality of charged metal powder particles from the outer surface of the rotating photoreceptor drum onto the workpart, preheating the workpart using the second induction coil. 3. The method as in claim 2 , wherein the workpart is preheated through thermal radiation. 4. The method as in claim 1 , wherein the electrostatic charge is neutralized by exposing the rotating photoreceptor drum outer surface to a layer definition using at least one laser beam, said layer definition provided by a controller circuit. 5. The method as in claim 1 , wherein: applying the first metal print layer further comprises: after delivering the first plurality of charged metal powder particles to the outer surface of the photoreceptor drum, cleaning any excess powder from the outer surface of the photoreceptor drum using a first at least one electrically neutral adjustable powder skimmer blade; and/or applying the second metal print layer further comprises: after delivering the second plurality of charged metal powder particles to the outer surface of the photoreceptor drum, cleaning any excess powder from the outer surface of the photoreceptor drum using a second at least one electrically neutral adjustable powder skimmer blade. 6. The method as in claim 5 , wherein: applying the first metal print layer further comprises: depositing said excess powder with respect to cleaning after delivering the first plurality of charged metal powder particles back into the first powder roller; and/or applying the second metal print layer further comprises: depositing said excess powder with respect to cleaning after delivering the second plurality of charged metal powder particles back into the second powder roller. 7. The method as in claim 5 , wherein: applying the first metal print layer further comprises: discharging any remaining charge from the photoreceptor drum outer surface using a first at least one discharge lamp, the discharging performed after delivering the first plurality of charged metal powder particles to the outer surface of the photoreceptor drum; and/or applying the second metal print layer further comprises: discharging any remaining charge from the photoreceptor drum outer surface using a second at least one discharge lamp, the discharging performed after delivering the second plurality of charged metal powder particles to the outer surface of the photoreceptor drum. 8. A method for printing a three-dimensional part, the method comprising: positioning a metal workpart on a stationary platform; applying a first metal print layer, comprising: electrically charging the platform; preheating the metal workpart using a first induction coil; rolling a rotating photoreceptor drum clockwise across the preheated metal workpart to transfer a first plurality of charged metal powder particles from an outer surface of the rotating photoreceptor drum onto an outer surface of the workpart to form a first metal print layer; and fusing the first metal print layer to the workpart using a second microwave emitter; applying a first metal print layer, comprising: preheating the metal workpart using a second induction coil; rolling the rotating photoreceptor drum counter-clockwise across the preheated metal workpart to transfer a second plurality of charged metal powder particles from an outer surface of the rotating photoreceptor drum onto an outer surface of the workpart to form a second metal print layer; and fusing the second metal print layer to the workpart using a first microwave emitter. 9. The method as in claim 8 , wherein the metal print layer is fused to the workpart using electromagnetic radiation having frequencies of about 100 MHz to about 300 GHz. 10. The method as in claim 8 , wherein the workpart is preheated using thermal radiation. 11. The method as in claim 8 , wherein applying the first metal print layer and/or applying the second metal print layer further comprises: charging the outer surface of the rotating photoreceptor drum with an electrostatic charge; neutralizing the electrostatic charge on a portion of the outer surface of the rotating photoreceptor drum surface to form a layer definition corresponding to the neutralized portion; and developing the layer definition with charged metal powder p