A method for making LNO film, including the steps of identifying a substrate, identifying a deposition target, placing the substrate and deposition target in a deposition environment, evolving target material into the deposition environment, and depositing evolved target material onto the substrate to yield an LNO film. The deposition environment defines a temperature of between 500 degrees Celsius and 750 degrees Celsius and a pressure of about 10.sup.−6 Torr. A seed or buffer layer may be first deposited onto the substrate, wherein the seed layer is about 30 mole percent gold and about 70 LiNbO.sub.3.

The disclosure relates to a method for growing a semiconductor assembly. The method includes the steps of providing a silicon substrate and growing two metal nitride layers, each metal nitride layer being grown by means of a metal target and a plasma. For the second metal nitride layer a higher hydrogen content is used, allowing for better crystal quality than in known methods. The disclosure further relates to a semiconductor assembly that is produced accordingly.

Systems, methods, and devices of the various embodiments may provide a mechanism to enable the growth of a rhombohedral epitaxy at a lower substrate temperature by energizing the atoms in flux, thereby reducing the substrate temperature to a moderate level. In various embodiments, sufficiently energized atoms provide the essential energy needed for the rhombohedral epitaxy process which deforms the original cubic crystalline structure approximately into a rhombohedron by physically aligning the crystal structure of both materials at a lower substrate temperature.

Systems, methods, and devices of the various embodiments may provide a mechanism to enable the growth of a rhombohedral epitaxy at a lower substrate temperature by energizing the atoms in flux, thereby reducing the substrate temperature to a moderate level. In various embodiments, sufficiently energized atoms provide the essential energy needed for the rhombohedral epitaxy process which deforms the original cubic crystalline structure approximately into a rhombohedron by physically aligning the crystal structure of both materials at a lower substrate temperature.

A composite nitride-based film structure includes a bulk single crystal, a plurality of nitride microcrystals, and an amorphous nitride thin film. The plurality of nitride microcrystals is provided on the bulk single crystal, and has a specific orientation relationship with a crystal structure of the bulk single crystal. The nitride thin film is provided on the bulk single crystal, surrounds the nitride microcrystal, and covers a surface of the bulk single crystal.

A composite nitride-based film structure includes a bulk single crystal, a plurality of nitride microcrystals, and an amorphous nitride thin film. The plurality of nitride microcrystals is provided on the bulk single crystal, and has a specific orientation relationship with a crystal structure of the bulk single crystal. The nitride thin film is provided on the bulk single crystal, surrounds the nitride microcrystal, and covers a surface of the bulk single crystal.

A bonded body includes a supporting substrate; a piezoelectric material substrate composed of a material selected from the group consisting of lithium niobate, lithium tantalate and lithium niobate-lithium tantalate; and a bonding layer bonding the supporting substrate and the piezoelectric material substrate and contacting a main surface of the piezoelectric material substrate. The bonding layer includes a void extending from the piezoelectric material substrate to the supporting substrate.

A method for manufacturing nitride catalyst is provided, which includes putting a Ru target and an M target into a nitrogen-containing atmosphere, in which M is Ni, Co, Fe, Mn, Cr, V, Ti, Cu, or Zn. The method also includes providing powers to the Ru target and the M target, respectively. The method also includes providing ions to bombard the Ru target and the M target for depositing M.sub.xRu.sub.yN.sub.2 on a substrate by sputtering, wherein 0<x<1.3, 0.7<y<2, and x+y=2, wherein M.sub.xRu.sub.yZ.sub.2 is cubic crystal system or amorphous.

A method for manufacturing nitride catalyst is provided, which includes putting a Ru target and an M target into a nitrogen-containing atmosphere, in which M is Ni, Co, Fe, Mn, Cr, V, Ti, Cu, or Zn. The method also includes providing powers to the Ru target and the M target, respectively. The method also includes providing ions to bombard the Ru target and the M target for depositing M.sub.xRu.sub.yN.sub.2 on a substrate by sputtering, wherein 0<x<1.3, 0.7<y<2, and x+y=2, wherein M.sub.xRu.sub.yZ.sub.2 is cubic crystal system or amorphous.

A bonded body includes a supporting substrate; a piezoelectric material substrate composed of a material selected from the group consisting of lithium niobate, lithium tantalate and lithium niobate-lithium tantalate; and a bonding layer bonding the supporting substrate and the piezoelectric material substrate and contacting a main surface of the piezoelectric material substrate. The bonding layer includes a void extending from the piezoelectric material substrate to the supporting substrate.