We report on an extensive study of the two-dimensional electron gas (2DEG) structures containing AlN layers. It is shown that the presence of large polarization fields in the AlN barrier layer in AlN/GaN heterostructures results in high values of the 2DEG sheet density of up to 3.6×1013 cm−2. Room-temperature sheet resistance of 180 Ω/□ is demonstrated in the AlN/GaN structure with a 35 Å AlN barrier. As a result of reduced alloy disorder scattering, low-temperature electron mobility is significantly enhanced in AlN/GaN heterostructures in comparison to AlGaN/GaN structures with similar values of the 2DEG sheet density. The growth of GaN cap layers on top of AlN/GaN structures with relatively thick (∼35 Å) AlN barriers is found to lead to a significant decrease in the 2DEG sheet density. However, inserting a thin (∼10 Å) AlN layer between AlxGa1−xN and GaN in the AlxGa1−xN/GaN (x∼0.2–0.45) 2DEG structures does not affect the 2DEG sheet density and results in an increase of the low-temperature electron mobility in comparison to standard AlGaN/GaN structures. At room temperature, a combination of the high 2DEG sheet density of 2.15×1013 cm−2 and high electron mobility of 1500 cm2/V s in Al0.37Ga0.63N/AlN/GaN yielded a low sheet resistance value of 194 Ω/□.
An overview is presented of progress in GaN electronic devices along with
recent results from work at UCSB. From 1995 to 2001, the power performance of
AlGaN/GaN high electron mobility transistors (HEMT) improved from 1.1 to
11 W mm-1, respectively. The disadvantage of the low thermal conductivity
of the sapphire substrate was mitigated by flip-chip bonding onto AlN
substrates, yielding large periphery devices with an output power of 7.6 W. A
variety of HEMT amplifier circuits have been demonstrated. The first AlGaN/GaN
heterojunction bipolar transistor (HBT) was demonstrated in 1998, with a
current gain of about 3. By developing the technique of emitter regrowth, a
current gain of 10 was achieved in both GaN BJTs and AlGaN/GaN HBTs. A common
emitter current gain cutoff frequency of 2 GHz was measured. Critical issues
involved in the growth of high quality AlGaN/(AlN)/GaN heterostructures and
GaN:Mg by metal-organic chemical vapour deposition (MOCVD) and molecular beam
epitaxy (MBE) and the device fabrication are discussed.
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