Unmanageable Defects in Proton- Irradiated Silicon: a Factual Outlook for Positron Probing N. Yu. Arutyunov 1,2, M. Elsayed 1, R.

Unmanageable Defects in Proton- Irradiated Silicon: a Factual Outlook for Positron Probing N. Yu. Arutyunov 1,2, M. Elsayed 1, R. Krause-Rehberg 1 1 Department of Physics, Martin Luther University, 06120 Halle, Germany 2 Institute of Electronics, Tashkent 700170, Uzbekistan V.V. Emtsev 3,G.A. Oganesyan 3,V.V. Kozlovski 4 3 Ioffe Physico-Technical Institute, St. Petersburg 194021, Russia 4 St. Petersburg Polytechnic University,St. Petersburg 195251, Russia Authors are thankful to German Academic Exchange Service (DAAD) for support Recent papers: Solid State Phenomena, 205 206 (2013) 317 J. Phys.: Condens. Matter, 25 (2013) 035801 AIP Conf. Proc. 1583 (2014) 41

Material(i) and Motivation(ii) Silicon Crystal Grown by the Floating-Zone Technique Proton irradiation (MeV energies) is effective way of modifying properties of semiconductors (i) Initial material : Oxygen [O] 10 16 cm -3, carbon lean [C i ] 10 15 cm -3 n-fz-si Moderately doped silicon n-fz-si([p]=7 10 15 cm -3 ) is of special interest owing to its wide use in various applications Knowledge about the radiation hardness of Si is indispensable (ii) Reliable data on RD created in silicon of n-type is scarce. Which defects are produced in this material of silicon under irradiation with 15 MeV protons at RT? Recent data: unmanageable thermally stable electrically neutral (or even electricaly inactive) point defects were revealed Arutyunov et al.,solid State Phenomena, 178 179 (2011) 313 Emtsev et al. Fiz. Tekh. Poluprov. 46 (2012) 473 We are to discuss possible configuration of these defects in silicon

Characterization: Hall s measurements and removal of carriers from conduction band of silicon n-fz-si([p]) irradiated with 15 MeV Protons Electron concentration (cm -3 ) 10 16 10 15 10 14 10 13 10 12 10 11 10 10 Protons 15 MeV D=3x10 13 cm -2 = 300K n-fz-si([p])= =7x10 15 cm -3 Level of [P] E c - 43 mev Initial 0 10 20 30 40 50 1000/T (K -1 ) 2 1 High-temperature region 1000/T 15: N d N a f{n(1/t)} const. Low-temperature exponential impurity ionization region region 1000/T 15: N d /N a φ{n(1/t)} (degree of compensation) This system of equation allows one to determine N d and N a separately and, thus, one can estimate the rate of introduction of donor and acceptor states Concentration of defects has been estimated using these data; Values have been applied for analysis of results obtained by PALS Removal rate of electrons: 110 120 cm -1 (15 MeV H + ) and 0,11 cm -1 (1 MeV electrons) tecnological advantage of H + beams

Temperature Dependency of e + Lifetime In Silicon n- FZ-Si([P]) Irradiated with 15 MeV Protons Average positron lifetime (ps) 250 240 230 220 n-fz-si([p=7x10 15 cm -3 ) Protons E = 15 MeV Shallow e + states Preserved at 340 C! τ av :254 ps 0 100 200 300 Measurement temperature (K) 1 1 - D=8x10 13 cm -2 2 - initial sample 2 τ av - strong T-dependency indicates effective positron-phonon interaction Value of e + lifetime suggests forming the defects of a vacancy type: τ av (100K) ~ 254 ps (Dose=8x10 13 cm 2 ) Shallow e + state (s): E st 0.2 0.6 mev (R.Krause-Rehberg and H.Leipner, 1999) We expected: isochronal annealing of E-centers and V 2 had to be completed at regular temperature 280 C 300 C τ av (T) had to decreases. We have found: T-dependency of τ av (T 85K) is observed in the course of annealing up to unexpectedly high temperature T ann. 500 C Arutyunov et. al J. Phys.: Condens. Matter, 25 (2013) 035801

1 st Stage: Annealing of E centers in Silicon n- FZ-Si([P]) Irradiated with 15 MeV Protons Average positron lifetime (ns) Electron concentration (cm -3 ) 0,245 0,240 0,235 0,230 0,225 0,220 0,215 2,4x10 15 D=8x10 13 cm -2 ; ~11% 2,2x10 15 2,0x10 15 1,8x10 15 1,6x10 15 Protons E = 15 MeV; ; T meas. =100K τ av - τ b ~21-23 ps Intial material 0 40 80 120 160 Annealing temperature ( o C ) Protons E = 15 MeV D=4x10 13 cm -2 Hall effect data τ av ~ 5 ps PALS 0.5-0.8x10 15 cm -3 60 80 100 120 140 160 Temperature of annealing ( O C ) E-centers: E b (0/-) E c 0.41 ev Negatively charged in investigated n-fz-si([p]) The annealing of E centers affects average positron lifetime insignificantly ( 5 ps) Electrons return to conduction band: concentration changes by (0.5 0.8) 10 15 cm 3 ( ~11%) Arutyunov et. al J. Phys.: Condens. Matter, 25 (2013) 035801

2 nd Stage: Annealing of Divacancies in n-fz- Si([P]) Irradiated with 15 MeV Protons Average positron lifetime (ns) Electron concentration (cm -3 ) 0,248 0,244 0,240 0,236 0,232 0,228 0,224 0,220 0,216 4,5x10 15 4,0x10 15 3,5x10 15 3,0x10 15 2,5x10 15 Protons E = 15 MeV D=4x10 13 cm -2 ; Thermally stable centers of a vacancy type Intial material PALS T meas. = 100K τ av - τ b ~14 ps 180 200 220 240 260 280 Temperature of annealing ( o C ) Protons E = 15 MeV D=8x10 13 cm -2 ; Hall effect data ~(0.8 1.5)x10 15 cm -3, ~15-20%) 180 200 220 240 260 280 Temperature of annealing ( O C ) Divacancy: E b (-/--) E c 0.23 ev E b (0/-) E c 0.41 ev Negatively charged in investigated n-fz- Si([P]){D=4 10 13 cm 2 }: ~70% of V 2 and ~30% of V 2 of total population For D=8 10 13 cm 2 : ~50% of V 2 and ~50% V 2 At 280 ºC average positron lifetime is by ~ 14 ps larger than the value characteristic of non-irradiated silicon This fact indicates thermally stable centers of a vacancy type (E-centers, V 2 were eliminated from the sample at 1 st and 2 nd stages of isochronal annealing ) Electron concentration changes by (0.8 1.5) 10 15 cm 3 (>15-20%) Arutyunov et. al J. Phys.: Condens. Matter, 25 (2013) 035801

3 rd Stage: Annealing of Thermally Stable Centers in Si of n-type Irradiated with 15 MeV Protons Average positron lifetime (ns) Protons E=15 MeV 0,252 0,246 0,240 0,234 0,228 0,222 0,216 D=8x10 13 cm -2 D=4x10 13 cm -2 Intial Si, ~ τ bulk T meas. = 100 K Phosphorusvacancy complexes 250 300 350 400 450 500 Temperature of anneling ( o C ) Data of measurements of Hall effect indcate that: centers include atoms of phosphorus centers are electrically neutral (or electrically inactive). They are deep donors having levels E DD >E c - 0.24 ev Positron annihilation data indicate that: deep donors are hidden at 1 st and 2 nd stages of the isochron. annealing deep donor has an open volume and it is a phosphorus-vacancy complex deep donor attracts e + effectively the annealing of deep donors results in restoring average positron lifetime: (from 232-236 ps to 216 217 ps,by ~20 ps), T ann = 280 ºC to ~ 500 ºC Arutyunov et. al J. Phys.: Condens. Matter, 25 (2013) 035801

Number of Vacancies In Phosphorus-Vacancy Complex Silicon of n-type irradiated 15 MeV protons Positron Lifetime, τ 340 320 300 280 260 240 220 Protons E = 15 MeV T ann. = 300 o C T meas. = 100 K τ 2 (I 2 ~58%) τ 2 (I 2 ~20%) τ av (D=8x10 13 cm -2 ) τ av (D=4x10 13 cm -2 ) τ bulk 0 1 2 3 Number of vacancies in cluste Horizontal lines: this work, two doses Long positron lifetime τ 2 is close to numbers of vacancies from 1 to 2 (elipsoid includes the results of calculations obtained by different authors) calc., Hakala et. al, PRB, 57 (1998) 7621; Line-and-squares (unrelaxed cluster): calc., Staab et. al, PRB 65 (2002) 115210; Line-and-dots (unrelaxed cluster): Kuriplach et al., PRB 58 (1998) 10475; Inward relaxation: big open square Makhov et al., PRL 92 (2004) 255504; Inward relaxation big dot Staab PRB 65 (2002) 115210; Inward relaxation big square Vacancy-phosphotrus complex (deep donor) includes, at least, 2 vacancies Arutyunov et. al J. Phys.: Condens. Matter 28 (2013) 035801; Solid State Phenomena 205 206 (2013) 317

Entropy S m and Activation Energy E a of Annealing Of Deep Donors Of Radiation Origin In Silicon of n-type Irradiated With 15 MeV Protons ln[(k i - k i+1 )/k i+1 ] (arb. units) -0,5-1,0-1,5 T meas =115 K 2,5 2,0 1,5 1,0 0,5 0,0 D=4x10 13 cm -2 Isohron. Anneal. n-fz-si [P]=7x10 15 cm -3 15 MeV Protons, =300 K E a ~ 1.05(0.21) ev 0,0014 0,0016 0,0018 T anneal. -1 (K -1 ) ln[ i + 1 i + 1 ] Equation of kinetics of chemical reaction k i k k A + E K K 0 S m 2 A ln ln[exp( ) 4πr0 N d (0.5 a ) ν 0 ] α K B E a 1.05(0.21) ev S m 2 3k B, D=4 10 13 cm -2 Similar value E a ~ 1 ev was found for neutral V 2 (EPR, Watkins 1964 138 A543) The value of configurational entropy S m indicates decomposition of point (not a large-scale ) defect of a vacancy type. Annealing 1 st order of reaction γ=1 Interval of annealing 320-460 o C: (ν 0 10 13 s -1 ) B a T i ϕ ( T ) = γ ln C 0 ln( dk / dt ) = A + E / k a a a B T a N deep donors const k = λ λ λ av 0 0 = λ 0 λ d λ av I 1 d I d Arutyunov et al., Solid State Phenomena, 205 206 (2013) 317; ibid. 178 179 (2011) 313

Formal configuration of deep donor center detected in silicon of n-type {n-fz-si ([P])} irradiated with protons 15 MeV VPV Two vacancies (dashed circles) are in close proximity to atom of phosphorus P. Nearest atoms of Si participate in closing bonds. The 5 th electron of P atom is on the deep donor level: VPV Decomposition of deep donor center restores impurity atom of phosphorus as a shallow donor in Si: 1 e per 1 centre (Hall effect data) Relaxation is not shown, red arrows show possible shift of the atoms of Si, green arrow shows the shift of vacancy towards the atom of phosphorus P Configuration of 2 semi-vacancies tied to P- impurity atom was considered for the E-center (Tolpygo et al. 1973 Sov. Phys. Solid. State 15 740); semi-vacancy pair was discussed by Masters (1973 Sol. St. Comm. 9 283)

Conclusion Deep donors of radiation origin have been revealed in silicon of n-type conductivity (n-fz-si([p]) irradiated with 15 MeV protons) Being thermally stable they are hidden at early stages of isochronal annealing whereas E- centers and divacancies disappear. e + lifetime ~ 280 300 ps E a 0.84 1.26 ev S m 2 3kB --------------------------- Sol. St. Phenom. (2013): Phonon-assisted trapping of e +, cross-section obeys to ~T 3 law σ+ 3 10 12 cm 2 (66K) 2 10 13 cm 2 (266 K) Data obtained by PALS spectroscopy: Configuration of deep donor consists of 2 vacancies and one atom of phosphorus Anealing of deep donors ranges temperatures from ~320 C to 700 C Ab intio calculations are needed (to shed the light on details of configuration of this defect)