Micro pick and bond assembly

What is claimed is: 1. A micro-pick-and-bond (μPnB) assembly head, comprising: a substrate; and a plurality of pedestals over a surface of the substrate, wherein each pedestal comprises: a base comprising a dielectric material, wherein the base is mechanically coupled to the substrate; and a pressure sensitive adhesive (PSA) material exposed at a free end of the pedestal opposite the substrate, wherein the PSA is separated from the substrate by the base, and the PSA has a lateral dimension of micrometer scale and; a plurality of flexural members over the substrate, each pedestal coupled to the substrate through one or more of the flexural members. 2. The μPnB assembly head of claim 1 , wherein: a largest lateral dimension of the pedestal base is less than 10 μm; and a height of the pedestal from the flexural member is less than 10 μm. 3. The μPnB assembly head of claim 2 , wherein the dielectric material is between the PSA material and the flexural member. 4. The μPnB assembly head of claim 3 , wherein: the PSA material is a silicone-based PSA material; and the pedestal base comprises polyimide. 5. The μPnB assembly head of claim 2 , wherein at least one of: the PSA material has sloped sidewalls with the PSA having lateral dimensions proximal to a tip being smaller than those proximal to the substrate; or the base comprises a dielectric material disposed between the PSA material and the substrate and a portion of the dielectric base material is undercut with the area the dielectric base layer proximal to the substrate being less than the area of an exposed surface the adhesive material. 6. The μPnB assembly head of claim 1 , wherein the PSA material is stable to at least 160° C. 7. The μPnB assembly head of claim 6 , wherein the PSA material is stable to at least 250° C., and comprises a siloxane polymer. 8. The μPnB assembly head of claim 1 , wherein each flexural member is elastically deformable by at least 0.1 μm in a direction perpendicular to the substrate surface. 9. The μPnB assembly head of claim 8 , wherein: each flexural member has a spring constant of 100-600 N/m; and the PSA material has a peel strength of no more than 1.0 N/cm. 10. The μPnB assembly head of claim 9 , wherein: each flexural member extends over a recess in the substrate surface; the pedestal is coupled to a region of the flexural member between anchoring points that contact the substrate surface; and the flexural member comprises at least one metal thin film or semiconductor thin film anchored to the substrate by a dielectric thin film material. 11. The μPnB assembly head of claim 1 , wherein: the substrate comprises glass or crystalline silicon having a site flatness of less than 1 μm for an 8×25 mm site; and the flexural member comprises a crystalline silicon layer of the substrate or a metal thin film separated from the substrate by a stoichiometric SiO 2 layer. 12. The μPnB assembly head of claim 1 wherein the pedestal has a circular top surface with a diameter less than 5 μm. 13. A method of fabricating the micro-pick-and-bond (μPnB) assembly head of claim 1 , the method comprising: depositing a dielectric material layer over the substrate; depositing a pressure sensitive adhesive (PSA) material layer over the dielectric material layer; and patterning the PSA material layer and the dielectric material layer into the plurality of pedestals. 14. The method of claim 13 , further comprising: depositing a dielectric base layer over a low stress material layer disposed on the substrate; depositing the PSA material layer over the dielectric base layer; patterning the PSA material layer and the dielectric base layer into the plurality of pedestals patterning the low stress material layer into a plurality of flexural members, each flexural member structurally supporting at least one of the pedestals; and forming a recess in the substrate that undercuts the flexural member below the pedestal. 15. The method of claim 14 , wherein: depositing the dielectric base layer further comprises spin coating a mixture including a high temperature stable polymer over the low stress material and curing or drying the mixture into the dielectric base layer; depositing the PSA material layer further comprises spin coating a liquid mixture including a siloxane polymer and curing or drying the mixture into the PSA material layer; patterning the PSA material layer and the dielectric base layer into a plurality of pedestals further comprises: depositing and patterning a photoresist over the PSA material layer; and etching or dissolving portions of the PSA material layer and dielectric base layer unprotected by the patterned photoresist. 16. A micro-pick-and-bond (μPnB) assembly method, comprising: aligning a plurality of die anchored to a source substrate with the plurality of pedestals of claim 1 ; pressing each the plurality of die with a surface of at least one of the pedestals to adhere a die to a pedestal with the PSA material; breaking anchors between the die and the source substrate by displacing the pedestals relative to the source substrate while the die are adhered to the pedestals with the PSA material; aligning the plurality of die affixed to the pedestals with lands on a bonding target substrate; affixing the plurality of die to the lands on the bonding target substrate; and breaking the bond between the die and the pedestals while the die are affixed to the lands. 17. The method of claim 16 , wherein breaking the bond between the die and the pedestals further comprises at least one of displacing the pedestals relative to the target substrate, or thermally decomposing a thermally decomposable material interfacing the PSA material. 18. The method of claim 17 , wherein breaking the bond between the die and the pedestals further comprises displacing the pedestals in both lateral and vertical directions concurrently to peel the PSA material from an interface material of either the pedestal or the die. 19. The method of claim 16 , wherein affixing the plurality of die to the lands on the bonding target substrate further comprises solder bonding the die.