Multilayer constrained-layer damping

We claim: 1. A multilayer damping laminate comprising: a first damping layer having a first glass transition temperature and a first damping layer thickness (H 1 ); a second damping layer having a second glass transition temperature and a second damping layer thickness (H 2 ); an internal constraining layer, at least a portion of which is disposed between the first damping layer and the second damping layer; and an external constraining layer, wherein at least a portion of the second damping layer is disposed between the internal constraining layer and the external constraining layer, wherein the damping layers of the laminate have a decreasing glass transition temperature profile beginning at the first damping layer, and wherein the multilayer damping laminate has a composite loss factor at 200 Hz that is greater than about 0.05; wherein the difference between the first glass transition temperature and the second glass transition temperature ranges from (−3(H 1 /H 2 ) 2 +15) ° C. to (15(H 1 /H 2 ) 2 +20) ° C. 2. The multilayer damping laminate of claim 1 , wherein the composite loss factor is greater than about 0.1. 3. The multilayer damping laminate of claim 1 , wherein the composite loss factor is greater than about 0.05 over a temperature range of at least 30° C. 4. The multilayer damping laminate of claim 1 , wherein the first glass transition temperature is at least 5° C. greater than the second glass transition temperature. 5. The multilayer damping laminate of claim 1 , wherein the difference between the first glass transition temperature and the second glass transition temperature ranges from about 5° C. to about 35° C. 6. The multilayer damping laminate of claim 1 , wherein the first glass transition temperature ranges from about −60° C. to about 100° C. 7. The multilayer damping laminate of claim 1 , wherein the second glass transition temperature ranges from about −60° C. to about 100° C. 8. The multilayer damping laminate of claim 1 , wherein the first damping layer has a first plateau modulus, wherein the second damping layer has a second plateau modulus, and wherein the damping layers of the laminate have an increasing plateau modulus profile beginning at the first damping layer. 9. The multilayer damping laminate of claim 8 , wherein the ratio of the second plateau modulus to the first plateau modulus ranges from 1 to (10(H 1 /H 2 ) 1.25 +10). 10. The multilayer damping laminate of claim 1 , wherein the first damping layer has a first viscoelastic loss factor greater than ((10 −10 /H 1 2.5 )+0.25), and wherein the second damping layer has a second viscoelastic loss factor greater than ((10 −10 /H 2 2.5 )+0.25), wherein H 1 and H 2 each have units of meters. 11. The multilayer damping laminate of claim 10 , wherein the difference between the first viscoelastic loss factor and the second viscoelastic loss factor ranges from 0.2 to 1.5 if the difference between the first glass transition temperature and the second glass transition temperature is less than about 20° C., and wherein the difference between the first viscoelastic loss factor and the second viscoelastic loss factor ranges from 0.2 to 3 if the difference between the first glass transition temperature and the second glass transition temperature is greater than about 20° C. 12. The multilayer damping laminate of claim 1 , wherein the first damping layer comprises a first viscoelastic damping material and the second damping layer comprises a second viscoelastic damping material. 13. The multilayer damping laminate of claim 12 , A wherein at least one of the first viscoelastic damping material and the second viscoelastic damping material comprises an adhesive. 14. The multilayer damping laminate of claim 13 , wherein the adhesive is a pressure sensitive adhesive. 15. The multilayer damping laminate of claim 1 , wherein the internal constraining layer and the external constraining layer each independently comprise a metal. 16. The multilayer damping laminate of claim 1 , wherein the internal constraining layer and the external constraining layer are each independently a metal foil. 17. The multilayer damping laminate of claim 1 , wherein the first damping layer thickness ranges from about 0.1 mil to about 200 mil. 18. The multilayer damping laminate of claim 1 , wherein the second damping thickness ranges from about 0.1 mil to about 200 mil. 19. The multilayer damping laminate of claim 1 , wherein the internal constraining layer and the external constraining layer each independently have a thickness ranging from about 0.2 mil to about 120 mil. 20. The multilayer damping laminate of claim 1 , wherein the internal constraining layer and the external constraining layer each independently have a thickness ranging from about 2 mil to about 50 mil. 21. The multilayer damping laminate of claim 1 , further comprising: a liner layer connected to the first damping layer opposite the second damping layer. 22. A multilayer damping laminate comprising: N damping layers, wherein N is an integer greater than or equal to 2, wherein at least a portion of each damping layer is coextensive with the other damping layers, and wherein each damping layer independently has a glass transition temperature (T g ) wherein T g (N)<T g (N−1)<T g (N−2)< . . . <T g (1); N−1 internal constraining layers, wherein at least a portion of each M th internal constraining layer is disposed between the M th damping layer and the (M+1) th damping layer, wherein M is an integer ranging from 1 to N−1; and an external constraining layer, wherein at least a portion of the N th damping layer is disposed between the (N−1) th constraining layer and the external constraining layer. 23. The multilayer damping laminate of claim 22 , wherein each damping layer independently has a plateau modulus (G o ), and wherein G o (N)>G o (N−1)>G o (N−2)> . . . >G o (1). 24. A system comprising: a base substrate; and the multilayer damping laminate of claim 1 , wherein the first damping layer is connected to the base substrate. 25. A method of reducing a vibration of a base substrate, the method comprising: providing a base substrate that is subject to a vibration; and connecting the first damping layer of the multilayer damping laminate of claim 1 to the base substrate, thereby reducing the vibration of the base structure. 26. The method of claim 25 , further comprising: shifting a location of maximum shear strain from the first damping layer to the second damping layer as the temperature of the multilayer damping laminate changes from the first glass transition temperature to the second glass transition temperature when measured at a frequency of interest. 27. The method of claim 26 , wherein the vibration of the base structure is dissipated over a sequential range of temperatures and frequencies.