Introduction
One of the limiting factors in GaN device technology are the relatively high ohmic contact resistances. In the search for improved contact characteristics, a wide variety of metallizations have been investigated on p-GaN besides the standard Ni/Au[Reference Nakamura and Pearton1-Reference Lester, King, Zhang, Ramer, Hersee and Zolper7], including Ni[Reference Ishikawa, Kobayashi, Koide, Yamasaki, Nagai, Umezaki, Koike and Murakami4,Reference Vassilevski, Rastegaeva, Babanin, Nikitina and Dmitriev5,Reference Akasaki, Amano, Sota, Sakai, Tanaka and Koike8], Au[Reference Ishikawa, Kobayashi, Koide, Yamasaki, Nagai, Umezaki, Koike and Murakami4,Reference Lester, King, Zhang, Ramer, Hersee and Zolper7,Reference Smith, Davis, Kim, Carpenter and Huang9,Reference Mori, Kozawa, Ohwaki, Taga, Nagai, Yamasaki, Asami, Shibata and Koike10], Pd[Reference Ishikawa, Kobayashi, Koide, Yamasaki, Nagai, Umezaki, Koike and Murakami4], Pd/Au[Reference Kim, Khim, Chae and Kim11,Reference Trexler, Pearton, Holloway, Mier, Evans and Karlicek12], Pt/Au[Reference King, Zhang, Ramer, Hersee and Lester6], Au/Mg/Au[Reference Smith, Davis, Kim, Carpenter and Huang9,Reference Smith, Bremser, Carlson, Weeks, Huang, Kim, Carpenter and Davis13], Au/C/Ni[Reference Trexler, Miller, Holloway and Khan14], Ni/Cr/Au[Reference Trexler, Pearton, Holloway, Mier, Evans and Karlicek12,Reference Kim, Yoo and Kim15] and Pd/Pt/Au[Reference King, Zhang, Ramer, Hersee and Lester6]. This area has been reviewed recently by Mohney and Lau[Reference Mohney, Lau and Pearton16], and by Liu and Lau[Reference Liu and Lau17]. Typically Ni, Pd or Pt is the metal in direct contact with the GaN, and the structure is annealed at 400 - 750 °C. This produces contact resistances in the 10−1 - 10−3 Ωcm2 range. For higher temperatures severe degradation in contact morphology is observed, usually resulting from the formation of the metal gallides[Reference Mohney, Lau and Pearton16].
For n-type ohmic contacts, the most popular metallization schemes have been those based on Al/Ti/n-GaN, often with overlayers of Au/Ni[Reference Mohney, Lau and Pearton16,Reference Liu and Lau17]. It is believed that diffusion of Al to the metal/GaN interface is a critical step in forming the lowest specific contact resistance, and that TiN formation produces a high concentration of nitrogen vacancies that lead to n+ doping level and lower Rc values[Reference Liu and Lau17]. We have previously reported that both W and WSix on n+ epi GaN layers (n ∼ 1019 cm-3) produce reasonable contacts (Rc ∼ 8×10-5xΩcm2), but extremely stable behavior[Reference Cole, Ren and Pearton18,Reference Cole, Eckart, Han, Pfeffer, Monahan, Ren, Yuan, Stall, Pearton, Li and Lu19] - annealing at 1000 °C led to a shallow reacted region of ≤ 100 Å, and in junction field-effect transistor structures these contacts can withstand implant activation anneals at 1100 °C[Reference Zolper and Shul20].
In this paper we report on use of ion implantation to increase the doping level in GaN, which would be of particular interest for creating n+ or p+ regions in device structures, and also on the characteristics of W and WSix metal contacts on both n- and p-type GaN. The thermal stability of the refractory metal contacts is superior to that of the conventional Ni/Au scheme employed for p-GaN.
Experimental
P-type (NA = 1018 cm−3), Mg-doped GaN layers 1 µm thick were grown on Al2O3 substrates by Molecular Beam Epitaxy using solid Ga and rf plasma-activated N2[Reference Venugopalan, Mohney, Luther, DeLucca, Wolter, Redwing and Bulman21]. Strong cathodoluminescence was observed at ∼385 nm, with very little deep level emission. Undoped GaN layers ∼3 µm thick were grown on Al2O3 by Metal Organic Chemical Vapor Deposition. These samples were implanted with 100 keV Si+ ions at a dose of 5 × 1015 cm−2, and annealed with AlN caps in place to 1400 °C for 10 secs[Reference Bermudez, Kaplan, Khan and Kuznia22]. This produced a peak n-type doping concentration of ∼5 × 1020 cm−3. W or WSi0.45 layers ∼ 1000 Å thick were deposited using an MRC501 sputtering system. The sample position was biased at 90 V with respect to the Ar discharge. Prior to sputtering, the native oxide was removed in a 20:1 H2O:NH4OH solution. Transmission line patterns were defined by dry etching the exposed metal with SF6/Ar, and forming mesas around the contact pads using BCl3/N2 dry etching to confine the current flow. For comparison, on the p-GaN, Au(1000 Å)/Ni(500 Å) was deposited by e-beam evaporation, defined by lift-off and mesas formed by dry etching. Both n- and p-type samples were annealed for 60 secs (in some experiments this was varied from 30 - 300 secs) at 300 - 1000 °C under flowing N2.
In addition, implantation of S, Se and Te for creation of n-type doping and of Mg, Be and C for p-type doping was examined in undoped MOCVD-grown GaN. Annealing was performed up to 1500°C, using AlN cap layers for surface protection.
Results and Discussion
(a) Implantation
Secondary Ion Mass Spectrometry(SIMS) did not detect any measurable redistribution for S, Se, Te, Mg or C at 1450 °C, implying effective diffusivities of ≤2×10−13 cm2 sec−1 for each of these dopants at this temperature. The exception was Be, which displayed an apparent damageassisted diffusion at 900 °C, but did not move at higher annealing temperatures. It appears that in GaN, the intersitial as-implanted Be undergoes a type of transient enhanced diffusion until excess point defects created by the nuclear stopping process of the implanted ions are removed by annealing, at which stage the Be is basically immobile.
While Si+ implantation produced n-type doping levels up to 5×1020 cm−3, the other donors were less effective. The maximum doping achieved with S+ implantation was ∼5×1018 cm−3, while with Te+ it was ∼1.6×1018 cm-3.
It is difficult to create p-type doping by implantation in GaN because of the large ionization levels of acceptor species and n-type character of residual lattice damage. We did not achieve p-type conductivity by implanting C+, while a maximum doping level of 1017 cm−3 was obtained with Mg+ under the same conditions.
(b) Contact Properties
(i) p-GaN
Figure 1 shows annealing temperature dependence of the I-V characteristics of the Ni/Au, W and WSi on p-GaN, with the measurements made at 25 °C in all cases. Note that for the optimum anneal temperatures (700 °C for Ni/Au and W, and 800 °C for WSix), the contacts are not ohmic, but are more accurately described as leaky Schottky diodes. In the case of W and WSi, we assume that annealing above the optimum temperature produces loss of N2 and poorer contact properties.
The contact morphology on the W and WSi metallization remained featureless to the highest temperature we investigated. This is in sharp contrast to the case of Ni/Au, as shown in Figure 2. For the latter metallization, islanding is quite severe after 700 °C annealing due to reaction of the Ni with the GaN[Reference Venugopalan, Mohney, Luther, DeLucca, Wolter, Redwing and Bulman21-Reference Mohney, Luther and Jackson23].
Since the hole concentration in p-GaN will increase rapidly with temperature due to the higher ionization efficiency for the Mg acceptors, we would expect an improvement in contact properties at elevated temperatures. For example, from calculating the Fermi level position as a function of temperature, we find the ionization efficiency improves from ∼10% at 25 °C to ∼56% at 300 °C. Figure 3 shows the I-V characteristics for the 700 °C (Ni/Au and W) or 800 °C(WSi) annealed samples, as a function of the measurement temperature(25 - 300 °C). For the Ni/Au, the contacts become ohmic at ≥ 200 °C, while for W and WSix this occurs at 300 °C. The Rc values at 300 °C are 9.2×10−2 Ωcm2 (Ni/Au), 6.8×10−1 Ωcm2 (W) and 2.6×10−2 Ωcm2 (WSi). The TLM measurements showed that the substrate sheet resistance is reduced from 1.39×104 Ω/□ at 200 °C, to 8470 Ω/□at 250 °C and 4600 Ω/□at 300 °C, indicating that the increased hole concentration plays a major role in decreasing Rc.
(ii) n-GaN
Figure 4 shows the annealing temperature dependence of Rc for W contacts on Siimplanted GaN. The specific contact resistance improves with annealing up to ∼950 °C, which appears to correspond to the region where the β-W2N interfacial phase is formed. Cole et al[Reference Cole, Eckart, Han, Pfeffer, Monahan, Ren, Yuan, Stall, Pearton, Li and Lu19]. reported that W and WSi contacts on GaN annealed in the range 750-850 °C showed the minimum degree of metal protrusion in the interfacial regions devoid of the β-W2N phase, whereas at lower annealing temperatures the horizontal spatial extent of this phase was smaller and allowed more protrusions to develop. The excellent structural stability of the W on GaN was clear from both AES and SEM data on annealed samples.
Summary and Conclusions
W and WSi ohmic contacts on both p- and n-type GaN have been annealed at temperatures from 300 - 1000 °C. There is minimal reaction (≤100 Å broadening of the metal/GaN interface) even at 1000 °C. Specific contact resistances in the 10−6 Ωcm2 range are obtained for W on Si-implanted GaN with a peak doping concentration of ∼ 5 × 1020 cm−3, after annealing at 950 °C. On p-GaN, leaky Schottky diode behavior is observed for W, WSix and Ni/Au contacts at room temperature, but true ohmic characteristics are obtained at 250 - 300 °C, where the specific contact resistances are typically in the 10−2 Ωcm2 range. The best contacts for W and WSix are obtained after 700 °C annealing for periods of 30 - 120 secs. The formation of β-W2N interfacial phases appear to be important in determining the contact quality.
Acknowledgments
The work at UF is partially supported by a DARPA/EPRI grant (D. Radack/J. Melcher) and by an NSF grant (DMR-9732865) monitored by L. D. Hess. Sandia is a multiprogram laboratory operated by Sandia Corporation, a Lockheed-Martin company, for the US Department of Energy under contract No. DEAC04-94AL85000.