High quality group-III metal nitride crystals, methods of making, and methods of use

What is claimed is: 1. A group III metal nitride crystal made from a process comprising: depositing at least one patterned mask layer on a substrate to form a patterned substrate, said mask layer comprising at least an inert layer comprising one or more of Au, Ag, Pt, Pd, Rh, Ru, Ir, Ni, Cr, V, Ti, or Ta, said inert layer being adhered to said substrate; placing said patterned substrate within a sealable container along with a group III metal source, at least one mineralizer composition, and a nitrogen containing solvent; and forming an ammonothermal group III metal nitride layer having one or more coalescence fronts on the patterned substrate by heating said sealable container, wherein said one or more coalescence fronts comprise a pattern of locally-approximately-linear arrays of threading dislocations, said threading dislocations having a concentration between about 5 cm −1 and about 10 5 cm −1 , said pattern having: at least one pitch dimension between about 5 micrometers and about 20 millimeters; and regions between said locally-approximately-linear arrays of threading dislocations having a threading dislocation density below about 10 5 cm −2 and a stacking-fault concentration below about 10 3 cm −1 . 2. The crystal of claim 1 , wherein the crystal comprises a group III metal selected from gallium, aluminum, indium, and a combination of any of the foregoing; and nitrogen. 3. The crystal of claim 1 , wherein the first large-area surface is characterized by, a symmetric x-ray rocking curve full width at half maximum less than about 200 arcsec; an impurity concentration of H greater than about 10 17 cm −3 ; and an impurity concentration greater than about 10 15 cm −3 of at least one of Li, Na, K, F, CI, Br, and I, as quantified by calibrated secondary ion mass spectrometry. 4. A bulk crystal grown on the crystal of claim 1 . 5. The crystal of claim 1 , wherein said mask layer comprises a discrete adhesion layer to adhere said inert layer to said substrate. 6. The crystal of claim 1 , wherein said mask layer comprises a discrete diffusion barrier layer. 7. The crystal of claim 1 , wherein the pattern further comprises a one-dimensional or two-dimensional array of openings having an opening dimension between about 1 micrometer and about 5 millimeters. 8. The crystal of claim 1 , wherein said crystal comprises a first large-area surface having a maximum dimension greater than about 10 millimeters. 9. The crystal of claim 1 , wherein said mask layer has a thickness between about 10 nanometers and about 100 micrometers. 10. The crystal of claim 1 , wherein said heating said sealable container comprises heating said sealable container to a temperature of at least about 400 degrees Celsius and pressurizing it to a pressure above about 50 MPa for a duration of at least 100 hours. 11. The crystal of claim 1 , wherein said inert layer comprises at least Au. 12. The crystal of claim 1 , wherein the substrate consists essentially of a free-standing, bulk, gallium nitride substrate. 13. A wafer formed from a bulk crystal grown on a seed crystal derived from a group III metal nitride crystal made from a process comprising: depositing at least one patterned mask layer on a substrate to form a patterned substrate, said mask layer comprising at least an inert layer comprising one or more of Au, Ag, Pt, Pd, Rh, Ru, Ir, Ni, Cr, V, Ti, or Ta, said inert layer being adhered to said substrate; placing said patterned substrate within a sealable container along with a group III metal source, at least one mineralizer composition, and a nitrogen containing solvent; and forming an ammonothermal group III metal nitride layer having one or more coalescence fronts on the patterned substrate by heating said sealable container; wherein said wafer is a free-standing ammonothermal group III metal nitride crystal, wherein the crystal is characterized by a wurtzite crystal structure, and comprises at least: a group III metal selected from gallium, aluminum, indium, and a combination of any of the foregoing, and nitrogen; and a first large-area surface having a maximum dimension greater than about 10 millimeters, wherein the first large-area surface is characterized by, a symmetric x-ray rocking curve full width at half maximum less than about 200 arcsec; an impurity concentration of H greater than about 10 17 cm −3 ; and an impurity concentration greater than about 10 15 cm −3 of at least one of Li, Na, K, F, Cl, Br, I, as quantified by calibrated secondary ion mass spectrometry, wherein the first large-area surface comprises a pattern of locally-approximately-linear arrays of threading dislocations having a concentration between about 5 cm −1 and about 10 5 cm −1 , and wherein the pattern is characterized by, at least one pitch dimension between about 5 micrometers and about 20 millimeters; and regions between said locally-approximately-linear arrays of threading dislocations having a threading dislocation density below about 10 5 cm −2 and a stacking-fault concentration below about 10 3 cm −1 . 14. The wafer of claim 13 , wherein the first large-area surface is characterized by a crystallographic orientation within 5 degrees of a {10-10} m-plane. 15. The wafer of claim 13 , wherein the first large-area surface is characterized by a crystallographic orientation within 5 degrees of a (0001) +c-plane or within 5 degrees of a (000−1)−c-plane. 16. The wafer of claim 13 , wherein the first large-area surface is characterized by a crystallographic orientation within 5 degrees of a semipolar orientation selected from {60−6±1}, {50−5±1}, {40−4±1}, {30−3±1}, {50−5±2}, {70−7±3}, {20−2±1}, {30−3±2}, {40−4±3}, {50−5±4}, {10−1±1}, {1 0 −1±2}, {1 0 −1±3}, {2 1 −3±1}, and {3 0 −3±4}. 17. The wafer of claim 13 , wherein the first large-area surface is characterized by impurity concentrations of oxygen (O), hydrogen (H), and at least one of fluorine (F) and chlorine (Cl) between about 1×10 16 cm −3 and about 1×10 19 cm −3 , between about 1×10 16 cm −3 and about 2×10 19 cm −3 , and between about 1×10 15 cm −3 and about 1×10 19 cm −3 , respectively. 18. The wafer of claim 13 , wherein the first large-area surface is characterized by impurity concentrations of oxygen (O), hydrogen (H), and at least one of sodium (Na) and potassium (K) between about 1×10 16 cm −3 and about 1×10 19 cm −3 , between about 1×10 16 cm −3 and about 2×10 19 cm −3 , and between about 3×10 15 cm −3 and about 1×10 18 cm −3 , respectively. 19. The wafer of claim 13 , wherein the wurtzite crystal structure is characterized to be substantially free of other crystal structures, the other crystal structures being less than about 1% in volume in reference to a volume of the substantially wurtzite crystal structure. 20. The wafer of claim 13 , wherein the crystal is substantially free of cracks. 21. The wafer of claim 13 , wherein the pattern is selected from two-dimensional hexagonal, square, rectangular, trapezoidal, triangular, and one-dimensional linear. 22. The wafer of claim 13 , wherein the locally-approximately-linear arrays are oriented within about 5 degrees of a crystallographic plane selected from {10−1 0}, {11−2 0}, and {0 0 0±1}, and a projection of the crystallographic plane on the large-area surface. 23. The wafer of claim 13 , wherein the pattern is characterized by a pitch dimension between about 200 micrometers and about 5 millimeters. 24. The wafer of claim 13