A key milestone for the next generation of high-performance multifunctional microelectronic devices is the monolithic integration of high-mobility materials with Si technology. The use of Ge instead of Si as a basic material in nanoelectronics would need homogeneous p- and n-type doping with high carrier densities. Here we use ion implantation followed by rear side flash-lamp annealing (r-FLA) for the fabrication of heavily doped n-type Ge with high mobility. This approach, in contrast to conventional annealing procedures, leads to the full recrystallization of Ge films and high P activation. In this way single crystalline Ge thin films free of defects with maximum attained carrier concentrations of 2.20 ± 0.11 × 1020 cm−3 and carrier mobilities above 260 cm2/(V·s) were obtained. The obtained ultra-doped Ge films display a room-temperature plasma frequency above 1,850 cm−1, which enables to exploit the plasmonic properties of Ge for sensing in the mid-infrared spectral range.
The incorporation of different functional optoelectronic elements on a single chip enables performance progress, which can overcome the downsizing limit in Si technology. To this day the application of Ge is limited to fiber-optic systems, infrared optics, photovoltaics and special applications in microelectronics where the high performance logic devices are crucial1,2,3,4,5,6,7,8. Furthermore, plasmonic sensing in the mid-infrared (MIR) has not been accessible to semiconductors so far, however, ultra-doped n-type Ge with carrier concentration in the range of 1019 to 1021 cm−3 is perfectly suited for such purpose9,10,11. When compared with n-type Si, n-type Ge is characterised by a smaller electron effective mass, 0.12 me for Ge vs. 0.26 me for Si, which corresponds to a higher plasma frequency (ωp) for certain doping levels. The near-infrared and MIR is the optical spectral range where most of the vibrational modes of bio- and gas molecules are located. The use of group IV-semiconductors for the plasmonic sensors will increase the diversity of microelectronic device applications fabricated in the Si complementary metal-oxide semiconductor (CMOS) technology processes12,13. For example, nanostructured n-type Ge with an ultra-high doping level can replace nanostructured gold antennas used nowadays10. Moreover, the fabrication of ultra-doped n-type Ge in a controllable way allows for the conversion of Ge from an indirect to a direct bandgap semiconductor via decreasing the energy difference between the conduction band valleys at the Γ and L point and can finally introduce a crossover of the Γ and L conduction band minima14,15. One of the main obstacles towards application of Ge in plasmonics is the lack of an efficient doping method for the fabrication of heavily doped Ge n-type layers with effective carrier concentrations well above 1019 cm−3.
In this paper we report on a sub-second fast annealing method using flash lamp annealing (FLA) to recrystallize Ge layers amorphized during ion implantation and to activate P dopants. It is shown that P implanted Ge with an amorphous layer thickness above 200 nm can be completely recrystallized without a significant diffusion of P. The novelty of our approach is based on the millisecond range rear-side FLA (r-FLA) treatment. Using r-FLA an effective carrier concentration above 2 × 1020 cm−3 with an activation efficiency around 80% and a carrier mobility above 260 cm2/(V·s) in P doped Ge is achieved. Such high activation efficiency in ultra-doped Ge makes ion implantation followed by r-FLA unique among different doping techniques. The recrystallization mechanism of Ge during millisecond range r-FLA, namely the interplay between random nucleation and solid phase epitaxy (SPE), is discussed in detail. We also demonstrate a room-temperature plasma frequency as high as 1,850 cm−1, which is suited for mid-infrared plasmonics.
In fact, n-type doping of Ge is a key bottleneck in the realization of advanced negative-channel metal-oxide-semiconductor (NMOS) devices16. The donors are fast diffusers and the diffusion is known to be mediated by vacancies17. Moreover, the energy levels of vacancy defects in Ge are located near the valence band edge leading to significant compensation of the n-type dopants like P or As18. Finally, the maximum effective carrier concentration in P doped Ge is limited by the self-compensation effect and by the P out-diffusion during growth which again limits the electrical activation efficiency of P to about 20% for doping above the solid-solubility limit (above 2 × 1020 cm−3)19,20,21. Therefore, single-step ion implantation followed by conventional annealing only allows for n-type doping in Ge in the range of 1–3 × 1019 cm−3. Using millisecond-range flash lamp annealing (FLA) and ion implantation n-type and p-type Ge layers with an active carrier concentration above 6 × 1019 cm−3 and 3 × 1020 cm−3 were reported, respectively22,23,24. Also, a similar electron concentration was obtained by the in-situ doping of epitaxial Ge thin films during chemical vapour deposition (CVD) or standard molecular beam epitaxy (MBE) using in-diffusion with a δ-doped layer as the source of P25,26.
Recently, G. Scappucci, et al. have proposed a MBE based bottom-up approach to produce n-type metallic Ge layers with electrically active carrier concentrations as high as 1.9 × 1020 cm−3 and 0.9 × 1020 cm−3 in the bi-layer and multi-layer sample, respectively19,20. The recent progress in the n-type doping in Ge is summarized in Fig. 1.
In general, the doping of semiconductors can be performed either in-situ26, during the growth of thin films, or ex-situ where the ion implantation is the only non-equilibrium technique allowing to introduce impurities into semiconductors significantly above the solid solubility limit. To this day, the highest reported value for the density of electrically active donors in P doped Ge was 1.74 × 1020 cm−3 with 44% of the electrically active dopants19,27. Such high dopant concentration was achieved by stacking multiple Ge:P δ-doped layers with 2 nm of Ge spacer-layer using MBE. In the case of P implanted Ge a doping level of 6 × 1019 cm−3 was obtained using ultra-short FLA treatment in the millisecond range23 and 1 × 1020 cm−3 by multi-implantation approach followed by rapid thermal annealing after each implantation step28.
Figure 2a shows the Rutherford backscattering/channelling (RBS/C) spectra obtained from a P implanted Ge wafer after front FLA (f-FLA) and r-FLA. As already mentioned, ion implantation followed by millisecond range FLA has successfully been demonstrated to achieve a maximum carrier concentration in the range of 6 × 1019 cm−3 for a P concentration above 1021 cm−3 in Ge23. However, according to ref. 23 the implanted layer is epitaxially regrown after f-FLA for 3 ms, only if the damaged zone is thinner than 80 nm23. If the damaged zone is thicker than 80 nm, polycrystalline Ge is formed after the f-FLA. Such a behaviour has also been observed in our study (see green curve in Fig. 2a). Within a 115 nm thick surface layer (channel number 750 to 780), the random and channeling spectra obtained from the front-side flashed sample are almost identical. It implies that this region is either strongly disordered or polycrystalline. The thickness of the polycrystalline layer was extracted from the RBS raw data, using established RBS analysis software RUMP29. Additionally, from the P profile obtained by SIMS (see an arrow at green curve, Fig. 2b) a small peak located at around 110 nm from the surface is clearly observed in the f-FLA samples. This peak precisely coincides with the interface between the polycrystalline and the epitaxially regrown layer. Moreover, the channelling spectra recorded from rear-side flashed samples with two different P concentrations show no significant differences of the backscattering yield between the implanted depth and the single crystalline bulk Ge. This proves directly the formation of a single crystalline n-type Ge layer via solid phase epitaxy. Due to the slight diffusion of P atoms during r-FLA, the peak of the atomic concentration of P is reduced from 2 × 1020 cm−3 (as-implanted) to 1.12 × 1020 cm−3 after annealing as can be seen in Fig. 2b (red curve).
Electrical characterisation of P doped Ge
The sheet resistance and Hall Effect measurements were performed in a 4-probe van der Pauw configuration in the temperature range from 2 to 300 K. Figure 3a shows the low-temperature range (below 30 K) of sheet resistance measured for two Ge samples after r-FLA with a nominal P concentration of 2 × 1020 cm−3 and 4 × 1020 cm−3 (the P concentration is referred to the as-implanted stage). The sheet resistance in the temperature range of 2 to 300 K is shown in the inset of Fig. 3a. Starting from 300 K it slightly decreases with decreasing temperature, goes through a minimum around 15 to 25 K, slowly increases and becomes temperature independent below 8 K. Taking into account the doped layer thickness of about 100 nm the mean layer resistivity of doped layer at low temperature is in the range of 10−4 Ωcm. Such a low resistivity and temperature independent sheet resistance below 8 K indicates that the P-doped Ge layers are metallic20. In order to eliminate an influence of the p-type substrate on the electrical properties of P doped Ge layers the Hall effect measurements presented in Fig. 3b,c were performed at 2 K. At such low temperatures, the carrier contribution from the substrate to the transport measurement can be neglected since acceptors are frozen out and the current is entirely due to electrons in the ultra-doped layer. As shown in Fig. 3b,c the relative activation efficiency of P is close to 100% for the sample doped with the low concentration (1 × 1020 cm−3) and the carrier mobility is as large as 340 cm2/(V·s). The presented mean carrier concentrations for particular doping level were estimated using the measured 2D Hall concentration and the thickness of the doped layer estimated from SIMS measurements (125 nm for a P concentration of 1 × 1020 cm−3, 145 nm for 2 × 1020 cm−3, 155 nm for 4 × 1020 cm−3 and 6 × 1020 cm−3). The carrier concentration measured at 2 K was found to be (1.20 ± 0.06) × 1020 cm−3 with a carrier mobility of around 260 cm2/(V·s) at a concentration of 2 × 1020 cm−3 (activation efficiency about 60%) and (2.20 ± 0.11) × 1020 cm−3 at a concentration of 4 × 1020 cm−3 with a carrier mobility of around 130 cm2/(V·s), respectively (see Fig. 3b). For the highest P concentration (6 × 1020 cm−3) the efficiency of the electrical activation of P and the carrier mobility are the lowest of the tested samples, namely 25% and 70 cm2/(V·s), respectively. According to the Ge-P phase diagram reported by Olesinski et al. the maximum solid solubility limit of P in Ge is limited to 5 × 1019 cm−3 at 700 °C30. In our case, using millisecond range r-FLA at the same annealing temperature, the obtained electrically active P concentration is much higher than the reported solid solubility limit of P in Ge and is one of the highest ever published for P doped Ge layers. For P concentrations in Ge higher than 2 × 1020 cm−3 a large fraction of P atoms cannot be electrically active since P will substitute Ge at the neighboring position forming P-P dimers19. The probability of P-P dimer formation in implanted Ge is significantly enhanced by conventional high-temperature annealing due to the strong P diffusion and increases with P concentration. Moreover, all lattice damage and remaining vacancies as well as other defects which act as recombination centres lead to the electron mobility degradation and donor compensation which mainly limits the maximum carrier concentration in doped Ge layers using ion implantation. The high activation efficiency obtained here suggests that after r-FLA the implanted layer is practically defect-free. Sheet resistance values below 60 Ω/sqr and carrier densities higher than 2 × 1020 cm−3 ensure low access resistance for nano-electronic devices required for source/drain contacts and make Ge attractive for optoelectronic applications.
Optical properties of ultra-doped Ge
Figure 4a shows micro-Raman spectra obtained from virgin and P doped Ge at the as-implanted stage and after FLA treatment from either front or rear side. The as-implanted sample exhibits a weak broad phonon mode located at 290 cm−1 due to the amorphous Ge layer created during P implantation. The full width at half maximum (FWHM) of the crystalline TO/LO phonon mode (at about 301 cm−1) varies from 3.14 cm−1 (for virgin Ge) to 3.80 cm−1 for P doped Ge after f-FLA. Additionally, the TO peak position of the sample after f-FLA is shifted by 0.60 cm−1 towards lower wavenumber. The red shift and the significant broadening of the TO phonon mode indicate the existence of a strongly disordered or polycrystalline Ge layer. This is in agreement with the presented RBS channeling data (shown in Fig. 2a). The same phenomenon was observed by Heera et al. in Ge wafers implanted with Ga followed by f-FLA24.
Spectroscopic ellipsometry represents a simple method to investigate the band structure of semiconductors. However, due to the low crystalline quality of semiconductors modified by ion implantation, the signatures of the main critical points are often smeared out31. Figure 4b shows the second derivative of the imaginary part of the dielectric function taken at an incident angle of 80 degree from a virgin Ge wafer and from Ge samples doped with different P concentrations after r-FLA and f-FLA. The changes in the ellipsometric spectra are caused by the modification of the interband transitions in the vicinity of critical points in the Brillouin zone. The second derivatives of the high-energy part of the dielectric function show two peaks at about 2.12 and 2.30 eV corresponding to E1 and E1 + Δ1 transitions near the Λ point, respectively. In contrast to ion implanted Ge followed by other annealing methods such as nanosecond laser annealing31 and f-FLA, in the r-FLA treated samples all critical points are clearly resolved confirming the high-quality of the ultra-doped n-type Ge layer. Moreover, the ellipsometric data clearly show a blue shift of the critical points with increasing P concentration. The E1 critical point shifts by 35 meV upon increasing the doping of Ge to (2.20 ± 0.11) × 1020 cm−3. The blue-shift of the critical points with increasing P doping above 2 × 1020 cm−3 is due to the compressive strain caused by the incorporation of P into the lattice of the Ge crystal. During epitaxial regrowth of the implanted layer under r-FLA, the P atoms having a smaller radius than Ge cause an uniaxial lattice compression of the doped layer along . The same effect was observed in Si implanted with B32. The critical points observed in the ellipsometry spectrum obtained from the f-FLA sample smear out which is typical for a low crystalline quality or polycrystalline semiconductors.
The mid-infrared absorption in ultra-doped Ge was investigated using Fourier transform infrared (FTIR) spectroscopy in the near and mid-infrared spectral range (from 400 to 7000 cm−1). Figure 5 shows the reflectivity spectra taken from commercial n-type Ge wafer (open squares – Ge-Ref) and ultra-doped Ge layers after r-FLA treatment (open circle – ne = 9 × 1019 cm−3 and open triangular ne = (2.20 ± 0.11) × 1020 cm−3). The effective carrier concentration in the implanted samples measured by Hall Effect was found to be around (9.00 ± 0.05) × 1019 cm−3 and (2.20 ± 0.11) × 1020 cm−3 at 2 K and (1.30 ± 0.06) × 1020 cm−3 and (3.20 ± 0.16) × 1020 cm−3 at 300 K. Prior to the measurements, the reference spectrum was recorded on a gold mirror in vacuum at room-temperature with the same optical alignment which was used to detect the reflectivity from Ge. Spectra presented in Fig. 5 are obtained by dividing the sample spectrum by the reference spectrum. Although the doped layer was only about 140 nm the shift of the plasma edge to higher frequencies with increasing doping concentration is clearly visible. According to theory, the plasma frequency edge is proportional to n0.5 and (m*)−0.5, where n is the carrier concentration and m* is the electron effective mass and should exhibit a blue shift with increasing n9. The plasma frequency ωp for a given doping level and particular material can be represented according to:
where ε∞ and ε0 are the high-frequency dielectric constant (for ultra-doped n-type Ge ε≈16) and the permittivity of free space, respectively. e is the elementary charge. The plasma frequency ωp taken from the real part of the dielectric function (ε′ = 0) is 1,850 cm−1 (ωp = 5,400 nm) (see the inset in Fig. 5) which is the highest value ever published for n-type Ge. To calculate the real and imaginary part of dielectric function we have used the Drude model where: ε∞ = 15.04, damping factor 63.35 cm−1 and σDC: 13,400 (Ωcm)−1.
The absorbed energy delivered to the sample during the FLA process depends on the overall optical absorption and reflection of the investigated system. Averaged over the flash-lamp spectrum, the absorption of amorphous Ge is about 24% higher than that of crystalline Ge. Moreover, the limited ability of a material to dissipate heat by heat conduction will lead to a corresponding strong temperature gradient over the wafer thickness. Therefore, in order to achieve the same temperature within the implanted layer, samples flashed from rear-side were preheated up to 180 °C prior to the flash. Finally, the temperature within the implanted region was about 700 °C for both cases (see Fig. 6). Although the maximum temperature within the implanted layer is roughly the same for both types of annealing, the temperature as a function of time within the implanted layer varies significantly. After f-FLA the implanted layer is kept at a temperature above 600 °C for about 2 ms while after r-FLA the implanted layer is at a temperature higher than 600 °C for a much longer time (see Fig. 6). This has a strong influence on the distribution of dopants in Ge, especially on the fast diffuser phosphorus and on the recrystallization process during the sub-second flash annealing. In order to explain the recrystallization mechanism of an implanted Ge layer during f-FLA, the different values of the activation energy and the pre-factor for seed nucleation and solid phase epitaxy as well as the temperature gradient within the amorphous layer and the speed of heat dissipation have to be taken into account30,31,32,33,34,35,36,37,38. Moreover, the incubation time of crystalline seeds at the surface for the random nucleation has to be considered. According to the reported data from calorimetric studies, e.g. in refs 33,37, in our case the incubation time of crystalline seeds and the recrystallization speed are expected to be in the range of 1 μs and 1 × 10−4 m/s, respectively. On the other hand, L. Nikolova et al. have shown that during ns-range laser annealing the incubation time for seed nucleation is as short as 20 ns, that the a-Ge/c-Ge interface moves with a speed of 20 m/s and that the activation energy is 1.4 eV38. For the activation energy of solid phase epitaxy (1.09 eV) a similar value was reported by M. Posselt and A. Gabriel using molecular-dynamics simulations39. The present f-FLA method is more similar to pulsed laser annealing than to the conventional rapid thermal annealing or furnace annealing. Moreover, it appears that the incubation time for nucleation and activation energy for the same mechanism is strongly temperature dependent. In our case, during f-FLA we considered both the temperature gradient within the implanted layer and a thermally activated incubation time which delays the onset of solid phase epitaxy from the surface. During f-FLA the energy deposited to the sample surface is absorbed within the first 30–50 nm of the implanted Ge layer leading to a temperature gradient within the amorphous layer. If the amorphized Ge layer is thicker than 100 nm, in case of f-FLA the temperature difference between the surface and the a-Ge/c-Ge interface is large enough to favour recrystallization from the surface via seed nucleation. As a consequence, the poly-crystalline Ge layer propagates towards the crystalline substrate together with heat dissipation because the heat dissipation in a-Ge is much faster than the movement of the crystalline/amorphous (c-Ge/a-Ge) interface at 700 °C40.
The deep a-Ge/c-Ge interface gets hot enough for the epitaxial regrowth of the implanted layer towards the surface before the implanted layer is fully recrystallized via seed nucleation (see Fig. 7a). As a result, during flash annealing from the front side two different recrystallization mechanisms take place: recrystallization via seed nucleation and solid phase epitaxy, as schematically shown in Fig. 7a. Interestingly, the snow-plough effect was observed only within the layer regrown via seed nucleation (marked by the arrow in Fig. 2b)41,42,43. Due to this effect the surplus of P is pushed ahead reducing slightly the peak concentration. Within the epitaxially regrown layer no P diffusion was detected (see Fig. 2b). In this particular case, the polycrystalline/single crystalline interface is located at about 115 nm below the surface.
Figure 7b shows schematically the recrystallization process during r-FLA. Because the highest temperature is always obtained at the flashed side, the heat is transferred through the whole wafer to the implanted layer. At such conditions the a-Ge/c-Ge interface gets hot first and the implanted amorphous layer recrystallizes epitaxially. The a-Ge/c-Ge interface has a temperature of about 600 °C after 6 ms during r-FLA. As can be seen in Fig. 6 the temperature within the implanted layer drops below 500 °C within 5 ms after f-FLA and needs more than 20 ms in the case of r- FLA. As a consequence, samples annealed from the rear-side are single crystalline up to the surface and, rather than the snow-plough effect, a slight in-depth diffusion of P was observed (see Fig. 2b). This diffusion leads to the formation of a box-shaped profile of P within the doped layer.
In summary, a very high n-type doping level of 2.2 × 1020 cm−3 was achieved in Ge by a combination of ion implantation and r-FLA. In contrast to f-FLA, the implanted Ge layer is single crystalline and practically free of defects after r-FLA. In this case the diffusion of P and the snow plough effect for implanted elements is mainly suppressed. In addition, the plasma frequency can be tuned up to 1,850 cm−1 (5,400 nm). The details of the complex crystallization mechanism, especially the balance between the recrystallization speed via solid phase epitaxy and the incubation time followed by nucleation, is still under discussion.
The (100) oriented undoped Ge wafers with a thickness of 300 μm were implanted with P ions with an energy of 60 keV and to a maximum concentration of 6 × 1020 cm−3. The amorphous layer formed during ion implantation is about 200 nm thick. After ion implantation Ge wafers were annealed by front-side FLA (f-FLA) for 3 ms with an energy density up to 61.5 J/cm2 which corresponds to a maximum surface temperature of about 700 °C. The same FLA system was used for rear-side annealing. The maximum flash energy was also in the range of 61.5 J/cm2 but prior to r-FLA samples were preheated at 180 °C for 30 s. The vertical temperature distribution within the sample during front and rear side annealing was simulated using in-house software. The detailed description of the model used to simulate the temperature distribution in flashed samples can be found in refs 44,45. Figure 7 shows the corresponding surface temperature within the implanted layer as a function of time. P concentration versus depth profiles were measured by secondary ion mass spectrometry (SIMS) employing a Cameca IMS7f micro-analyzer. A beam of 15 keV Cs+ ions was rastered over a surface area of 200 × 200 μm2 and secondary ions were collected from the central part of the sputtered crater. Crater depths were measured with a Dektak 8 stylus profilometer and a constant erosion rate was assumed when converting sputtering time to sample depth. Calibration of the P signal was performed using the as-implanted sample as reference.
The crystallization process of the P implanted and annealed samples were studied using Rutherford backscattering-channelling spectrometry (RBS/C). The RBS/C measurements were performed on the samples before and after annealing using the 1.7 MeV He+ beam of the Rossendorf van de Graff accelerator.
Electrical and optical characterization
The conductivity type and carrier concentration of P implanted samples were determined by Hall Effect measurements using a commercial Lakeshore Hall System with the van der Pauw geometry. Samples were measured in the temperature range from 2 to 300 K with a superconducting magnet. Gold electrodes were sputtered onto the four corners of the square-like samples. The sputtering process also removed the native GeOx layer to some extent. Silver glue was used to contact the wires to the gold electrodes. All contacts are confirmed to be ohmic measuring current-voltage curves at different temperatures. The optical properties were investigated by μ-Raman spectroscopy, ellipsometry and Fourier transform infrared spectroscopy in the near and mid-infrared spectral range. The phonon spectra were determined by micro-Raman spectroscopy in backscattering geometry in the range of 100 to 600 cm−1 using a 532 nm Nd:YAG laser with a liquid-nitrogen cooled charge coupled device camera. For the ellipsometry measurements a rotating analyser ellipsometer VASE system (J. A.Woollam Co., Inc., USA) operating at an energy range of 1 to 4 eV was used. The FTIR measurements were performed at RT using a Bruker Vertex 80v FT-IR system. The simulation of the dielectric function was performed with a multilayer model based on transfer matrix method.
How to cite this article: Prucnal, S. et al. Ultra-doped n-type germanium thin films for sensing in the mid-infrared. Sci. Rep. 6, 27643; doi: 10.1038/srep27643 (2016).
Chaisakul, P. et al. Integrated germanium optical interconnects on silicon substrates. Nature Photon 8, 482–488 (2014).
Chau, R., Doyle, B., Datta, S., Kavalieros, J. & Zhang, K. Integrated nanoelectronics for the future. Nature Mater. 6, 810–812 (2007).
Claeys, C. & Simoen, E. Germanium-Based Technologies: From Materials to Devices. Amsterdam (2007).
Kamata, Y. High-k/Ge MOSFETs for future nanoelectronics. Mater. Today 11, 30–38 (2008).
Steglich, M. et al. Ge-on-Si photodiode with black silicon boosted responsivity. Appl. Phys. Lett. 107, 051103, 10.1063/1.4927836 (2015).
von Borany, J. et al. The formation of narrow nanocluster bands in Ge-implanted SiO2-layers. Solid-St. Electron. 43, 1159–1163 (1999).
Takeuchi, W. et al. High hole mobility tin-doped polycrystalline germanium layers formed on insulating substrates by low-temperature solid-phase crystallization. Appl. Phys. Lett. 107, 022103, 10.1063/1.4926507 (2015).
Chakraborty, P. S. et al. A 0.8 THz fmax SiGe HBT Operating at 4.3 K. IEEE Electron Device Letters 35, 151–153 (2014).
Soref, R., Hendrickson, J. & Cleary, J. W. Mid- to long-wavelength infrared plasmonic-photonics using heavily doped n-Ge/Ge and n-GeSn/GeSn heterostructures. Opt. Express 20, 3814–3824 (2012).
Baldassarre, L. et al. Midinfrared Plasmon-Enhanced Spectroscopy with Germanium Antennas on Silicon Substrate. Nano Lett. 15, 7225–7231 (2015).
Nedeljkovic, M., Soref, R. & Mashanovich, G. Z. Predictions of Free-Carrier Electroabsorption and Electrorefraction in Germanium. IEEE Photon. J. 7, 2600214, 10.1109/JPHOT.2015.2419217 (2015).
Stanley, R. Plasmonics in the mid-infrared. Nature Photon 6, 409–411 (2012).
Soref, R. Mid-infrared photonics in silicon and germanium. Nature Photon 4, 495–497 (2010).
Sun, X., Liu, J., Kimerling, L. C. & Michel, J. Room-temperature direct bandgap electroluminesence from Ge-on-Si light-emitting diodes. Opt. Lett. 34, 1198–1200 (2009).
Camacho-Aguilera, R., Han, Z., Cai, Y., Kimerling, L. C. & Michel J. Direct band gap narrowing in highly doped Ge. Appl. Phys. Lett. 102, 152106, 10.1063/1.4802199 (2013).
Goley, P. S. & Hudait, M. K. Germanium Based Field-Effect Transistors: Challenges and Opportunities. Materials 7, 2301–2339 (2014).
Impellizzeri, G. et al. Fluorine effect on As diffusion in Ge. J. Appl. Phys. 109, 113527, 10.1063/1.3592962 (2011).
Weber, J. R., Janotti, A. & Van de Walle, C. G. Dangling bonds and vacancies in germanium. Phys. Rev. B 87, 035203, 10.1103/PhysRevB.87.035203 (2013).
Mattoni, G., Klesse, W. M., Capellini, G., Simmons, M. Y. & Scappucci, G. Phosphorus Molecules on Ge(001): A Playground for Controlled n-Doping of Germanium at High Densities. ACS Nano 7, 11310–11316 (2013).
Scappucci, G. et al. R. Bottom-up assembly of metallic germanium. Sci. Rep. 5, 12948, 10.1038/srep12948 (2015).
Scappucci,G., Capellini, G., Klesse, W. M. & Simmons, M. Y. New avenues to an old material: controlled nanoscale doping of germanium. Nanoscale 5, 2600–2615 (2013).
Posselt, M. et al. P implantation into preamorphized germanium and subsequent annealing: Solid phase epitaxial regrowth, P diffusion and activation. J. Vac. Sci. Technol. B 26, 430–434 (2008).
Wündisch, C. et al. Millisecond flash lamp annealing of shallow implanted layers in Ge. Appl. Phys. Lett. 95, 252107, 10.1063/1.3276770 (2009).
Heera, V. et al. Heavily Ga-doped germanium layers produced by ion implantation and flash lamp annealing: Structure and electrical activation. J. Appl. Phys. 107, 053508, 10.1063/1.3309835 (2010).
Cai, Y., Camacho-Aguilera, R., Bessette, J. T., Kimerling, L. C. & Michel, J. High phosphorous doped germanium: Dopant diffusion and modelling. J. Appl. Phys. 112, 034509, 10.1063/1.4745020 (2012).
Luong, T. K. P. et al. Molecular-beam epitaxial growth of tensile-strained and n-doped Ge/Si(001) films using a GaP decomposition source. Thin Solid Films 557, 70–75 (2014).
Capellini, G., Klesse, W. M., Mattoni, G., Simmons, M. Y. & Scappucci, G. Alternative High n-Type Doping Techniques in Germanium. ECS Transactions 64, 163–171 (2014).
Kim, J., Bedell, S. W. & Sadana, D. K. Multiple implantation and multiple annealing of phosphorus doped germanium to achieve n-type activation near the theoretical limit. Appl. Phys. Lett. 101, 112107, 10.1063/1.4751845 (2012).
Doolittle, L. R. Algorithms for the rapid simulation of Rutherford backscattering spectra. Nucl. Instrum. Methods Phys. Res. B 9, 344–351 (1985).
Olesinski, R., Kanani, N. & Abbaschian, G. The Ge–P (germanium-phosphorus) system. J. Phase Equilibria 6, 262–266 (1985).
Gao, K. et al. Ge1−xSnx alloys synthesized by ion implantation and pulsed laser melting. Appl. Phys. Lett. 105, 042107, 10.1063/1.4891848 (2014).
Viña, L. & Cardona, M. Effect of heavy doping on the optical properties and the band structure of silicon. Phys. Rev. B 29, 6739–6751 (1984).
Johnson, B. C., Gortmaker, P. & McCallum, J. C. Intrinsic and dopant-enhanced solid-phase epitaxy in amorphous germanium. Phys. Rev. B 77, 214109, 10.1103/PhysRevB.77.214109 (2008).
Germain, P., Zellama, K., Squelard, S., Bourgoin, J. C. & Gheorghiu, A. Crystallization in amorphous germanium. J. Appl. Phys. 50, 6986–6994 (1979).
Edelman, F., Komem, Y., Bendayan, M. & Beserman, R. Initial crystallization stage of amorphous germanium films. J. Appl. Phys. 72, 5153–5157 (1992).
Marine, W. & Marfaing, J. Solid state nucleation rate of Si and Ge near melting point. Phase Transitions 31, 299–308 (1991).
Blum, N. A. & Feldman, C. The crystallization of amorphous germanium films. J. Non-Cryst. Solids 22, 29–35 (1976).
Nikolova, L. et al. Nanocrystallization of amorphous germanium films observed with nanosecond temporal resolution. Appl. Phys. Lett. 97, 203102, 10.1063/1.3518069 (2010).
Posselt M. & Gabriel, A. Atomistic simulation of amorphous germanium and its solid phase epitaxial recrystallization. Phys. Rev. B 80, 045202, 10.1103/PhysRevB.80.045202 (2009).
Nikolova, L. et al. Complex crystallization dynamics in amorphous germanium observed with dynamic transmission electron microscopy. Phys. Rev. B 87, 064105, 10.1103/PhysRevB.87.064105 (2013).
Baeri, P., Campisano, S. U., Foti, G. & Rimini, E. Segregation Effects in Cu-Implanted Si after Laser-Pulse Melting. Phys. Rev. Lett. 41, 1246–1249 (1978).
Wittmer, M., Ting, C.‐Y., Ohdomari, I. & Tu, K. N. Redistribution of As during Pd2Si formation: Ion channeling measurements. J. Appl. Phys. 53, 6781–6787 (1982).
Zhou, S. et al. Hyperdoping silicon with selenium: solid vs. liquid phase epitaxy. Sci. Rep. 5, 8329, 10.1038/srep08329 (2015).
Skorupa, W. et al. Advanced Thermal Processing of Ultrashallow Implanted Junctions Using Flash Lamp Annealing. J. Electrochem. Soc. 152, G436–G440 (2005).
Smith, M., McMahon, R. A., Voelskow, M. & Skorupa, W. Modeling and regrowth mechanisms of flash lamp processing of SiC-on-silicon heterostructures. J. Appl. Phys. 96, 4843–4851 (2004).
We would like to thank I. Skorupa for the ellipsometry measurements and support by the Ion Beam Center (IBC) at HZDR is gratefully acknowledged.
The authors declare no competing financial interests.
About this article
Cite this article
Prucnal, S., Liu, F., Voelskow, M. et al. Ultra-doped n-type germanium thin films for sensing in the mid-infrared. Sci Rep 6, 27643 (2016). https://doi.org/10.1038/srep27643
Journal of Materials Science (2021)
Monte Carlo Study of Si, Ge, and In<sub>0.53</sub>Ga<sub>0.47</sub>As n-Channel FinFET Scaling: Channel Orientation, Quantum Confinement, Doping, and Contacts
IEEE Nanotechnology Magazine (2020)
New Journal of Physics (2020)