Tire with rubber tread of intermedial and lateral zones with path of least electrical resistance

What is claimed is: 1. A tire is provided having a circumferential rubber tread composed of a cap/base configuration comprised of an outer tread cap rubber layer with a lug and groove configuration with the outer portions of the tread lugs providing the running surface of the tread, and a tread base rubber layer underlying the outer tread cap rubber layer; wherein the outer tread cap rubber layer is composed of three circumferential load bearing zones comprised of a silica-rich intermedial tread zone rubber layer positioned between and extending beneath two carbon black-rich lateral tread zone rubber layers to thereby underlie the lateral tread zone rubber layers and overlay the carbon black-rich tread base rubber layer; wherein outer tread lug surfaces of the intermedial tread zone rubber layer and the lateral tread zone rubber layers comprise the running surface of the tread; wherein rubber composition of the intermedial tread zone rubber layer has a 100° C. hot rebound property greater than the 100° C. hot rebound property of the rubber composition of said lateral tread zone rubber layers, wherein a path of least electrical resistance extends from said carbon black-rich lateral rubber tread zone to the carbon black-rich tread base rubber layer by an extension of a lateral tread zone layer which extends to and joins said tread base rubber layer or by an intermediate carbon black-rich rubber bridge which extends between and joins said lateral tread zone rubber layer and said tread base rubber layer, wherein the silica-rich rubber composition of the intermedial tread zone rubber layer contains at least 40 phr of precipitated silica and a maximum of 30 phr of rubber reinforcing carbon black and is therefore relatively electrical resistive, wherein the rubber reinforcing carbon black-rich rubber compositions of the lateral tread zone rubber layer, tread base rubber layer and rubber bridge contains at least 40 phr of rubber reinforcing carbon black. 2. The tire of claim 1 wherein the value of the 100° C. hot rebound property of the intermedial tread zone rubber composition is at least about 4 units greater than the 100° C. hot rebound property value of the lateral tread zone rubber composition. 3. The tire of claim 1 wherein the 100° C. hot rebound value of the intermedial tread zone rubber composition is in arrange of from about 60 to about 80 percent and the 100° C. hot rebound value of the rubber composition of the lateral tread zone rubber composition is in a range of from about 56 to about 76 so long as the 100° C. rebound values differ by at least about 4 units. 4. The tire of claim 1 wherein the lateral tread zone rubber composition has an at least 20 percent greater tear resistance property than the intermedial tread zone rubber and where the intermedial and lateral tread zones are configured with lugs and intervening grooves with each lateral tread zone containing at least one tread groove. 5. The tire of claim 1 wherein the elastomers of the rubber compositions of the intermedial tread rubber zone and lateral tread rubber zones are the same or different so long as the 100° C. hot rebound property of the rubber composition of the intermedial tread rubber zone is greater than the 100° C. hot rebound property of the rubber composition of the lateral rubber zones. 6. The tire of claim 1 wherein the span of the running surface of the intermedial tread zone rubber layer axially spans from about 30 to about 80 percent of the running surface of the tread cap rubber layer and the two lateral tread rubber zone rubber layers collectively span from about 20 to about 70 percent of the running surface of the tread cap rubber layer where said span of running surface of the tread includes the running surfaces of the tread lugs and widths of the tread grooves between the tread lugs. 7. The tire of claim 6 wherein the span of running surfaces of the two individual lateral tread zones are of substantially equal widths. 8. The tire of claim 6 wherein the span of running of the two individual lateral tread zones is asymmetrical in a sense that they are of unequal widths. 9. The tire of claim 1 wherein the Grosch high severity abrasion rate of the rubber compositions of the running surfaces of the intermedial tread zone running surface and lateral tread zone are desirably similar. 10. The tire of claim 1 wherein the lateral tread zones, intermedial tread zone and underlying tread base are co-extruded together to form an integral and unified tread composite. 11. The tire of claim 1 wherein the rubber of the intermedial, tread cap zone has a lower tan delta value at 10 percent strain (100° C.) than the rubber of the two lateral tread cap zones. 12. The tire of claim 1 wherein the tear resistance (Newtons at 95° C.) of the rubber composition of the lateral tread zone rubber is at least 20 percent greater than the tear resistance of the rubber composition of the intermedial tread zone. 13. The tire of claim 1 wherein the intermedial and lateral tread zones are configured with lugs and intervening grooves with the lateral tread zones each containing at least one tread groove.