2015
DOI: 10.1016/j.jcrysgro.2015.08.027
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Single-crystalline semipolar GaN on Si(001) using a directional sputtered AlN intermediate layer

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Cited by 15 publications
(8 citation statements)
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“…Since the structures grown on the template are determined by the quality of the mother layer, it may be questioned whether pulsed-mode growth can still be effectively carried out on low-quality templates with nanoscale thickness (<100 nm) and/or similar seed materials. 17 Once the feasibility of growing GaN nanorod arrays on ultrathin templates has been proved, several benefits can be expected in Si-based GaN epitaxy: (1) the availability of templates for physical deposition methods such as AlN sputtering; 28 (2) direct growth without strain relaxation layers (a stack of AlGaN layers is commonly used); (3) optical selectivity from the mother layer because of the large bandgap difference; (4) the realization of advanced device structures on nanoarray platforms such as novel III nitride/silicon tandem solar cells and vertical field-effect transistors. 29,30 In particular, the first and second benefits reduce costs owing to cheaper maintenance and simplified epilayers.…”
Section: Introductionmentioning
confidence: 99%
“…Since the structures grown on the template are determined by the quality of the mother layer, it may be questioned whether pulsed-mode growth can still be effectively carried out on low-quality templates with nanoscale thickness (<100 nm) and/or similar seed materials. 17 Once the feasibility of growing GaN nanorod arrays on ultrathin templates has been proved, several benefits can be expected in Si-based GaN epitaxy: (1) the availability of templates for physical deposition methods such as AlN sputtering; 28 (2) direct growth without strain relaxation layers (a stack of AlGaN layers is commonly used); (3) optical selectivity from the mother layer because of the large bandgap difference; (4) the realization of advanced device structures on nanoarray platforms such as novel III nitride/silicon tandem solar cells and vertical field-effect transistors. 29,30 In particular, the first and second benefits reduce costs owing to cheaper maintenance and simplified epilayers.…”
Section: Introductionmentioning
confidence: 99%
“…Without any ordering from the interface, the AlN layer wants to orient itself into (0001), since this orientation is obtained when sputtering at room temperature. 32) By gradually tilting to (0001), the next stable is the (10-14) orientation. The lattice mismatch of (10-14) AlN/sapphire is 9% along [11][12][13][14][15][16][17][18][19][20] sapphire (Table I).…”
Section: Discussionmentioning
confidence: 99%
“…27) However, direct growth on m-plane sapphire usually leads to a formation of twinned N-polar (10-1-3) GaN due to inherent twofold symmetry of the bonds at the GaN/sapphire interface. [28][29][30] Recently, untwinned (10-13) GaN layers were reported using directional sputtering on (001) Si [31][32][33] and m-plane sapphire. 34) Semi-polar orientations even more inclined towards (0001) have been only reported by planar growth on (112) and (113) Si.…”
Section: Introductionmentioning
confidence: 99%
“…Nonpolar and semipolar GaN-based structures are usually grown on foreign lattice-mismatched substrates (bulk GaN substrates are generally expensive and small in size, not to even mention of the nonpolar and semipolar orientations) and thus suffer from insufficient quality, shared by polar orientation growth as well. Sputtered AlN buffers were found to be useful for MOCVD growth of nonpolar and semipolar GaN on Si [63][64][65] and sapphire substrates [66,67].…”
Section: Sputtered Aln Buffers For Growth Of Nonpolar and Semipolar Ganmentioning
confidence: 99%