Display stack with compressible capacitive sensors

What is claimed is: 1. A display stack comprising: a cover film comprising a top surface exposed to an ambient environment and an opposing bottom surface; a display; and a force sensitive capacitive sensor stack positioned in between the cover film and the display, the force sensitive capacitive sensor stack comprising: a first clear sensor layer optically coupled to the bottom surface of the cover film with an optically clear adhesive; a translucent and compressible light guide layer comprising a first side optically coupled to the first clear sensor layer with the optically clear adhesive, the translucent and compressible light guide layer comprising optically clear silicon, wherein the light guide layer has a hardness value such that the light guide layer plastically deforms in response to force; and a second clear sensor layer optically coupled to the display and to a second side of the translucent and compressible light guide layer with the optically clear adhesive, the second side opposite the first side; wherein the force sensitive capacitive sensor stack is configured to detect an amount of force received at the cover film, and to compress in response to the force. 2. The display stack of claim 1 , further comprising: a first illuminator positioned at a third side surface of the translucent and compressible light guide layer, the third side surface transverse to the first side and the second side, the first illuminator configured to direct light through the translucent and compressible light guide layer; and a second illuminator positioned at a fourth side surface of the translucent and compressible light guide layer opposite the third side surface, the second illuminator configured to direct light through the translucent and compressible light guide layer; wherein the second illuminator is positioned offset from the first illuminator such that the first illuminator and second illuminator are in a staggered formation. 3. The display stack of claim 1 , wherein the translucent and compressible light guide layer further comprises a material dispersed within the optically clear silicon, wherein the material reflects light propagating through the translucent and compressible light guide layer. 4. The display stack of claim 1 , wherein the first side of the translucent and compressible light guide layer comprises a textured surface portion that facilitates optical coupling between the force sensitive capacitive sensor stack and the cover film, the textured surface portion comprising a plurality of raised protrusions extending from the first side of the translucent and compressible light guide layer configured to increase a light propagation surface area between the cover film and the force sensitive capacitive sensor stack. 5. A device comprising: a cover layer; a display; and a capacitive sensor stack positioned in between the cover layer and the display, the capacitive sensor stack comprising: a first sensor optically coupled to the cover layer; a light guide optically coupled to the first sensor, wherein the light guide is compressible such that the light guide plastically deforms in response to force; and a second sensor optically coupled to the display and to the light guide; wherein the capacitive sensor stack is configured to detect a force received at the cover film and to compress in response to the force. 6. The device of claim 5 , wherein the light guide is translucent or transparent and comprises one or more of optically clear silicon, optically clear thermoplastic elastomers, optically clear elastomers, or optically clear thermoplastic polyurethane. 7. The device of claim 5 , wherein the capacitive sensor stack is a force sensitive capacitive sensor stack. 8. The device of claim 5 , wherein the light guide has a durometer hardness value of greater than or equal to 20 shore A hardness and less than or equal to 80 shore A hardness. 9. The device of claim 5 , further comprising: a first illuminator optically coupled to a first side of the light guide, wherein the first side is transverse to a second side of the light guide upon which the first sensor is optically coupled; a second illuminator optically coupled to a third side of the light guide opposite the first side; wherein the display is an electrophoretic display; and the light guide is configured to distribute at least a portion of light emitted from the first illuminator and the second illuminator to a front side of the electrophoretic display. 10. The device of claim 9 , wherein: the first illuminator is positioned at a first location along the first side of the light guide; and the second illuminator is positioned at a second location along the third side of the light guide, the second position offset from a third position on the third surface that is opposite the first position. 11. The device of claim 5 , further comprising a backlight coupled to the display, wherein the display is a liquid crystal display. 12. The device of claim 5 , wherein the light guide comprises optically clear silicon and another material within the optically clear silicon, wherein the material reflects light propagating through the light guide. 13. The device of claim 5 , further comprising a first textured surface portion at an interface between the first sensor and the light guide to facilitate optical coupling, the textured surface portion comprising a plurality of raised protrusions extending from the light guide. 14. The device of claim 13 , further comprising a second textured surface portion opposite the first textured surface portion at an interface between the second sensor and the light guide, the first textured surface portion and the second textured surface portion comprising one or more of a diffuser, groove, grating, dimple, lens, planar surface, concave surface, or convex surface. 15. The device of claim 5 , wherein the first sensor is printed directly on the light guide. 16. The device of claim 5 , wherein the capacitive sensor stack comprises a dielectric optically clear adhesive positioned in between the first sensor and the second sensor, and the first sensor and the second sensor comprise capacitive electrodes. 17. A method of forming a display stack for an electronic device comprising: providing a display; injection molding a light guide comprising optically clear silicon, wherein the light guide is compressible such that the light guide plastically deforms in response to force; forming a capacitive sensor stack by optically coupling a first sensor to a first surface of the light guide and optically coupling a second sensor to a second surface of the light guide opposite the first surface; optically coupling the capacitive sensor stack to a front surface of the display such that the second sensor is optically coupled to the display; and optically coupling a cover layer to the first sensor of the capacitive sensor stack; wherein the capacitive sensor stack is configured to detect a force applied at the cover film and to compress in response to the force. 18. The method of claim 17 , further comprising: printing the first sensor on the first surface of the light guide; and printing the second sensor on the second surface of the light guide opposite the first surface. 19. The method of claim 17 , further comprising forming a textured surface on at least a portion of the light guide, the textured surface comprising one or more of a diffuser, groove, grating, dimple, lens, planar surface, concave surface, or convex surface via