Hydrocarbon trap with increased zeolite loading and improved adsorption capacity

What is claimed is: 1. A hydrocarbon trap for reducing cold-start vehicle exhaust emissions comprising: a monolithic flow-through substrate having a porosity of at least 60% and including a washcoating of zeolite at a loading of at least 5 g/in 3 zeolite in and/or on said substrate, wherein said washcoating of zeolite is impregnated into porous walls of said substrate and coated onto said porous walls of said substrate, wherein said hydrocarbon trap includes a catalyst comprising a mixture of nickel and copper in or on said substrate and further includes a three-way catalyst coated over said zeolite coated porous walls. 2. The hydrocarbon trap of claim 1 , wherein said substrate has a porosity of at least 65%, and wherein at least 2 g/in 3 of the washcoating of the zeolite penetrates into said porous walls of the substrate. 3. The hydrocarbon trap of claim 1 , wherein said substrate does not include cell plugs. 4. The hydrocarbon trap of claim 1 , wherein said substrate is selected from the group consisting of cordierite, silicon carbide, and mullite. 5. The hydrocarbon trap of claim 1 , wherein said zeolite has a Si/Al 2 ratio of from about 20 to about 500. 6. The hydrocarbon trap of claim 1 , wherein said zeolite is selected from zeolites having the structure BEA, FAU, MOR, MFI, FER, CHA, LTL, LTA, or mixtures thereof. 7. The hydrocarbon trap of claim 1 , further including an oxygen storage capacity material wherein said oxygen storage capacity material is ceria-praesodymium or mixtures thereof. 8. The hydrocarbon trap of claim 3 , including a loading of about 2 g/in 3 of said three-way catalyst, and wherein said substrate has a pore size of over 20 microns. 9. The hydrocarbon trap of claim 3 , wherein said three-way catalyst comprises a precious metal selected from the group consisting of platinum, palladium, rhodium, and mixtures thereof. 10. The hydrocarbon trap of claim 8 , wherein said substrate has a wall thickness of about 5 to 20 mils. 11. The hydrocarbon trap of claim 10 , wherein said substrate has a cell density of about 300 to 900 cells per square inch (cpsi). 12. The hydrocarbon trap of claim 11 , wherein said monolithic substrate has an open frontal area (OFA) of about 60 to 80%. 13. A method of forming a hydrocarbon trap for use in an exhaust treatment system of a vehicle, comprising: providing a monolithic wall-flow substrate having a porosity of at least 60%; providing a slurry of a hydrocarbon trapping material comprising zeolite; coating said slurry into and/or on said monolithic substrate such that a washcoated zeolite loading of the substrate is at least 5 g/in 3 , including applying two or more coats of said slurry into and/or on said monolithic substrate so that said zeolite coats porous walls of said monolithic substrate and at least 2 g/in 3 of the zeolite penetrates into said porous walls of the monolithic substrate such that a porous wall volume of said porous walls is at least partially filled with said zeolite; and coating a three-way catalyst over said zeolite coating. 14. The method of claim 13 , wherein said monolithic substrate includes a mixture of nickel and copper, the mixture of nickel and copper calcined at a temperature to react with the monolithic substrate, the mixture of nickel and copper impregnated into the monolithic substrate prior to said coating of said slurry. 15. The method of claim 13 , wherein said monolithic substrate has an open frontal area (OFA) of about 60 to 80%. 16. The method of claim 13 , wherein providing said slurry of said hydrocarbon trapping material comprising zeolite comprises providing a slurry comprising solids in water, the solids including about 80% by weight zeolite and 20% by weight binder. 17. The method of claim 14 , wherein the slurry includes an oxygen storage capacity material. 18. An exhaust treatment system comprising the hydrocarbon trap of claim 1 positioned in an exhaust passage of a vehicle. 19. A hydrocarbon trap for reducing cold-start vehicle exhaust emissions comprising: a monolithic flow-through substrate consisting of a) and b), where a) is cordierite, silicon carbide, or mullite; and b) is pores with a pore size of over 20 micron, the substrate having a porosity of at least 65%; a loading of at least 4 g/in 3 zeolite in and/or on the substrate, wherein the zeolite is impregnated into porous walls of the substrate and coated onto the porous walls of the substrate; and a three-way catalyst over the zeolite, the three-way catalyst loaded at a loading of about 2 g/in 3 , and an open front area of the substrate loaded with the zeolite is between about 40 and 60%.