Moisture resistant electrochromic device

What is claimed is: 1. An apparatus, comprising: a single substrate; and a plurality of layers, deposited on the single substrate, which comprises: an electrochromic (EC) thin film stack; at least one conductive layer that resists moisture permeation; and at least one encapsulation layer that resists moisture permeation; wherein the at least one encapsulation layer and the at least one conductive layer collectively restrict moisture permeation between the EC stack and an ambient environment; and wherein one or more outer portions of the EC stack are selectively removed to expose edge portions of the EC stack and to reduce the area of the EC thin film relative to at least one of the conductive layer and the encapsulation layer, such that one or more of the conductive layer and the encapsulation layer extend over the edge portions of the EC stack to restrict moisture permeation between the EC stack and the ambient environment. 2. The apparatus of claim 1 , wherein: the at least one encapsulation layer comprises a multi-layer structure of alternating high refractive-index material layers and low refractive-index material layers. 3. The apparatus of claim 1 , wherein: the at least one encapsulation layer comprises a multi-layer structure of alternating organic material layers and inorganic material layers. 4. The apparatus of claim 1 , wherein: the at least one encapsulation layer comprises a barrier layer stack formed on another substrate which is resistant to moisture permeation, wherein the other substrate is laminated on the plurality of layers. 5. The apparatus of claim 1 , wherein the encapsulation layer comprises one or more of: an anti-reflective (AR) layer; or an infrared cut-off filter layer. 6. The apparatus of claim 1 , comprising an obscuration layer, deposited on the single substrate and under the plurality of layers, wherein the obscuration layer is an annular structure structured to: obscure at least a portion of the plurality of layers from a surface of the single substrate opposite another surface on which the plurality of layers are deposited; and at least partially reflect laser processing wavelengths used to execute removal of a portion of the plurality of layers from the single substrate. 7. The apparatus of claim 1 , wherein the conductive layer comprises one or more edge portions which resist moisture permeation and an inner portion which may permit moisture permeation, wherein the one or more edge portions of the conductive layer and the at least one encapsulation layer portion restrict moisture permeation between the EC stack and inner portion of the conductive layer and the ambient environment. 8. The apparatus of claim 6 , comprising a buffer layer, deposited between the obscuration layer and the EC stack, wherein the buffer layer is structured to prevent damage to the obscuration layer during removal of one or more portions of the plurality of layers. 9. A method, comprising: providing, on a single substrate, a stack of layers comprising: an electrochromic (EC) thin film stack, a plurality of conductive layers above and below the EC stack, and at least one encapsulation layer; wherein at least one of the plurality of conductive layers and the at least one encapsulation layer collectively restrict moisture permeation between the EC stack and an ambient environment; and selectively removing one or more outer portions of at least the EC stack to expose edge portions of the EC stack, such that one or more of the at least one of the plurality of conductive layers or the at least one encapsulation layer extends over the edge portions of the EC stack to restrict moisture permeation between the EC stack and the ambient environment. 10. The method of claim 9 , wherein providing at least one encapsulation layer comprises one or more of: depositing an encapsulation layer on a conductive layer that is deposited on the EC stack; or depositing an encapsulation layer on the single substrate, such that the encapsulation layer is between the EC stack and the single substrate. 11. The method of claim 9 , wherein: the plurality of conductive layers above and below the EC stack comprise a top conductive layer above the EC stack and a bottom conductive layer below the EC stack; the at least one encapsulation layer comprises a bottom encapsulation layer below the bottom conductive layer; the EC stack comprises: a bottom EC stack layer which comprises one of an EC film or a counter-electrode film; a top EC stack layer which comprises another of the EC film or the counter-electrode film; and an ion conducting (IC) layer between the top EC stack layer and the bottom EC stack layer; and selectively removing one or more outer portions of at least the EC stack comprises: executing a first cut to remove an outer portion of the bottom conductive layer, bottom EC stack layer, and IC layer, and to expose an outer portion of the bottom encapsulation layer proximate to a first side of the substrate; executing a second cut to remove an outer portion of the top EC layer proximate to the first side, such that the top EC stack layer covers respective edge portions of the bottom conductive layer, bottom EC stack layer, and IC layer proximate to the first side; executing a third cut to remove an outer portion of the top conductive layer and the EC stack, and to expose a first outer portion of the bottom conductive layer, proximate to a second side of the substrate; and executing a fourth cut to remove another outer portion of the top conductive layer, and to at least partially expose the outer portion of the bottom encapsulation layer proximate to the first side of the substrate. 12. The method of claim 11 , wherein: providing the stack of layers further comprises depositing an obscuration layer on the substrate, wherein the obscuration layer is structured to: obscure at least a portion of the stack of layers from a surface of the single substrate opposite another surface on which the stack of layers are deposited; and at least partially reflect laser processing wavelengths used to execute one or more of the first cut, second cut, third cut, or fourth cut. 13. The method of claim 11 , wherein: coupling at least one set of bus bars to the plurality of conductive layers, wherein each set of bus bars comprises at least one bus bar coupled to the top conductive layer at a location proximate to one side of the substrate and at least one other bus bar coupled to at least the bottom conductive layer proximate to an opposite side of the substrate. 14. The method of claim 9 , wherein the encapsulation layer comprises one or more of: an anti-reflective (AR) layer; or an infrared cut-off filter layer. 15. The method of claim 9 , wherein: the plurality of conductive layers above and below the EC stack comprise a top conductive layer above the EC stack and a bottom conductive layer below the EC stack; the EC stack comprises: a bottom EC stack layer which comprises one of an EC film or a counter-electrode film; a top EC stack layer which comprises another of the EC film or the counter-electrode film; and an ion conducting (IC) layer between the top EC stack layer and the bottom EC stack layer; and providing the stack of layers comprises depositing one of the top conductive layer, top EC stack layer, IC layer, bottom EC stack layer, or bottom conductive layer in a particular pattern on the substrate, based at least in part upon one or more masking elements, such that one or more of the conductive layers and the encapsulation layer extend over the edge portions of the EC s