Stretch laminate with beamed elastics and formed nonwoven layer

What is claimed is: 1. A stretch laminate for a wearable article, comprising an outward-facing layer, a wearer-facing layer, and an elastic material sandwiched between the outward-facing layer and the wearer-facing layer, the elastic material having been pre-strained by a pre-strain percentage along a stretch direction during manufacture of the laminate, such that when the stretch laminate is in a relaxed condition the outward-facing layer and the wearer-facing layer are gathered along the stretch direction, wherein the outward-facing layer is formed of a section of nonwoven web material comprising an accumulation of filaments and has an inner surface and an outer surface, the outer surface comprising an ordered arrangement of zones each zone comprising an attenuated region adjacent to a build-up region, wherein the attenuated region has a first basis weight and the build-up region has a second basis weight, wherein the first basis weight is less than the second basis weight, the difference in basis weight corresponding to disposition of the filaments according to the ordered arrangement, wherein the outward-facing layer comprises a first area and a second area, the first area being occupied by the ordered arrangement of zones and the second area being distinguishable from the first area by an absence of an attenuated region over a continuous surface area of the outward-facing layer in its ungathered condition, the continuous surface area being equal to or greater than approximately 4 cm 2 and having no dimension in the x-y plane smaller than approximately 1 cm, the second area being delineated from the first area by a perimeter demarking a discontinuity or interruption in the arrangement of zones; and wherein the outward-facing layer is bonded about the elastic material to the wearer-facing layer in the second area by adhesive positioned on the outward-facing layer and the wearer-facing layer. 2. The stretch laminate of claim 1 , wherein the nonwoven web material has been formed via continuous deposition of spun filaments onto a continuous forming belt having an outer receiving side and an inner side and moving along a machine direction through a working location, to form a batt of filaments deposited on the receiving side of the forming belt, the forming belt comprising an airflow permeable substrate belt and an ordered arrangement of airflow blocking structures disposed on the substrate belt, thereby imparting to the forming belt an ordered arrangement of airflow-permeable regions and airflow-blocked regions coextensive with the airflow blocking structures, the airflow blocking structures extending in a z-direction outward from the substrate belt so has to have a z-direction depth on the receiving side of the forming belt; wherein before and as they contact the forming belt the filaments are entrained in air flow directed at and through the belt generally along a z-direction, such that the filaments accumulate on the forming belt to a greater weight over the airflow-permeable regions and to a lesser weight over the airflow-blocked regions, to create build-up regions of the batt over the airflow-permeable portions and attenuated regions of the batt over the airflow-blocked regions; wherein the batt is consolidated into a nonwoven web material following its formation on the forming belt; whereby the attenuated regions form one or more z-direction depressions predominately in the outer surface of the section of nonwoven web material. 3. The stretch laminate of claim 1 wherein the attenuated region(s) and the build-up region(s) comprised by the zone(s), and the zone(s) itself (themselves), are visually discernible. 4. The stretch laminate of claim 1 wherein the elastic material comprises a plurality of elastic strands spaced apart from each other in a cross-stretch direction. 5. The stretch laminate of claim 4 wherein the elastic strands have an Average-Strand-Spacing no greater than 3.0 mm. 6. The stretch laminate of claim 5 wherein the elastic strands have an Average Decitex no greater than 300. 7. The stretch laminate of claim 5 wherein the pre-strain percentage is an Average-Pre-Strain and the Average-Pre-Strain is no greater than 250 percent. 8. The stretch laminate of claim 4 wherein the elastic strands have a Manufacturing-Strand-Spacing no greater than 3.0 mm. 9. The stretch laminate of claim 4 wherein the pre-strain percentage is a Manufacturing Pre-Strain, and the elastic strands have been joined with the outward-facing layer under a Manufacturing Pre-Strain no greater than 250 percent. 10. The stretch laminate of claim 1 wherein the outward-facing layer is formed at least in part of filaments spun from resin comprising polypropylene and a melt additive. 11. The stretch laminate of claim 10 wherein the melt additive is selected from the group consisting of erucamide, stearamide, oleamide, silicones and combinations thereof. 12. The stretch laminate of claim 1 wherein the outward-facing layer is formed at least in part of bicomponent filaments. 13. The stretch laminate of claim 12 wherein the bicomponent filaments have a core-sheath configuration. 14. The stretch laminate of claim 12 wherein the bicomponent filaments have a side-by-side configuration. 15. The stretch laminate of claim 12 wherein the bicomponent filaments have a first component comprising polypropylene and a second component comprising polyethylene. 16. The stretch laminate of claim 1 wherein the outer surface of the outward-facing layer exhibits an outer percent contact area of from about 20 percent to about 40 percent, in accordance with the Percent Surface Contact Area Method described herein, and the wearer-facing layer has a wearer-facing surface that exhibits an inner percent contact area that is at least 1.25 times the outer percent contact area.