Yes indeed. In the latest patent, there is significantly more in the Claim department of the patent. They have been testing, "the developed titanium", with a very detailed analyses of it here in the new patent...
"2. The nanostructured titanium alloy article according to claim 1, wherein the developed titanium structure is a developed a-titanium structure.
3. The nanostructured titanium alloy article according to claim 1, wherein the grains are a phase grains.
4. The nanostructured titanium alloy article according to claim 1, wherein the developed titanium structure has a dislocation density ≥10{circumflex over ( )}15 m{circumflex over ( )}-2.
5. The nanostructured titanium alloy article according to claim 1, wherein ≥80% of the grains have a grain shape aspect ratio that is in a range of 0.3 to 0.7.
6. The nanostructured titanium alloy article according to claim 1, wherein the developed titanium structure has an ultimate tensile strength that is ≥1400 MPa.
7. The nanostructured titanium alloy article according to claim 1, wherein the developed titanium structure includes a-titanium matrix having retained ß-titanium particles.
8. The nanostructured titanium alloy article according to claim 1, wherein the developed titanium structure has an ultimate tensile strength that is ≥1200 MPa.
9. The nanostructured titanium alloy article according to claim 8, wherein the developed titanium structure has a total tensile elongation ≥10%.
10. The nanostructured titanium alloy article according to claim 9, wherein the developed titanium structure has an area reduction ≥25%.
11. The nanostructured titanium alloy article according to claim 10, wherein the developed titanium structure has an ultimate shear strength that is ≥740 MPa.
12. The nanostructured titanium alloy article according to claim 10, wherein the developed titanium structure has an ultimate shear strength that is ≥650 MPa.
13. The nanostructured titanium alloy article according to claim 12, wherein the developed titanium structure has an axial fatigue endurance limit ≥700 MPa measured at 10{circumflex over ( )}7 cycles.
14. The nanostructured titanium alloy article according to claim 13, wherein the developed titanium structure has a cantilever-rotating beam fatigue endurance limit ≥650 MPa measured at 10{circumflex over ( )}7 cycles.
15. The nanostructured titanium alloy article according to claim 13, wherein the developed titanium structure has a cantilever-rotating beam fatigue endurance limit ≥700 MPa measured at 10{circumflex over ( )}7 cycles.
16. The nanostructured titanium alloy article according to claim 12, wherein the developed titanium structure has an axial fatigue endurance limit ≥950 MPa measured at 10{circumflex over ( )}7 cycles.
17. The nanostructured titanium alloy article according to claim 1, wherein the developed titanium structure has a composition by weight percent:
nitrogen (N) 0.07% maximum;
carbon (C) 0.1% maximum;
hydrogen (H) 0.015% maximum;
iron (Fe) 0.50% maximum;
oxygen (O) 0.40% maximum;
trace impurities 0.40% maximum; and
a balance of titanium (Ti).
18. The nanostructured titanium alloy article according to claim 17, wherein the developed titanium structure has a composition by weight percent:
Aluminum (Al) 6.75% maximum; and
Vanadium (V) 4.5% maximum.
19. The nanostructured titanium alloy article according to claim 17, wherein the developed titanium structure has a composition by weight percent:
Aluminum (Al) 6.5% maximum;
Niobium (Nb) 7.5% maximum; and
Tantalum (Ta) 0.5% maximum.
20. The nanostructured titanium alloy article according to claim 17, wherein the developed titanium structure has a composition by weight percent:
Zirconium (Zr) 25% maximum; and
other elements 1% maximum."