Printing with metal-surface charge element in glow discharge regime

We claim: 1. A printing system comprising: a metal-surface charge element that includes at least one metal charge roller to deposit electric charge on an imaging surface, each metal charge roller including a metal external surface in charge-transferring relation with the imaging surface and in a glow discharge regime during operation of the printing system for printing, wherein the glow discharge regime excludes filamentary streamer discharges; and a power supply connected to each metal charge roller to provide electric charge to each metal charge roller at a potential within the glow discharge regime, wherein the at least one metal charge roller comprises: at least two metal charge rollers to deposit a target electric charge on the imaging surface in steps such that, during operation of the printing system for printing, each metal charge roller of the at least two metal charge rollers deposits, via the power supply, a respective portion of the target electric charge on the imaging surface while remaining in the glow discharge regime, wherein a sum of the respective portions of electric charge equals the target electric charge, and wherein the sum of the respective portions of electric charge would result in filamentary streamer discharge behavior outside of the glow discharge regime if the sum of respective portions of electric charge was applied in a single step. 2. The printing system of claim 1 , comprising: a discharge source aimed at the imaging surface; at least one ink developer roller in ink-dispensing relation with the imaging surface; and a transfer unit in ink-transferring relation with the imaging surface, the transfer unit defining a paper movement path. 3. The printing system of claim 2 wherein the discharge source comprises one of a laser and an image-forming energy source. 4. The printing system of claim 1 wherein the at least one metal charge roller is spaced apart from the imaging surface. 5. The printing system of claim 1 wherein the printing system comprises a liquid electrophotographic printer. 6. The printing system of claim 1 , wherein at least some of the excluded filamentary streamer discharges have an amplitude of current that is at least one order of magnitude greater than an amplitude of current in the glow discharge regime. 7. The printing system of claim 1 , wherein the target electric charge corresponds to an imaging surface-to-ground potential. 8. The printing system of claim 7 , wherein the target electric charge is at least 500 Volts. 9. The printing system of claim 1 wherein the at least one metal charge roller comprises a solid metal cylinder. 10. The printing system of claim 1 wherein the at least one metal charge roller comprises a hollow metal cylinder. 11. The printing system of claim 1 , wherein an amplitude of current in the glow discharge regime is at least one order of magnitude less than an amplitude of current of at least some of the excluded filamentary streamer discharges. 12. The printing system of claim 1 , wherein an upper boundary of the glow discharge regime is at least partially defined by a first threshold associated with temporal fluctuation in current amplitude of the metal charge roller. 13. The printing system of claim 12 , wherein the upper boundary corresponds to a charge-roller potential at which measurements of the temporal fluctuation exceed the first threshold. 14. A printing system comprising: a metal-surface charge element including: at least two metal charge rollers with each metal charge roller including a metal external surface in charge-transferring relation with the imaging surface and in a glow discharge regime during operation of the printing system for printing, the at least two metal charge rollers to deposit electric charge on an imaging surface in steps such that each metal charge roller deposits a portion of a target electric charge on the imaging surface; and a power supply to provide a first portion of the target electric charge via a first one of the metal charge rollers via a first potential within the glow discharge regime between the first metal charge roller and the imaging surface and to provide subsequent portions of the target electric charge via each metal charge roller after the first portion at a subsequent potential within the glow discharge regime between that metal charge roller and the imaging surface after being charged by the previous metal charge roller, wherein a sum of the first portion and subsequent portions equals the target electric charge, and wherein a sum of the first potential and subsequent potentials would result in at least some filamentary streamer discharge behavior outside of the glow discharge regime if applied in a single step via a single metal charge roller. 15. The printing system of claim 14 , wherein the sum of the first potential and subsequent potentials is 1600 Volts. 16. A method of operating a printer with a metal-surface charge element, the method comprising: electrically charging an imaging surface of the printer by applying electric charge in a glow discharge regime to a metal-surface charge element that includes at least two metal charge rollers, each metal charge roller in rotational and charge-transferring relation with the imaging surface, wherein electrically charging the imaging surface comprises, in a first step, applying a first potential within the glow discharge regime between a first metal charge roller and the imaging surface and, after the first metal charge roller, in subsequent steps applying subsequent potentials within the glow discharge regime between each subsequent metal charge roller and the imaging surface after being charged by the previous metal charge roller, wherein a sum of the first potential and all subsequent potentials would be within a filamentary streamer discharge regime if applied in a single step via a single metal charge roller; forming a charge image on the electrically-charged imaging surface; applying ink to the imaging surface to image the ink according to the charge image; and transferring the imaged ink to paper. 17. The method of claim 16 wherein electrically charging the imaging surface comprises calibrating the printer prior to printing by: applying an electric potential to a first one of the metal charge rollers, observing the electric current drawn by the first metal charge roller, and if the current is steady incrementing the potential on the first metal charge roller and iterating, and if the current fluctuates, decrementing the potential on the first metal charge roller; if there is a next metal charge roller, applying an electric potential to that next metal charge roller, observing the electric current drawn by that next metal charge roller, and if the current is steady, then incrementing the potential on that next metal charge roller and iterating, and if the current fluctuates decrementing the potential on that next metal charge roller; and repeating until there are no more metal charge rollers. 18. The method of claim 17 and further comprising determining whether the imaging surface has charged to a predetermined print potential, and if not, inserting another metal charge roller, applying an electric potential to that metal charge roller, observing the electric current drawn by that metal charge roller, and if the current is steady incrementing the potential on that metal charge roller and iterating, and if the current fluctuates decrementing the potential on that metal charge roller. 19. The method of claim 18 wherein inserting anot