Siegfried Segers scite author profile

Reactive magnetron sputtering is a widely used deposition technique in different application areas. In this study its use is evaluated for the deposition of metal thin films (Al, Cu and Ti) and oxide thin films (Al2O3, TiOx) on woven and nonwoven substrates. The study shows that good adhesion can only be achieved when the substrate is pre-treated in a glow discharge. The influence of the substrate on the reflectivity of Al and Cu thin films was investigated. For conductive textile applications, the resistivity of metal thin films and TiOx was investigated.

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Direct estimation of capture cross sections in the presence of slow capture: application to the identification of quenched-in deep-level defects in Ge

Segers¹,

Lauwaert²,

Clauws³

et al. 2014

Semicond. Sci. Technol.

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Quenching experiments have been performed on both n-and p-type Ge in a dedicated furnace using infrared lamp heating. The capture and emission characteristics of the induced deep-level defects in the quenched samples were investigated by means of Deep Level Transient Spectroscopy. For all defect levels, a high impact of capture in the transition region (slow capture) was found. An empirical approach to analyse this effect is presented, which allows to extract reliable capture crosssection parameters. The defect parameters thus obtained were compared with previously published data and it was found that some prominent quenching-induced deep levels are related to metal impurities (Cu and Ni), while others may be vacancy-related.

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Temperature-independent slow carrier emission from deep-level defects in p-type germanium

Segers¹,

Lauwaert²,

Clauws³

et al. 2013

J. Phys. D: Appl. Phys.

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Abstract. In the deep-level transient spectroscopy (DLTS) spectra of the 3d-transition metals cobalt and chromium in p-type germanium, evidence is obtained that hole emission from defect levels can occur by two parallel paths. Besides classical thermal emission, we observed a second, slower and temperature-independent emission. We show that this extra emission component allows to determine unambiguously whether or not multiple DLTS peaks arise from the same defect. Despite similar characteristics, we demonstrate that the origin of the non-thermal emission is not tunneling but photoionization related to black body radiation from an insufficiently shielded part of the cryostat.

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Electronic properties of manganese impurities in germanium

Lauwaert

Segers

Moens

et al. 2015

J. Phys. D: Appl. Phys.

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The electronic properties of manganese in crystalline germanium have been investigated by means of deep level transient spectroscopy (DLTS). Mn was diffused in the material by a thermal treatment at 700 • C. Next to the deep levels of nickel and copper, which are known contaminants in Ge treated at high temperature, three not previously reported levels were observed. These two hole and one electron traps, with apparent energy level positions at E V + 0.136eV, E V + 0.342eV and E C −0.363eV, were assigned to substitutional Mn. The analysis of the carrier capture cross-sections, the absence of field-assisted emission and the observation of the Mn 2− electron paramagnetic resonance spectrum in n-type Ge:Mn at low temperature are all compatible with Mn introducing two acceptor and one donor levels in the band gap of Ge.

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Mn Related Defect Levels in Germanium

Lauwaert¹,

Moens²,

Segers³

et al. 2014

Meet. Abstr.

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1. Introduction. Mn doped germanium was studied almost 60 years ago by means of Hall effect [1] and photo conductivity [2] measurements. Based on the temperature dependence of the resistivity and carrier concentration, two levels, one at 0.37eV from the conduction band and one at 0.16eV from the valence band have been assigned to Mn impurities[1]. In agreement with the valence bond model and similar observations by counterdoping with donors for Fe, Co and Ni, these impurities have been assigned to double acceptors. Moreover, the presence of a double acceptor level was confirmed by the observation of the Mn2- state with Electron Paramagnetic Resonance (EPR). [3] However it was also noted in the early studies that the presence of contamination with acceptor impurities may cast doubt on the charge transition assignment. Since the availability of Deep Level Transient Spectroscopy (DLTS), which is a more reliable technique to study deep levels in semiconductors, the electronic properties of most of the 3d transition metals have already been studied with a higher energy resolution. Metal in-diffusion was successful to introduce Cu and Ni[4]. More recently the defect levels of Ti, Cr, Fe and Co have been identified with DLTS on metal-implanted Ge [5,6]. The present study reports on results obtained on Mn doped Ge. 2. Experimental conditions. The source material are single crystal germanium wafers, supplied by Umicore, with a shallow dopant concentration of 1014 cm-3 Ga and Sb for p- and n-type, respectively. To introduce Mn impurities, 99.995% pure Mn was thermally evaporated on the Ge surface. Afterwards the specimens were placed in a resistive furnace under Ar atmosphere for 10 minutes at 700°C. Finally, the residual Mn on the surface was removed by etching with a mixture of HNO3 and HF (3:1?). Schottky diodes for DLTS were prepared by evaporation of Au (n-type) or In (p-type) barriers immediately after etching. To identify the contamination introduced during the processing, Schottky diodes were also prepared on parts of the specimens outside the Mn covered areas. Schottky diodes on n-Ge were also prepared by annealing the n-Ge:Mn samples (after indiffusion at 700°C) to 400°C for 20 min in order to form a MnGe metallic alloy contact. 3. Results and discussion. Fig. 1 a shows the DLTS spectrum of n-Ge:Mn with a MnGe Schottky contact. A similar spectrum was recorded on the specimen with an Au-Schottky barrier. Conventional DLTS shows one electron trap (Mn-E1), while injection of minority carriers (Vp>0) reveals two additional levels (Mn-H1 and Mn-H2). Fig. 1 b shows the DLTS spectrum of p-type Ge, with presence of Mn-H1 and Mn-H2 only after Mn diffusion. Figure 1: DLTS spectrum of a) n-Ge/MnGe diode. b) p-type Ge with and without Mn-difussion. The electron trap Mn-E1 (E=0.36eV) and the hole trap Mn-H1 (E=0.14eV) correspond with the two levels reported before [1,2]. The Mn-H2 peak (E=0.34eV) has to our knowledge not been reported before in the context of transition metal impurities. Nonetheless, its appearance only in Mn diffused samples, its almost equal amplitude and concentration profile to Mn-H1 suggests that it is also related to substitutional Mn in Ge. This may indicate that the substitutional Mn defect can adopt 4 charge states in Ge, one of which certainly corresponds with 2-, as identified with EPR. 4. Conclusions. Three Mn related defect levels have been identified with DLTS. The striking similarity with previously published results for two of the observed levels suggest the assignment to substitutional Mn in germanium. The third level was not reported before but can most probably also be assigned to Mn. References [1]H. H. Woodbury and W.W. Tyler, Phys. Rev., 100, p. 659 (1955). [2]R. Newman, H.H. Woodbury and W.W. Tyler, Phys. Rev., 102, p. 613 (1956). [3]G.D. Watkins, Bull. Am. Phys. Soc., 2, 235 (1957). [4]P. Clauws and E. Simoen Mater. Sci. Semicond. Process. 9,546 (2006) [5]J. Lauwaert, J. Van Gheluwe, J. Vanhellemont, E. Simoen and P. Clauws, J. Appl. Phys. 105, 073707 (2009) [6]J. Lauwaert, J. Vanhellemont, E. Simoen, H. Vrielinck and P. Clauws, J. Appl. Phys. 111, 113713 (2012)

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