Truck tire with tread design for reducing abnormal wear

What is claimed is: 1. A heavy truck tire, comprising: a casing, wherein the casing has a central axis; a rubber tread that has a rib that has a first layer and a second layer, wherein the first layer is located farther from the central axis in a radial direction than the second laver, wherein the first layer has a lower max tan(δ) than a max tan(δ) of the second layer, wherein the max tan(δ) of the first layer is from 0.06-0.15, wherein the max tan(δ) of the second layer is from 0.12-0.271; wherein the tread extends in an axial direction between tread edges over a rolling tread width, and wherein the first layer and the second layer both extend across a majority of the rolling tread width, and wherein the first layer is intended to contact ground until worn off at such time the second tread layer is intended to contact the ground; wherein a plurality of longitudinal grooves are in the tread rubber and separate the first layer such that the first layer is not continuous from one of the tread edges to the other one of the tread edges in the axial direction; a third layer that is located closer to the central axis in the radial direction than the first layer and the second layer, wherein the third layer engages the second layer and bottoms of the longitudinal grooves; wherein an interface between the first layer and the second layer engages the longitudinal grooves and is spaced outward in the radial direction from the bottoms of the longitudinal grooves; a sculptural feature that reduces irregular wear, wherein the sculpture feature is selected from the group consisting of: a sacrificial rib; a micro sipe located at an edge of a rib of the tread that extends from an outer surface of the first layer in a direction towards the central axis in the radial direction; a directional micro sipe that extends from the outer surface of the first layer in a direction towards the central axis in the radial direction at a non-zero angle; and a directional sipe that extends from the outer surface of the first layer in a direction towards the central axis in the radial direction at a non-zero angle; wherein the third layer has a lower max tan(δ) than the max tan(δ) of the second layer, and wherein the max tan(δ) of the third layer is the same as or lower than the max tan(δ) of the first layer; wherein the rib comprises both end open sipes defining tread blocks and the third layer is an undertread layer of the tread, and wherein the first layer and the second layer are located in the tread blocks of the tread and the third layer is not located in the rib of the tread. 2. A heavy truck tire, comprising: a casing, wherein the casing has a central axis; a rubber tread that has a rib that has a first layer and a second layer, wherein the first layer is located farther from the central axis in a radial direction than the second layer, wherein the first layer has a lower max tan(δ) than a max tan(δ) of the second layer, wherein the max tan(δ) of the first layer is from 0.06-0.15, wherein the max tan(δ) of the second layer is from 0.12-0.27: wherein the tread extends in an axial direction between tread edges over a rolling tread width, and wherein the first layer and the second layer both extend across a majority of the rolling tread width, and wherein the first layer is intended to contact ground until worn off at such time the second tread layer is intended to contact the ground; wherein a plurality of longitudinal grooves are in the tread rubber and separate the first layer such that the first layer is not continuous from one of the tread edges to the other one of the tread edges in the axial direction; a third layer that is located closer to the central axis in the radial direction than the first layer and the second layer, wherein the third layer engages the second layer and bottoms of the longitudinal grooves; wherein an interface between the first layer and the second layer engages the longitudinal grooves and is spaced outward in the radial direction from the bottoms of the longitudinal grooves; a sculptural feature that reduces irregular wear, wherein the sculpture feature is selected from the group consisting of: a sacrificial rib; a micro sipe located at an edge of a rib of the tread that extends from an outer surface of the first layer in a direction towards the central axis in the radial direction; a directional micro sipe that extends from the outer surface of the first layer in a direction towards the central axis in the radial direction at a non-zero angle; and a directional sipe that extends from the outer surface of the first layer in a direction towards the central axis in the radial direction at a non-zero angle; wherein the max tan(δ) of the second layer is from 0.26-0.27. 3. A heavy truck tire, comprising: a casing, wherein the casing has a central axis; a rubber tread that has a rib that has a first layer and a second layer, wherein the first layer is located farther from the central axis in a radial direction than the second layer, wherein the first layer has a lower max tan(δ) than a max tan(δ) of the second layer, wherein the max tan(δ) of the first layer is from 0.06-0.15, wherein the max tan(δ) of the second layer is from 0.26-0.27; and a sculptural feature that reduces irregular wear; wherein the first layer has a complex shear modulus for 25% strain (G*25) at 60° C. that is from 1.2 MPa to 2.3 MPa, and wherein the second layer has a complex shear modulus for 25% strain (G*25) at 60° C. that is from 1.2 MPa to 2.3 MPa. 4. The tire as set forth in claim 3 , wherein the first layer has a complex shear modulus for 25% strain (G*25) at 60° C. that is from 1.5 MPa to 1.8 MPa, and wherein the second layer has a complex shear modulus for 25% strain (G*25) at 60° C. that is from 1.5 MPa to 1.8 MPa. 5. The tire as set forth in claim 3 , wherein the max tan(δ) of the first layer is from 0.06-0.09. 6. A heavy truck tire, comprising: a casing, wherein the casing has a central axis; a rubber tread that has a rib that has a first layer and a second layer, wherein the first layer is located farther from the central axis in a radial direction than the second layer, wherein the first layer has a lower max tan(δ) than a max tan(δ) of the second layer, wherein the max tan(δ) of the first layer is from 0.06-0.15, wherein the max tan(δ) of the second layer is from 0.26-0.27; and a sculptural feature that reduces irregular wear; wherein the complex shear modulus for 25% strain (G*25) at 60° C. of the first layer is less than the complex shear modulus for 25% strain (G*25) at 60° C. of the second layer; wherein the tread extends in an axial direction between tread edges over a rolling tread width, and wherein the first layer and the second layer both extend across a majority of the rolling tread width, and wherein the first layer is intended to contact ground until worn off at such time the second tread layer is intended to contact the ground; wherein a plurality of longitudinal grooves are in the tread rubber and separate the first layer such that the first layer is not continuous from one of the tread edges to the other one of the tread edges in the axial direction; a third layer that is located closer to the central axis in the radial direction than the first layer and the second layer, wherein the third layer engages the second layer and bottoms of the longitudinal grooves; wherein an interface between the first layer and the second layer engages the longitudinal grooves and is spaced outward in the radial direction from the bottoms of the longitudinal grooves. 7. The tire as set forth in claim 6 , wherein the max tan(δ) of the first layer is from 0.06-0.09.