Architectures for high temperature TBCs with ultra low thermal conductivity and abradability and method of making

What is claimed is: 1. A thermal barrier coating system, comprising: a turbine component comprising: a turbine component substrate; and at least one thermal barrier coating layer applied over the turbine component substrate, wherein the at least one thermal barrier coating layer includes a material comprising at least one rare earth element or rare earth oxide comprising one or more of yttrium, lanthanum and ytterbium, the at least one thermal barrier coating selected from one or a combination of the following, present by weight percent: a layer having 3.9% La and 4.1% Y, the balance of the layer zirconia; a layer having 5.9% La and 2.7% Y, the balance of the layer zirconia; a layer having 7.8% La and 1.4% Y, the balance of the layer zirconia; and a layer having 30.5 wt % ytterbia, 24.8 wt % lanthana, 1.4 wt % hafnia, 1.5 wt % tantala, the balance of the layer zirconia and incidental impurities, the thermal barrier coating layer having dense vertical cracking with a grain size in the range of 0.5 to 5 m having a predetermined grain size distribution and a thermal conductivity lower than 2.2 W/mK by about 25-50% with a fracture toughness not less than about 1.2 MPam 1/2 . 2. The thermal barrier coating system of claim 1 , further comprising a bond coat layer applied to the turbine component substrate over which the at least one thermal barrier coating layer is applied. 3. The thermal barrier coating system of claim 2 , further comprising an outer layer having at least one of a higher abrasion resistance and a higher erosion resistance than the thermal barrier coating layer overlying the bond coat layer. 4. The thermal barrier coating system of claim 2 further comprising an inner layer adjacent the bond coat layer, the inner layer comprising yttria-stabilized zirconia. 5. The thermal barrier coating system of claim 1 , wherein the thermal barrier coating comprises a plurality of thermal barrier coating layers applied over one or more of an inner layer comprising yttria-stabilized zirconia and a bond coat layer, and wherein at least one of the plurality of layers has a thermal conductivity lower than the inner layer by 25-50%, and wherein at least one of the plurality of layers has at least one of a higher erosion resistance and a higher abrasion resistance than the inner layer. 6. The thermal barrier coating system of claim 5 , comprising an outer layer comprising La and Y the balance zirconia, selected from one of 3.9 wt % La and 4.1 wt % Y, 5.9 wt % La and 2.7 wt % Y, and 7.8 wt % La and 1.4 wt % Y. 7. The thermal barrier coating system of claim 6 , one or more of the plurality of thermal barrier coating layers and the outer layer comprising La-Yb-Zr oxides comprising from 30-40 wt % lanthana and 30-40 wt % ytterbia. 8. The thermal barrier coating system of claim 1 , the thermal barrier coating layer, further comprising one or more of an inner layer comprising yttria-stabilized zirconia and a bond coat layer. 9. The thermal barrier coating system of claim 1 , further comprising a plurality of abradable ridges on the thermal barrier coating layer. 10. The thermal barrier coating system of claim 1 , wherein the thermal barrier coating layer is chemically homogeneous. 11. A thermal barrier coating system, comprising: a turbine component comprising: a turbine component substrate; and a thermal barrier coating layer applied over the turbine component substrate, wherein the thermal barrier coating layer consists of at least one rare earth element or rare earth oxide comprising one or more of lanthanum and ytterbium, the thermal barrier coating layer selected from one or a combination of the following, present by weight percent: a layer having 3.9% La and 4.1% Y, the balance of the layer zirconia; a layer having 5.9% La and 2.7% Y, the balance of the layer zirconia; a layer having 7.8% La and 1.4% Y, the balance of the layer zirconia; and a layer having 30.5 wt % ytterbia, 24.8 wt % lanthana, 1.4 wt % hafnia, 1.5 wt % tantala, the balance of the layer zirconia and incidental impurities, the thermal barrier coating layer having a thermal conductivity lower than 2.2 W/mK by about 25-50% with a fracture toughness not less than about 1.2 MPam 1/2 . 12. A thermal barrier coating system, comprising: a turbine component comprising: a turbine component substrate; and at least one thermal barrier coating layer applied over the turbine component substrate, wherein the thermal barrier coating layer consists of a material comprising at least one rare earth element or rare earth oxide comprising one or more of yttrium, lanthanum and ytterbium, the at least thermal barrier coating layer selected from one or a combination of the following, present by weight percent: a layer having of 3.9% La and 4.1% Y, the balance of the layer zirconia; a layer having 5.9% La and 2.7% Y, the balance of the layer zirconia; a layer having 7.8% La and 1.4% Y, the balance of the layer zirconia; and a layer having 30.5 wt % ytterbia, 24.8 wt % lanthana, 1.4 wt % hafnia, 1.5 wt % tantala, the balance of the layer zirconia and incidental impurities, the thermal barrier coating layer having dense vertical cracking with a grain size in the range of 0.5 to 5 m having a predetermined grain size distribution and a thermal conductivity lower than 2.2 W/mK by about 25-50% with a fracture toughness not less than about 1.2 MPam 1/2 . 13. The thermal barrier coating system of claim 12 wherein the zirconia includes yttria-stabilized zirconia (YSZ).