Wellbore zonal isolation

What is claimed is: 1. A sealing assembly for a zone of a wellbore, comprising: a setting tool for rigless deployment of the sealing assembly into the wellbore, the setting tool comprising extendable arms; ratchet rings disposed on the extendable arms, the ratchet rings expandable to a diameter of the wellbore; an expandable metal structure disposed around the ratchet rings; and polymer disposed on the expandable metal structure to plug permeability of the wellbore zone, the expandable metal structure to receive electricity from an electricity source to heat the expandable metal structure to melt the polymer to plug the permeability. 2. The sealing assembly of claim 1 , wherein the polymer comprises a thermoplastic resin or an ethylene-vinyl acetate (EVA) polymer, or a mixture thereof. 3. The sealing assembly of claim 1 , wherein the expandable metal structure comprises a metal stent. 4. The sealing assembly of claim 1 , wherein the ratchet rings comprise teeth to remain in an expanded state. 5. The sealing assembly of claim 1 , wherein the expandable metal structure comprises linkages for the expandable metal structure to expand and remain in an expanded state. 6. The sealing assembly of claim 1 , comprising a hydraulic cylinder to hydraulically extend the extendable arms. 7. The sealing assembly of claim 6 , wherein the setting tool comprises the hydraulic cylinder. 8. The sealing assembly of claim 1 , comprising a wireline or coiled tubing coupled to the setting tool for the rigless deployment. 9. A sealing assembly for a zone of a wellbore of claim 2 , comprising: a setting tool for rigless deployment of the sealing assembly into the wellbore, the setting tool comprising extendable arms; ratchet rings disposed on the extendable arms, the ratchet rings expandable to a diameter of the wellbore; an expandable metal structure disposed around the ratchet rings; polymer disposed on the expandable metal structure to plug permeability of the wellbore zone; and a microwave radiation source to heat the expandable metal structure to melt the polymer to plug the permeability, wherein the expandable metal structure comprises ceramic particles. 10. An oil-well intervention system for a wellbore zone, comprising: a sealing assembly to seal the wellbore zone, comprising: a setting tool for rigless deployment of the sealing assembly into the wellbore, the setting tool comprising hydraulic extendable arms; ratchet rings disposed on the hydraulic arms, the ratchet rings expandable to a diameter of the wellbore zone and to lock in place in an expanded state; an expandable metal structure disposed on the ratchet rings; and polymer disposed around an outer surface of the expandable metal structure, the expandable metal structure to receive electrical current through a deployment extension from an electrical source to heat the expandable metal structure to melt the flexible polymer to seal permeability in the wellbore zone. 11. The oil-well intervention system of claim 10 , comprising a dispenser to provide the deployment extension to couple to the setting tool to facilitate lowering of the sealing assembly into the wellbore zone for the rigless deployment of the sealing assembly. 12. The oil-well intervention system of claim 11 , wherein the deployment extension comprises coiled tubing, and wherein the dispenser comprises a coil tubing reel. 13. The oil-well intervention system of claim 11 , wherein the deployment extension comprises a wireline, and wherein the dispenser comprises a wireline dispenser. 14. The oil-well intervention system of claim 10 , wherein the expandable metal structure comprises a stent or mesh, and wherein the wellbore zone comprises a water zone. 15. A method of sealing permeability of a wellbore water zone, comprising: deploying a sealing assembly into the wellbore water zone, wherein the sealing assembly comprises an expandable metal structure and polymer disposed on the expandable metal structure; expanding, via a hydraulic cylinder, the expandable metal structure and polymer against a wall of the wellbore water zone; and heating the expandable metal structure as expanded to melt the polymer against the wall of the wellbore water zone, wherein heating comprises applying electricity to the sealing assembly to heat the expandable metal structure. 16. The method of claim 15 , comprising allowing the polymer as melted to flow into a formation defining the wellbore water zone and to harden to seal the permeability. 17. The method of claim 16 , wherein the sealing assembly comprises a setting tool and ratchet rings disposed on arms of the setting tool, wherein the expandable metal structure is disposed on the ratchet rings, and wherein expanding comprises extending the arms to expand the ratchet rings to expand the expandable metal structure and polymer against the formation. 18. The method of claim 17 , comprising: releasing the ratchet rings from the setting tool arms; retrieving, via coiled tubing, a wireline, or a slickline, the setting tool from the wellbore water zone after the polymer hardens; and leaving the expandable metal structure and the ratchet rings in place after the polymer hardens. 19. The method of claim 17 , comprising maintaining the ratchet rings expanded via teeth of the ratchet rings. 20. The method of claim 15 , wherein deploying comprising lowering, via coiled tubing or a wireline, the sealing assembly in the wellbore water zone in a rigless operation. 21. The method of claim 15 , wherein the expandable metal structure comprises a stent or mesh. 22. A method of sealing permeability of a wellbore water zone, comprising: deploying a sealing assembly into the wellbore water zone, wherein the sealing assembly comprises an expandable metal structure and polymer disposed on the expandable metal structure; expanding, via a hydraulic cylinder, the expandable metal structure and polymer against a wall of the wellbore water zone; and heating the expandable metal structure as expanded to melt the polymer against the wall of the wellbore water zone, wherein heating comprises applying electromagnetic radiation to heat the expandable metal structure, and wherein the expandable metal structure comprises ceramic particles.