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1. Formation of silicon nanocrystals in silicon carbide using flash lamp annealing

Author

Weiss, C., Schnabel, M., Prucnal, S., Hofmann, J., Reichert, A., Fehrenbach, T., Skorupa, W., and Janz, S.

Subjects
Physics - Applied Physics, Condensed Matter - Materials Science
Abstract

During the formation of Si nanocrystals (Si NC) in Si$_x$C$_{1-x}$ layers via solid-phase crystallization, the unintended formation of nanocrystalline SiC reduces the minority carrier lifetime and therefore the performance of Si$_x$C$_{1-x}$ as an absorber layer in solar cells. A significant reduction in the annealing time may suppress the crystallization of the SiC matrix while maintaining the formation of Si NC. In this study, we investigated the crystallization of stoichiometric SiC and Si-rich SiC using conventional rapid thermal annealing (RTA) and nonequilibrium millisecond range flash lamp annealing (FLA). The investigated Si$_x$C$_{1-x}$ films were prepared by plasma-enhanced chemical vapor deposition and annealed at temperatures from 700${\deg}$C to 1100${\deg}$C for RTA and at flash energies between 34 J/cm$^2$ and 62 J/cm$^2$ for FLA. GIXRD and FTIR were conducted to investigate hydrogen effusion, Si and SiC NC growth, and SiC crystallinity. Both the Si content and the choice of the annealing process affect the crystallization behavior. It is shown that under certain conditions, FLA can be successfully utilized for the formation of Si NC in a SiC matrix, which closely resembles Si NC in a SiC matrix achieved by RTA. The samples must have excess Si, and the flash energy should not exceed 40 J/cm$^2$ and 47 J/cm$^2$ for Si$_{0.63}$C$_{0.37}$ and Si$_{0.77}$C$_{0.23}$ samples, respectively. Under these conditions, FLA succeeds in producing Si NC of a given size in less crystalline SiC than RTA does. This result is discussed in terms of nucleation and crystal growth using classical crystallization theory. For FLA and RTA samples, an opposite relationship between NC size and Si content was observed and attributed either to the dependence of H effusion on Si content or to the optical absorption properties of the materials, which also depend on the Si content.

Published
2020
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2. Breaking the doping limit in silicon by deep impurities

Author

Wang, Mao, Debernardi, A., Berencén, Y., Heller, R., Xu, Chi, Yuan, Ye, Xie, Yufang, Böttger, R., Rebohle, L., Skorupa, W., Helm, M., Prucnal, S., and Zhou, Shengqiang

Subjects
Condensed Matter - Materials Science
Abstract

N-type doping in Si by shallow impurities, such as P, As and Sb, exhibits an intrinsic limit due to the Fermi-level pinning via defect complexes at high doping concentrations. Here we demonstrate that doping Si with the chalcogen Te by non-equilibrium processing, a deep double donor, can exceed this limit and yield higher electron concentrations. In contrast to shallow impurities, both the interstitial Te fraction decreases with increasing doping concentration and substitutional Te dimers become the dominant configuration as effective donors, leading to a non-saturating carrier concentration as well as to an insulator-to-metal transition. First-principle calculations reveal that the Te dimers possess the lowest formation energy and donate two electrons per dimer to the conduction band. These results provide novel insight into physics of deep impurities and lead to a possible solution for the ultra-high electron concentration needed in today's Si-based nanoelectronics., Comment: 26 pages, including the suppl information

Published
2018
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3. Extended Infrared Photoresponse in Te-Hyperdoped Si at Room Temperature

Author

Wang, Mao, Berencén, Y., García-Hemme, E., Prucnal, S., Hübner, R., Yuan, Ye, Xu, Chi, Rebohle, L., Böttger, R., Heller, R., Schneider, H., Skorupa, W., Helm, M., and Zhou, Shengqiang

Subjects
Condensed Matter - Materials Science
Abstract

Presently, silicon photonics requires photodetectors that are sensitive in a broad infrared range, can operate at room temperature, and are suitable for integration with the existing Si-technology process. Here, we demonstrate strong room-temperature sub-band-gap photoresponse of photodiodes based on Si hyperdoped with tellurium. The epitaxially recrystallized Te-hyperdoped Si layers are developed by ion implantation combined with pulsed-laser melting and incorporate Te-dopant concentrations several orders of magnitude above the solid solubility limit. With increasing Te concentration, the Te-hyperdoped layer changes from insulating to quasi-metallic behavior with a finite conductivity as the temperature tends to zero. The optical absorptance is found to increase monotonically with increasing Te concentration and extends well into the mid-infrared range. Temperature-dependent optoelectronic photoresponse unambiguously demonstrates that the extended infrared photoresponsivity from Te-hyperdoped Si p-n photodiodes is mediated by a Te intermediate band within the upper half of the Si band gap. This work contributes to pave the way toward establishing a Si-based broadband infrared photonic system operating at room temperature., Comment: 18 pages, 7 figures

Published
2018
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5. Realizing the insulator-to-metal transition in Se-hyperdoped Si via non-equilibrium material processing

Author

Liu, F., Prucnal, S., Berencén, Y., Zhang, Z., Yuan, Y., Liu, Y., Heller, R., Boettger, R., Rebohle, L., Skorupa, W., Helm, M., and Zhou, S.

Subjects
Condensed Matter - Materials Science
Abstract

We report on the insulator-to-metal transition in Se-hyperdoped Si layers driven by manipulating the Se concentration via non-equilibrium material processing, i.e. ion implantation followed by millisecond-flash lamp annealing. Electrical transport measurements reveal an increase of carrier concentration and conductivity with increasing Se concentration. For the semi-insulating sample with Se concentrations below the Mott limit, quantitative analysis of the temperature dependence of conductivity indicates a variable-range hopping mechanism with an exponent of s = 1/2 rather than 1/4, which implies a Coulomb gap at the Fermi level. The observed insulator-to-metal transition is attributed to the formation of an intermediate band in the Se-hyperdoped Si layers., Comment: 10 pages, 4 figures, accepted by J. Phys. D: Appl. Phys

Published
2017
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6. Suppressing the cellular breakdown in silicon supersaturated with titanium

Author

Liu, Fang, Prucnal, S, Hübner, R, Yuan, Ye, Skorupa, W, Helm, M, and Zhou, Shengqiang

Subjects
Condensed Matter - Materials Science
Abstract

Hyper doping Si with up to 6 at.% Ti in solid solution was performed by ion implantation followed by pulsed laser annealing and flash lamp annealing. In both cases, the implanted Si layer can be well recrystallized by liquid phase epitaxy and solid phase epitaxy, respectively. Cross-sectional transmission electron microscopy of Ti-implanted Si after liquid phase epitaxy shows the so-called growth interface breakdown or cellular breakdown owing to the occurrence of constitutional supercooling in the melt. The appearance of cellular breakdown prevents further recrystallization. However, the out-diffusion and cellular breakdown can be effectively suppressed by solid phase epitaxy during flash lamp annealing due to the high velocity of amorphous-crystalline interface and the low diffusion velocity for Ti in the solid phase., Comment: 10 pages, 4 figures

Published
2016
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7. Interaction between magnetic moments and itinerant carriers in d0 ferromagnetic SiC

Author

Liu, Y, Yuan, Y, Liu, F, Böttger, R, Anwand, W, Wang, Y, Semisalova, A, Ponomaryov, AN, Lu, X, N'Diaye, AT, Arenholz, E, Heera, V, Skorupa, W, Helm, M, and Zhou, S

Subjects
cond-mat.mtrl-sci
Abstract

Elucidating the interaction between magnetic moments and itinerant carriers is an important step to spintronic applications. Here, we investigate magnetic and transport properties in d0 ferromagnetic SiC single crystals prepared by postimplantation pulsed laser annealing. Magnetic moments are contributed by the p states of carbon atoms, but their magnetic circular dichroism is different from that in semi-insulating SiC samples. The anomalous Hall effect and negative magnetoresistance indicate the influence of d0 spin order on free carriers. The ferromagnetism is relatively weak in N-implanted SiC compared with that in Al-implanted SiC after annealing. The results suggest that d0 magnetic moments and itinerant carriers can interact with each other, which will facilitate the development of SiC spintronic devices with d0 ferromagnetism.

Published
2017

8. Extended infrared photoresponse in Te-hyperdoped Si at room temperature

Author

Wang, Mao, Berencén, Yonder, García Hemme, Eric, Prucnal, S., Hübner, R., Yuan, Ye, Xu, Chi, Rebohle, L., Böttger, R., Heller, R., Schneider, H., Skorupa, W., Helm, M., Zhou, Shengqiang, Wang, Mao, Berencén, Yonder, García Hemme, Eric, Prucnal, S., Hübner, R., Yuan, Ye, Xu, Chi, Rebohle, L., Böttger, R., Heller, R., Schneider, H., Skorupa, W., Helm, M., and Zhou, Shengqiang

Abstract

Presently, silicon photonics requires photodetectors that are sensitive in a broad infrared range, can operate at room temperature, and are suitable for integration with the existing Si-technology process. Here, we demonstrate strong room-temperature sub-band-gap photoresponse of photodiodes based on Si hyperdoped with tellurium. The epitaxially recrystallized Te-hyperdoped Si layers are developed by ion implantation combined with pulsed-laser melting and incorporate Te-dopant concentrations several orders of magnitude above the solid solubility limit. With increasing Te concentration, the Te-hyperdoped layer changes from insulating to quasi-metallic behavior with a finite conductivity as the temperature tends to zero. The optical absorptance is found to increase monotonically with increasing Te concentration and extends well into the mid-infrared range. Temperature-dependent optoelectronic photoresponse unambiguously demonstrates that the extended infrared photoresponsivity from Te-hyperdoped Si p-n photodiodes is mediated by a Te intermediate band within the upper half of the Si band gap. This work contributes to pave the way toward establishing a Si-based broadband infrared photonic system operating at room temperature., Ministerio de Economía y Competitividad (España), Structural Characterization Facilities at Ion Beam Center, Federal Ministry of Education & Research, Alexander von Humboldt Foundation, Helmholtz Association, China Scholarship Council, Depto. de Estructura de la Materia, Física Térmica y Electrónica, Fac. de Ciencias Físicas, TRUE, pub

Published
2024

9. Bandgap narrowing in Mn doped GaAs probed by room-temperature photoluminescence

Author

Prucnal, S., Gao, K., Skorupa, I., Rebohle, L., Vines, L., Schmidt, H., Khalid, M., Wang, Y., Weschke, E., Skorupa, W., Grenzer, J., Huebner, R., Helm, M., and Zhou, S.

Subjects
Condensed Matter - Materials Science
Abstract

The electronic band structure of the (Ga,Mn)As system has been one of the most intriguing problems in solid state physics over the past two decades. Determination of the band structure evolution with increasing Mn concentration is a key issue to understand the origin of ferromagnetism. Here we present room temperature photoluminescence and ellipsometry measurements of Ga_{100%-x}Mn_{x}As alloy. The up-shift of the valence-band is proven by the red shift of the room temperature near band gap emission from the Ga_{100%-x}Mn_{x}As alloy with increasing Mn content. It is shown that even a doping by 0.02 at.% of Mn affects the valence-band edge and it merges with the impurity band for a Mn concentration as low as 0.6 at.%. Both X-ray diffraction pattern and high resolution cross-sectional TEM images confirmed full recrystallization of the implanted layer and GaMnAs alloy formation., Comment: 24 pages, 7 figures, accepted at Phys. Rev. B 2015

Published
2015
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10. High Curie temperature and perpendicular magnetic anisotropy in homoepitaxial InMnAs films

Author

Yuan, Y., Wang, Y., Gao, K., Khalid, M., Wu, C., Zhang, W., Munnik, F., Weschke, E., Baehtz, C., Skorupa, W., Helm, M., and Zhou, S.

Subjects
Condensed Matter - Materials Science
Abstract

We have prepared the dilute magnetic semiconductor (DMS) InMnAs with different Mn concentrations by ion implantation and pulsed laser melting. The Curie temperature of the In1-xMnxAs epilayer depends on the Mn concentration x, reaching 82 K for x=0.105. The substitution of Mn ions at the Indium sites induces a compressive strain perpendicular to the InMnAs layer and a tensile strain along the in-plane direction. This gives rise to a large perpendicular magnetic anisotropy, which is often needed for the demonstration of electrical control of magnetization and for spin-transfer-torque induced magnetization reversal., Comment: 16 pages, 5 figures

Published
2015
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11. Hyperdoping silicon with selenium: solid vs. liquid phase epitaxy

Author

Zhou, S., Liu, F., Prucnal, S., Gao, K., Khalid, M., Baehtz, C., Posselt, M., Skorupa, W., and Helm, M.

Subjects
Condensed Matter - Materials Science
Abstract

Chalcogen-hyperdoped silicon shows potential applications in silicon-based infrared photodetectors and intermediate band solar cells. Due to the low solid solubility limits of chalcogen elements in silicon, these materials were previously realized by femtosecond or nanosecond laser annealing of implanted silicon or bare silicon in certain background gases. The high energy density deposited on the silicon surface leads to a liquid phase and the fast recrystallization velocity allows trapping of chalcogen into the silicon matrix. However, this method encounters the problem of surface segregation. In this paper, we propose a solid phase processing by flash-lamp annealing in the millisecond range, which is in between the conventional rapid thermal annealing and pulsed laser annealing. Flash lamp annealed selenium-implanted silicon shows a substitutional fraction of around 70% with an implanted concentration up to 2.3%. The resistivity is lower and the carrier mobility is higher than those of nanosecond pulsed laser annealed samples. Our results show that flash-lamp annealing is superior to laser annealing in preventing surface segregation and in allowing scalability., Comment: 19 pages, 7 figures, to be published at Scientific Reports

Published
2015
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12. A comprehensive study of the magnetic, structural and transport properties of the III-V ferromagnetic semiconductor InMnP

Author

Khalid, M., Gao, Kun, Weschke, E., Huebner, R., Baehtz, C., Gordan, O., Salvan, G., Zahn, D. R. T., Skorupa, W., Helm, M., and Zhou, Shengqiang

Subjects
Condensed Matter - Materials Science
Abstract

The manganese induced magnetic, electrical and structural modification in InMnP epilayers, prepared by Mn ion implantation and pulsed laser annealing, are investigated in the following work. All samples exhibit clear hysteresis loops and strong spin polarization at the Fermi level. The degree of magnetization, the Curie temperature and the spin polarization depend on the Mn concentration. The bright-field transmission electron micrographs show that InP samples become almost amorphous after Mn implantation but recrystallize after pulsed laser annealing. We did not observe an insulator-metal transition in InMnP up to a Mn concentration of 5 at./%. Instead all InMnP samples show insulating characteristics up to the lowest measured temperature. Magneotresistance results obtained at low temperatures support the hopping conduction mechanism in InMnP. We find that the Mn impurity band remains detached from the valence band in InMnP up to 5 at./% Mn doping. Our findings indicate that the local environment of Mn ions in InP is similar to GaMnAs, GaMnP and InMnAs, however, the electrical properties of these Mn implanted III-V compounds are different. This is one of the consequences of the different Mn binding energy in these compounds., Comment: 21 pages, 8 figures, to be published at J. Appl. Phys

Published
2015
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13. Ferromagnetism and impurity band in a new magnetic semiconductor: InMnP

Author

Khalid, M., Weschke, E., Skorupa, W., Helm, M., and Zhou, S.

Subjects
Condensed Matter - Materials Science
Abstract

We have synthesized ferromagnetic InMnP, a member of III-Mn-V ferromagnetic semiconductor family, by Mn ion implantation and pulsed laser annealing. Clear ferromagnetic hysteresis loops and a perpendicular magnetic anisotropy are observed up to a Curie temperature of 42 K. Large values of negative magnetoresistance and magnetic circular dichroism as well as anomalous Hall effect are further evidences of a ferromagnetic order in InMnP. An effort is made to understand the transport mechanism in InMnP using the theoretical models. We find that the valence band of InP does not merge with the impurity band of the heavily doped ferromagnetic InMnP. Our results suggest that impurity band conduction is a characteristic of Mn-doped III-V semiconductors which have deep Mn-acceptor levels., Comment: 12 pages, 5 figures

Published
2014
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14. Origin and enhancement of the 1.3 um luminescence from GaAs treated by ion-implantation and flash lamp annealing

Author

Gao, Kun, Prucnal, S., Skorupa, W., Helm, M., and Zhou, Shengqiang

Subjects
Condensed Matter - Materials Science
Abstract

GaAs and GaAs based materials have outstanding optoelectronic properties and are widely used as light emitting media in devices. Many approaches have been applied to GaAs to generate luminescence at 0.88, 1.30, 1.55 um which are transmission windows of optical fibers. In this paper we present the photoluminescence at 1.30 um from deep level defects in GaAs treated by ion-implantation and flash lamp annealing (FLA). Such emission, which exhibits superior temperature stability, can be obtained from FLA treated virgin GaAs as well as doped GaAs. Indium-doping in GaAs can greatly enhance the luminescence. By photoluminescence, Raman measurements, and positron annihilation spectroscopy, we conclude that the origin of the 1.30 um emission is from transitions between the VAs-donor and X-acceptor pairs., Comment: 24 pages, 6 figures

Published
2014
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15. Using x-ray diffraction to identify precipitates in transition metal doped semiconductors

Author

Zhou, Shengqiang, Potzger, K., Talut, G., von Borany, J., Skorupa, W., Helm, M., and Fassbender, J.

Subjects
Condensed Matter - Materials Science
Abstract

In the past decade, room temperature ferromagnetism was often observed in transition metal doped semiconductors, which were claimed as diluted magnetic semiconductors (DMS). Nowadays intensive activities are devoted to clarify wether the observed ferromagnetism stems from carrier mediated magnetic impurities, ferromagnetic precipitates, or spinodal decomposition. In this paper, we have correlated the structural and magnetic properties of transition metal doped ZnO, TiO2, and Si, prepared by ion implantation. Crystalline precipitates, i.e., transition metal (Co, Ni) and Mn-silicide nanocrystals, are responsible for the magnetism. Additionally due to their orientation nature with respect to the host, these nanocrystals in some cases are not detectable by conventional x-ray diffraction (XRD). This nature results in the pitfall of using XRD to exclude magnetic precipitates in DMS materials., Comment: 7 pages, 5 figures

Published
2013
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16. Crystallographically oriented Co and Ni nanocrystals inside ZnO formed by ion implantation and postannealing

Author

Zhou, Shengqiang, Potzger, K., von Borany, J., Groetzschel, R., Skorupa, W., Helm, M., and Fassbender, J.

Subjects
Condensed Matter - Materials Science
Abstract

In the last decade, transition-metal-doped ZnO has been intensively investigated as a route to room-temperature diluted magnetic semiconductors (DMSs). However, the origin for the reported ferromagnetism in ZnO-based DMS remains questionable. Possible options are diluted magnetic semiconductors, spinodal decomposition, or secondary phases. In order to clarify this question, we have performed a thorough characterization of the structural and magnetic properties of Co- and Ni-implanted ZnO single crystals. Our measurements reveal that Co or Ni nanocrystals (NCs) are the major contribution of the measured ferromagnetism. Already in the as-implanted samples, Co or Ni NCs have formed and they exhibit superparamagnetic properties. The Co or Ni NCs are crystallographically oriented with respect to the ZnO matrix. Their magnetic properties, e.g., the anisotropy and the superparamagnetic blocking temperature, can be tuned by annealing. We discuss the magnetic anisotropy of Ni NCs embedded in ZnO concerning the strain anisotropy., Comment: 13 pages, 14 figures

Published
2009
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17. Fe-implanted ZnO: Magnetic precipitates versus dilution

Author

Zhou, Shengqiang, Potzger, K., Talut, G., Reuther, H., von Borany, J., Groetzschel, R., Skorupa, W., Helm, M., Fassbender, J., Volbers, N., Lorenz, M., and Herrmannsdoerfer, T.

Subjects
Condensed Matter - Materials Science
Abstract

Nowadays ferromagnetism is often found in potential diluted magnetic semiconductor systems. However, many authors argue that the observed ferromagnetism stems from ferromagnetic precipitates or spinodal decomposition rather than from carrier mediated magnetic impurities, as required for a diluted magnetic semiconductor. In the present paper we answer this question for Fe-implanted ZnO single crystals comprehensively. Different implantation fluences and temperatures and post-implantation annealing temperatures have been chosen in order to evaluate the structural and magnetic properties over a wide range of parameters. Three different regimes with respect to the Fe concentration and the process temperature are found: 1) Disperse Fe$^{2+}$ and Fe$^{3+}$ at low Fe concentrations and low processing temperatures, 2) FeZn$_2$O$_4$ at very high processing temperatures and 3) an intermediate regime with a co-existence of metallic Fe (Fe$^0$) and ionic Fe (Fe$^{2+}$ and Fe$^{3+}$). Ferromagnetism is only observed in the latter two cases, where inverted ZnFe$_2$O$_4$ and $\alpha$-Fe nanocrystals are the origin of the observed ferromagnetic behavior, respectively. The ionic Fe in the last case could contribute to a carrier mediated coupling. However, their separation is too large to couple ferromagnetically due to the lack of p-type carrier. For comparison investigations of Fe-implanted epitaxial ZnO thin films are presented., Comment: 14 pages, 17 figures

Published
2009
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18. Ferromagnetic transition metal implanted ZnO: a diluted magnetic semiconductor?

Author

Zhou, Shengqiang, Potzger, K., Xu, Qingyu, Talut, G., Lorenz, M., Skorupa, W., Helm, M., Fassbender, J., Grundmann, M., and Schmidt, H.

Subjects
Condensed Matter - Materials Science
Abstract

Recently theoretical works predict that some semiconductors (e.g. ZnO) doped with magnetic ions are diluted magnetic semiconductors (DMS). In DMS magnetic ions substitute cation sites of the host semiconductor and are coupled by free carriers resulting in ferromagnetism. One of the main obstacles in creating DMS materials is the formation of secondary phases because of the solid-solubility limit of magnetic ions in semiconductor host. In our study transition metal ions were implanted into ZnO single crystals with the peak concentrations of 0.5-10 at.%. We established a correlation between structural and magnetic properties. By synchrotron radiation X-ray diffraction (XRD) secondary phases (Fe, Ni, Co and ferrite nanocrystals) were observed and have been identified as the source for ferromagnetism. Due to their different crystallographic orientation with respect to the host crystal these nanocrystals in some cases are very difficult to be detected by a simple Bragg-Brentano scan. This results in the pitfall of using XRD to exclude secondary phase formation in DMS materials. For comparison, the solubility of Co diluted in ZnO films ranges between 10 and 40 at.% using different growth conditions pulsed laser deposition. Such diluted, Co-doped ZnO films show paramagnetic behaviour. However, only the magnetoresistance of Co-doped ZnO films reveals possible s-d exchange interaction as compared to Co-implanted ZnO single crystals., Comment: 27 pages, 8 figures

Published
2009
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19. Structural and magnetic properties of Mn-implanted Si

Author

Zhou, Shengqiang, Potzger, K., Zhang, Gufei, Muecklich, A., Eichhorn, F., Schell, N., Groetzschel, R., Schmidt, B., Skorupa, W., Helm, M., Fassbender, J., and Geiger, D.

Subjects
Condensed Matter - Materials Science
Abstract

Structural and ferromagnetic properties in Mn implanted, p-type Si were investigated. High resolution structural analysis techniques like synchrotron X-ray diffraction revealed the formation of MnSi1.7 nanoparticles already in the as implanted samples. Depending on the Mn-fluence, the size increases from 5 nm to 20 nm upon rapid thermal annealing. No significant evidence is found for Mn substituting Si sites either in the as-implanted or annealed samples. The observed ferromagnetism yields a saturation moment of 0.21 mu_B per implanted Mn at 10 K, which could be assigned to MnSi1.7 nanoparticles as revealed by a temperature dependent magnetization measurement., Comment: 21 pages, 6 figures, accepted for publicaiton at Phys. Rev. B

Published
2006
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20. Crystallographically oriented magnetic ZnFe2O4 nanoparticles synthesized by Fe implantation into ZnO

Author

Zhou, Shengqiang, Potzger, K., Reuther, H., Talut, G., Eichhorn, F., von Borany, J., Skorupa, W., Helm, M., and Fassbender, J.

Subjects
Condensed Matter - Materials Science
Abstract

In this paper, a correlation between structural and magnetic properties of Fe implanted ZnO is presented. High fluence Fe^+ implantation into ZnO leads to the formation of superparamagnetic alpha-Fe nanoparticles. High vacuum annealing at 823 K results in the growth of alpha-Fe particles, but the annealing at 1073 K oxidized the majority of the Fe nanoparticles. After a long term annealing at 1073 K, crystallographically oriented ZnFe2O4 nanoparticles were formed inside ZnO with the orientation relationship of ZnFe2O4(111)[110]//ZnO(0001)[1120]. These ZnFe2O4 nanoparticles show a hysteretic behavior upon magnetization reversal at 5 K., Comment: 21 pages, 7 figures, accepted by J. Phys. D: Appl. Phys

Published
2006
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21. Absence of ferromagnetism in V-implanted ZnO single crystals

Author

Zhou, Shengqiang, Potzger, K., Reuther, H., Kuepper, K., Skorupa, W., Helm, M., and Fassbender, J.

Subjects
Condensed Matter - Materials Science
Abstract

The structural and magnetic properties of V doped ZnO are presented. V ions were introduced into hydrothermal ZnO single crystals by ion implantation with fluences of 1.2*10^16 to 6*10^16 cm^-2. Post-implantation annealing was performed in high vacuum from 823 K to 1023 K. The ZnO host material still partly remains in a crystalline state after irradiation, and is partly recovered by annealing. The V ions show a thermal mobility as revealed by depth profile Auger electron spectroscopy. Synchrotron radiation x-ray diffraction revealed no secondary phase formation which indicates the substitution of V onto Zn site. However in all samples no pronounced ferromagnetism was observed down to 5 K by a superconducting quantum interference device magnetometer., Comment: 13 pages, 4 figs, MMM conference 2007, accepted by J. Appl. Phys

Published
2006
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22. Crystalline Ni nanoparticles as the origin of ferromagnetism in Ni implanted ZnO crystals

Author

Zhou, Shengqiang, Potzger, K., Zhang, Gufei, Eichhorn, F., Skorupa, W., Helm, M., and Fassbender, J.

Subjects
Condensed Matter - Materials Science
Abstract

We report the structural and magnetic properties of ZnO single crystals implanted at 623 K with up to 10 at. % of Ni. As revealed by X-ray diffraction, crystalline fcc-Ni nanoparticles were formed inside ZnO. The magnetic behavior (magnetization with field reversal and with different temperature protocol) of all samples is well explained by a magnetic Ni-nanoparticle system. Although the formation of Ni:ZnO based diluted magnetic semiconductor cannot be ruled out, the major contribution to the magnetic properties stems from crystalline nanoparticles synthesized under these implantation conditions., Comment: 15 pages, 4 figures, to be published at J. Appl. Phys

Published
2006
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23. Fe implanted ferromagnetic ZnO

Author

Potzger, K., Zhou, Shengqiang, Reuther, H., Muecklich, A., Eichhorn, F., Schell, N., Skorupa, W., Helm, M., Fassbender, J., Herrmannsdoerfer, T., and Papageorgiou, T. P.

Subjects
Condensed Matter - Materials Science
Abstract

Room-temperature ferromagnetism has been induced within ZnO single crystals by implant-doping with Fe ions. For an implantation temperature of 620 K and an ion fluence of 4x10^16 cm^-2, very tiny Fe particles, formed inside the host matrix, are responsible for the ferromagnetic properties. They were identified using synchrotron X-ray diffraction and Moessbauer spectroscopy. On the other hand, Fe ions implanted at a temperature of 253 K and an ion fluence of 4x10^15 cm^-2 are incorporated into the host matrix and develop a room temperature diluted magnetic semiconductor (DMS)., Comment: 13 pages, 2 figs, to be published in Appl. Phys. Lett

Published
2005
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39. Deposition of silicon oxide films on silicon using HelixJet – an atmospheric-pressure plasma jet process below 100 °C

Author

(0000-0002-8066-6392) Rebohle, L., Quade, A., Schumann, T., Blaschke, D., Hübner, R., Heller, R., Foest, R., Schäfer, J., Skorupa, W., (0000-0002-8066-6392) Rebohle, L., Quade, A., Schumann, T., Blaschke, D., Hübner, R., Heller, R., Foest, R., Schäfer, J., and Skorupa, W.

Abstract

Silicon oxide films are widely applied for their superior dielectric, chemical and mechanic properties as well as for their resistance against reactive chemicals. Simultaneously, there is an increasing number of applications which demand a low deposition temperature. In this work, we compare the material properties of SiOx layers deposited at ca. 70°C by atmospheric-pressure plasma jet deposition (PA) with those of SiO2 layers thermally grown or deposited by plasma-enhanced chemical vapour deposition. The films were deposited on silicon wafers and analysed using different analysis techniques. According to cross-sectional transmission electron microscopy and high-frequency capacitance-voltage measurements, the interface between the PA oxide and the Si substrate is smooth with no apparent defects and displays an electrically active interface defect density between 3.5-8.0×1012 cm-2 directly after deposition and below 2.0×1012 cm-2 after furnace annealing. Right after deposition, the PA oxide contains carbon and hydrogen in a concentration of several at%, and the SiO2 plasma polymer network comprises several active centres (residual charge, free radicals, non-saturated bonds). The most abundant configuration is the Si(-O)4 tetrahedron, followed by Si(-O)3 with similar intensity. This indicates that there are still dangling Si bonds or bonds terminated by hydroxyl or methyl groups. After furnace annealing, the formation of the SiO2 network is completed and the optical and electrical properties of the PA oxide converge to that of thermal oxide.

Published
2022

44. Band gap renormalization in n-type GeSn alloys made by ion implantation and flash lamp annealing.

Author

Prucnal, S., Berencén, Y., Wang, M., Rebohle, L., Kudrawiec, R., Polak, M., Zviagin, V., Schmidt-Grund, R., Grundmann, M., Grenzer, J., Turek, M., Droździel, A., Pyszniak, K., Zuk, J., Helm, M., Skorupa, W., and Zhou, S.

Subjects
OPTOELECTRONIC devices, GERMANIUM alloys, TIN alloys, ION implantation, INCOHERENT light annealing
Abstract

The last missing piece of the puzzle for the full functionalization of group IV optoelectronic devices is a direct bandgap semiconductor made by CMOS compatible technology. Here, we report on the fabrication of GeSn alloys with Sn concentrations up to 4.5% using ion implantation followed by millisecond-range explosive solid phase epitaxy. The n-type single crystalline GeSn alloys are realized by co-implantation of Sn and P into Ge. Both the activation of P and the formation of GeSn are performed during a single-step flash lamp annealing for 3 ms. The bandgap engineering in GeSn as a function of the doping level and Sn concentration is theoretically predicted by density functional theory and experimentally verified using ellipsometric spectroscopy. We demonstrate that both the diffusion and the segregation of Sn and P atoms in Ge are fully suppressed by millisecond-range nonequilibrium thermal processing. [ABSTRACT FROM AUTHOR]

Published
2019
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