Systems and methods for anti-microbial purification of air

What is claimed is: 1. An air supply system comprising: a conduit for channeling a flow of air therethrough, wherein the flow of air has microorganisms entrained therein; an anti-microbial filter in flow communication with the flow of air, wherein the anti-microbial filter comprises: a first air-impermeable substrate having a first filtration surface and a second air-impermeable substrate having a second filtration surface and spaced from each other between about 20 nanometers to about 400 nanometers, each of the first and second filtration surfaces having a plurality of atomically sharp surface features for non-selective lysing of at least some of the microorganisms that contact the anti- microbial filter, wherein the first and second filtration surfaces are oriented obliquely relative to an airflow direction of the flow of air; and a sensor operable to monitor a capacitance across the anti-microbial filter; a power source electrically connected to the anti-microbial filter; and a controller in communication with the power source, wherein the controller causes the power source to provide a surge charge to remove contamination from the anti-microbial filter when the capacitance measured by the sensor reaches a threshold value. 2. The air supply system in accordance with claim 1 further comprising a layer of coating material on each of the pluralities of atomically sharp surface features, wherein the coating material enhances at least one of the durability or the conductivity of the plurality of atomically sharp surface features. 3. The air supply system in accordance with claim 1 , wherein the controller causes the power source to at least one of: electrically bias the anti-microbial filter with a positive charge or a negative charge to attract the microorganisms to the anti-microbial filter; or provide an electrical discharge from the anti-microbial filter, wherein the electrical discharge lyses at least some of the microorganisms entrained in the flow of air. 4. The air supply system in accordance with claim 1 , wherein each of the pluralities of atomically sharp surface features comprises first atomically sharp surface features and second atomically sharp surface features that differ from each other by at least one physical characteristic. 5. The air supply system of claim 1 , wherein the system is adapted to: channel a flow of air, having microorganisms entrained therein, towards the anti-microbial filter, control a velocity of the flow of air, wherein the velocity is selected to facilitate non-selective lysing of at least some of the microorganisms that contact the anti-microbial filter; and discharge a flow of purified air from the anti-microbial filter. 6. The system in accordance with claim 5 wherein the system is adapted to provide a voltage to the anti-microbial filter. 7. The system in accordance with claim 6 wherein the system is adapted to remove particulates entrained in the flow of air upstream from the anti-microbial filter. 8. The system in accordance with claim 7 wherein the system is adapted to channel a flow of recirculated air, formed from the flow of purified air, towards the anti-microbial filter such that microorganisms within the flow of purified air discharged from anti-microbial filter are recirculated towards the anti-microbial filter. 9. The system in accordance with claim 8 , wherein the system is adapted to control a velocity of the flow of air by selectively accelerating the flow of air towards the anti-microbial filter at a velocity greater than a predetermined threshold. 10. An air supply system comprising: a conduit for channeling a flow of air therethrough, wherein the flow of air has microorganisms entrained therein; an anti-microbial filter in flow communication with the flow of air, wherein the anti-microbial filter comprises a first air-impermeable substrate having a first filtration surface and a second air-impermeable substrate having a second filtration surface and spaced from each other between about 20 nanometers to about 400 nanometers to define an airflow path therebetween, each of the first and second filtration surfaces comprising a plurality of atomically sharp surface features for non-selective lysing of at least some of the microorganisms that contact the anti-microbial filter; a power source electrically connected to the anti-microbial filter; and a controller in communication with the power source, wherein the controller causes the power source to provide a surge charge to remove contamination from the anti-microbial filter when a measured capacitance reaches a threshold value. 11. The air supply system in accordance with claim 10 , wherein each atomically sharp surface feature comprises at least one atomically sharp edge, the first and second filtration surfaces oriented such that the at least one atomically sharp edge is oriented obliquely or perpendicularly relative to an airflow direction of the flow of air. 12. An aircraft comprising: a confined space; the air supply system of claim 10 ; and a filter upstream from the anti-microbial filter, wherein the filter removes particulates entrained in the flow of air. 13. The aircraft in accordance with claim 12 further comprising: an auxiliary air mover that selectively accelerates the flow of air towards the anti-microbial filter at a velocity greater than a predetermined threshold; and an airflow sensor in communication with the auxiliary air mover, wherein the auxiliary air mover selectively accelerates the flow of air based on airflow velocity data received from the airflow sensor. 14. The aircraft in accordance with claim 12 further comprising a recirculation duct provides a flow of recirculated air from the confined space to the air supply system such that microorganisms within the flow of purified air discharged from anti-microbial filter are recirculated towards the anti-microbial filter. 15. The aircraft in accordance with claim 12 further comprising a layer of coating material on the each of the pluralities of atomically sharp surface features, wherein the coating material enhances at least one of the durability or the conductivity of the plurality of atomically sharp surface features. 16. The aircraft in accordance with claim 12 , wherein the controller causes the power source to at least one of: electrically bias the anti-microbial filter with a positive charge or a negative charge to attract the microorganisms to the anti-microbial filter; or provide an electrical discharge from the anti-microbial filter, wherein the electrical discharge is for lysing at least some of the microorganisms entrained in the flow of air. 17. An air supply system comprising: a conduit for channeling a flow of air therethrough, wherein the flow of air has microorganisms entrained therein; an anti-microbial filter in flow communication with the flow of air, wherein the anti-microbial filter comprises a first air-impermeable substrate having a first filtration surface and a second air-impermeable substrate having a second filtration surface and spaced from each other between about 20 nanometers and about 400 nanometers, each of the first and second filtration surfaces having a plurality of atomically sharp surface features for non-selective lysing of at least some of the microorganisms that contact the anti-microbial filter, wherein the filtration surface is oriented obliquely relative to an airflow direction of the flow of air; and a power source electrically connected to the anti-microbial filter, wherein the power source is operable to provide a surg