Diffuse discharge circuit breaker

What is claimed is: 1. An apparatus of a direct current (DC) circuit breaker operable to interrupt a current flow in an electrical circuit, the DC circuit breaker comprising: a mechanical switch including a pair of contacts configured to be positioned apart upon activation of the DC circuit breaker; and one or more photoconductive components, each having a volume that is capable of handling a peak current of over 5 kA, wherein the one or more photoconductive components are in parallel with the mechanical switch, wherein the one or more photoconductive components are configured to establish a current upon activation of the DC circuit breaker, and wherein each of the one or more photoconductive components comprises: a crystalline material positioned to receive a pulsed light signal having a pulse width of 10-20 μs from a light source, wherein the crystalline material is doped with a dopant that forms two or more mid-gap states within a bandgap of the crystalline material to achieve, upon excitation of the crystalline material by the pulsed light signal, a recombination time that is at least one order of magnitude smaller than a characteristic time of a highest frequency component of an electrical signal controlling the light source such that the crystalline material exhibits a substantially linear transconductance in response to the light source; and a pair of electrodes coupled to the crystalline material and configured to allow an electric field to be established across the crystalline material to generate the current, wherein a total volume of the one or more photoconductive components is around 9,000 cm 3 . 2. The apparatus of claim 1 , wherein each of the one or more photoconductive components further includes an optical fiber between the light source and the crystalline material. 3. The apparatus of claim 1 , wherein the DC circuit breaker includes a laser configured to produce the pulsed light signal that comprises a square pulse or a rectangular pulse. 4. The apparatus of claim 1 , wherein the mechanical switch is configured to diffuse discharge caused by a fault current. 5. The apparatus of claim 4 , wherein the mechanical switch comprises one of a rod array vacuum breaker, a non-rod array breaker, a series saturable reactor, or a combination thereof. 6. The apparatus of claim 1 , wherein the one or more photoconductive components are configured to establish the current in both directions parallel to the pair of contacts. 7. The apparatus of claim 1 , further comprising a resonant circuit configured to store energy to enable generation of the current upon the electric field being established across the crystalline material, wherein the resonant circuit includes at least an inductor and a capacitor. 8. The apparatus of claim 7 , wherein the one or more photoconductive components are configured to be stackable with at least one of the pair of contacts or the resonant circuit. 9. The apparatus of claim 1 , further comprising a convective cooling configuration coupled to the one or more photoconductive components and configured to dissipate heat generated from the one or more photoconductive components. 10. A method for operating a circuit breaker that is part of an electrical circuitry, comprising: opening a pair of contacts upon receiving an indication that the circuit breaker is to be activated; generating a pulsed light signal having a pulse width of 10-20 μs by a laser light source coupled to one or more photoconductive components, each having a volume that is capable of handling a peak current of over 5 kA, wherein the one or more photoconductive components are connected in parallel with the pair of contacts; and receiving, at a crystalline material of each of the one or more photoconductive components, the pulsed light signal from the laser light source, wherein the crystalline material is coupled to a pair of electrodes to allow an electric field to be established across the crystalline material upon receiving the pulsed light signal, and wherein the crystalline material is doped with a dopant that forms two or more mid-gap states within a bandgap of the crystalline material to achieve, upon excitation of the crystalline material by the pulsed light signal, a recombination time that is at least one order of magnitude smaller than a characteristic time of a highest frequency component of an electrical signal controlling the laser light source such that the crystalline material exhibits a substantially linear transconductance in response to the pulsed light signal, and wherein upon receiving the pulsed light signal by the crystalline material, at least part of a current that flows through the electrical circuitry to flow through the one or more photoconductive components. 11. The method of claim 10 , wherein the receiving of the pulsed light signal includes receiving the pulsed light signal via an optical fiber positioned coupled to the laser light source and to the crystalline material. 12. The method of claim 10 , wherein the pulsed light signal is a square pulse or a rectangular laser pulse. 13. The method of claim 10 , wherein the pair of contacts forms a mechanical switch, and wherein the mechanical switch comprises one of a rod array vacuum breaker, a non-rod array breaker a series saturable reactor, or a combination thereof. 14. The method of claim 10 , wherein the current that flows through the one or more photoconductive components flows in either direction parallel to the pair of contacts. 15. The method of claim 10 , further comprising: storing energy in a resonant circuit connected to the one or more photoconductive components, wherein the resonant circuit is configured to generate a reverse current in response to activation of the circuit breaker. 16. The method of claim 15 , wherein the one or more photoconductive components are configured as a stackable component with at least one of the pair of contacts or the resonant circuit. 17. The method of claim 10 , further comprising: dissipating heat generated by the one or more photoconductive components by a convective cooling configuration attached to the one or more photoconductive components.