SBIR-STTR Award

Aluminum Nitride (A1N) substrates are attractive for III-nitride epitaxial growth due to their high thermal conductivity, close lattice and thermal expansion match to IlI-nitride compositions used for opto-electronic and electronic devices and their relative ease of growth when compared to Gallium Nitride (GaN). Vapor sublimation is an attractive method for growing A1N bulk crystals. Seeded growth is the best way to maximize the crystal growth yield. In standard crystal growth from the melt, a small seed crystal is dipped into the melt and the crystal diameter is slowly increased to reduce the probability of growth failures such as twins or polycrystal. The cone region uses a significant reaction of the melt and results in unusable crystal. A similar process can be used for sublimation growth but for large crystals this method is too inefficient and wasteful. Optimally, sublimation growth of A1N requires a low-defect A1N seed of the same diameter as the crystal to be grown. Unfortunately, A1N crystals of appropriate size are not yet available and other crystals which are not optimally matched to A1N need to be used as seed crystals. In Phase I we propose to determine at least one appropriate, large-area seed for A1N sublimation growth. The best seed will be optimized in Phase II. We recognize that when we have succeeded in growing large-area A1N crystals the hetero-seeding problem will have been solved. Nevertheless, seeding even with A1N seeds will continue to be a significant problem, as it still is with very well established crystal growth methods. After the successful growth of the first large-area A1N crystal, we will optimize A1N as the seed.

Keywords:
Seed Aluminum-Nitride Single-Crystal

Keywords:
Seed Aluminum-Nitride Single-Crystal

A1N is an attractive substrate material for electronic applications of III-nitriides since it is a good insulator and has very high thermal conductivity. A1N can be grown by sublimation and condensation as was demonstrated by Slack. Scaling the A1N growth to commercially viable substrates requires improvements in furnace, crucible, seeding, slicing and polishing. AXT with its technology transfer partner, KSU, proposed a comprehensive development for A1N substrates which included source material, crystal growth and wafer preparation. In Phase I, we successfully demonstrated the feasibility of all aspects of the program. Sources of high purity A1N were identified and samples.. The sublimation rate of A1N powder as a function of temperatures was measured and was shown to be sufficiently high for large crystal growth at high temperature. PBN was demonstrated as a suitable crucible and reactor furniture material for A1N growth. A high density of small, unseeded crystals was spontaneously nucleated in the crucible. Small samples of epitaxially grown GaN, as a proxy for A1N, were mechanically and chem-mechanically polished to a high quality surface finish. In summary, all key elements required to grow large A1N crystals and prepare wafers were demonstrated in Phase I. In Phase II, we propose to implement seeded crystal growth by using seed crystals prepared by epitaxial growth of A1N on SiC or sapphire and by controlled spontaneous nucleation, to modify the reactor to give more controlled temperature zones for sublimation and crystallization, to scal up the furnace to allow growth of crystals up to 50 mN diameter by 100mN length and to slice and polish A1N wafers. We will also demonstrate epitaxy growth on the substrates and distribute substrates to users.

Keywords:
A1N SUBLIMATION CONDENSATION SEEDED GROWTH SLICING CHEM-MECHANICAL POLISHING SEMICONDUCTOR