J.Vaitkus et al. PC spectra. CERN RD50 Workshop, Ljubljana, 2008.06.02-04 "Analysis of deep level system transformation by photoionization spectroscopy"

Slides:

Advertisements

Similar presentations

CHAPTER 4 CONDUCTION IN SEMICONDUCTORS

Advertisements

TCT study of silicon epitaxial and MCZ detectors V. Eremin 1, M. Boscardin 2, M. Bruzzi 3, D. Creanza 4, A. Macchiolo 5, D. Menichelli 3, C. Piemonte 2,

REACTIONS OF INTERSTITIAL CARBON WITH BACKGROUND IMPURITIES IN N- AND P-TYPE SILICON STRUCTURES L.F. Makarenko*, L.I. Murin**, M. Moll***, F.P. Korshunov**,

COST Action MP0805 Meeting, Istanbul, April 12-13, 2010 University of Nottingham, UK Effects of Hydrogen Irradiation on Deep Levels in MBE Grown Dilute.

Semiconductor Device Physics

William Cunningham Properties of SiC radiation detectors W. Cunningham a, J. Melone a, V.Kazukauskas b,c P. Roy a, F. Doherty a, M. Glaser d, J.Vaitkus.

Carrier Transport Phenomena

Lecture #8 OUTLINE Generation and recombination Excess carrier concentrations Minority carrier lifetime Read: Section 3.3.

Principle of operation and limits of application

EXAMPLE 3.1 OBJECTIVE Solution Comment

Wide Bandgap Semiconductor Detectors for Harsh Radiation Environments

EE415 VLSI Design The Devices: Diode [Adapted from Rabaey’s Digital Integrated Circuits, ©2002, J. Rabaey et al.]

FREE CARRIER ABSORPTION TECHNIQUES - MICROWAVE & IR –

1Ruđer Bošković Institute, Zagreb, Croatia

J.Vaitkus et al., WOEDAN Workshop, Vilnius, The steady and transient photoconductivity, and related phenomena in the neutron irradiated Si.

(Deep Level Transient Spectroscopy) II. Advanced Techniques

References Hans Kuzmany : Solid State Spectroscopy (Springer) Chap 5 S.M. Sze: Physics of semiconductor devices (Wiley) Chap 13 PHOTODETECTORS Detection.

Potential vs. Kinetic Energy

Techniques for determination of deep level trap parameters in irradiated silicon detectors AUTHOR: Irena Dolenc ADVISOR: prof. dr. Vladimir Cindro.

Charge Carrier Related Nonlinearities

TIM GFROERER, Davidson College Davidson, NC USA

KINETICS OF INTERSTITIAL CARBON ANNEALING AND MONITORING OF OXYGEN DISTRIBUTION IN SILICON PARTICLE DETECTORS L.F. Makarenko*, M. Moll**, F.P. Korshunov***,

The contribution from The contribution from photoluminescence (PL) Gordon Davies, King’s College London.

NEEP 541 Ionization in Semiconductors - II Fall 2002 Jake Blanchard.

22 October 2009FCAL workshop, Geneve1 Polarization effects in the radiation damaged scCVD Diamond detectors Sergej Schuwalow, DESY Zeuthen On behalf of.

M. Bruzzi et al. Thermal donors in MCz Si, Trento Meeting Rd50 February 28, 2005 Mara Bruzzi, D. Menichelli, M. Scaringella INFN Florence, University of.

Thermally Stimulated Currents Method Ioana Pintilie a) National Institute of Materials Physics, Bucharest-Magurele, P.O.Box MG-7, Romania b) Institute.

Fluence–dependent lifetime variations in neutron irradiated MCZ Si measured by microwave probed photoconductivity and dynamic grating techniques E.Gaubas,

Gunnar Lindstroem – University of Hamburg1 G. Lindstroem a, E. Fretwurst a, F. Hönniger a, A. Junkes a, K. Koch a and I. Pintilie a,b a Institute for Exp.

ENE 311 Lecture 9.

J.Vaitkus. WODEAN Workshop,13-15 May, 2010, Bucurest Photoresponse spectrum in differently irradiated and annealed Si Juozas Vaitkus Vilnius University,

J.Vaitkus et al. RD , Bari Deep levels roles in non-equilibrium conductivity in irradiated Si J. Vaitkus, A. Mekys, G. Mockevičius, J. Storasta,

References Hans Kuzmany : Solid State Spectroscopy (Springer) Chap 5 S.M. Sze Physics of semiconductor devices (Wiley) Chap 13 PHOTODETECTORS.

WODEAN, June-07 Some DLTS results…. J.H. Bleka et al. University of Oslo, Department of Physics, Physical Electronics, P.O Blindern, N-0316 Oslo,

D. Menichelli, RD50, Hamburg, august TSC, DLTS and transient analysis in MCz silicon Detectors at different process temperature, irradiation.

(Deep Level Transient Spectroscopy)

ECE 875: Electronic Devices Prof. Virginia Ayres Electrical & Computer Engineering Michigan State University

ECEE 302: Electronic Devices

Analysis of electron mobility dependence on electron and neutron irradiation in silicon J.V.VAITKUS, A.MEKYS, V.RUMBAUSKAS, J.STORASTA, Institute of Applied.

Luminescence basics Types of luminescence

Region of possible oscillations

Introduction to semiconductor technology. Outline –4 Excitation of semiconductors Optical absorption and excitation Luminescence Recombination Diffusion.

J.Vaitkus. RD50 Workshop, Liverool, May, 2011 Deep level system Gaussian approximation according the extrinsic photoconductivity in irradiated Si.

INTERSTITIAL DEFECT REACTIONS IN P-TYPE SILICON IRRADIATED AT DIFFERENT TEMPERATURES L.F. Makarenko*, S.B. Lastovski**, L.I. Murin**, M. Moll*** * Belarusian.

Photoluminescence and Photocurrent in a Blue LED Ben Stroup & Timothy Gfroerer, Davidson College, Davidson, NC Yong Zhang, University of North Carolina.

NEEP 541 Displacements in Silicon Fall 2002 Jake Blanchard.

Lecture 1 OUTLINE Semiconductors, Junction, Diode characteristics, Bipolar Transistors: characteristics, small signal low frequency h-parameter model,

Ioana Pintilie, Vilnius 2-6 june Defect investigation on MCz after 1 MeV neutron irradiation I. Pintilie 1, E. Fretwurst 2, A. Junkes 2 and G. Lindstroem.

J.Vaitkus IWORID6, Glasgow,

Solid State Detectors - Physics

Fluence dependent recombination lifetime in neutron and proton irradiated MCz, FZ and epi-Si structures E.Gaubas, J.Vaitkus, T.Čeponis, A.Uleckas, J.Raisanen,

Fluence and isochronal anneal dependent variations of recombination and DLTS characteristics in neutron and proton irradiated MCz, FZ and epi-Si structures.

J.Vaitkus, L.Makarenko et all. RD50, CERN, 2012 The free carrier transport properties in proton and neutron irradiated Si(Ge) (and comparison with Si)

Double Electric field Peak Simulation of Irradiated Detectors Using Silvaco Ashutosh Bhardwaj, Kirti Ranjan, Ranjeet Singh*, Ram K. Shivpuri Center for.

Excess Carriers in Semiconductors

Ioana Pintilie, 11 th RD50 Workshop, November 2007, Geneve

Institute of Applied Research, Vilnius University,

Remarks on the measurement of thermally stimulated current

16th RD 50 Workshop - Barcelona, 31 May - 2 June 2010

Degenerate Semiconductors

Lecture #8 OUTLINE Generation and recombination

Chapter 4 Excess Carriers in Semiconductors

Lecture #6 OUTLINE Carrier scattering mechanisms Drift current

Diatomic molecules

Basic Semiconductor Physics

Semiconductor Device Physics

Review of semiconductor physics

Lecture 5 OUTLINE Semiconductor Fundamentals (cont’d)

The WODEAN project – outline and present status

ELECTRICAL PROPERTIES

Presentation transcript:

J.Vaitkus et al. PC spectra. CERN RD50 Workshop, Ljubljana, "Analysis of deep level system transformation by photoionization spectroscopy" J.Vaitkus, E.Gaubas, V.Kalendra, V.Kazukauskas (Vilnius University)

J.Vaitkus et al. PC spectra. CERN RD50 Workshop, Ljubljana, Outline: I.The photoconductivity specral response method possibilities II.The peculiarities of the samples; III.The results of analyze of the deep levels parameters in the differently irradiated and treated samples IV.Conclusions.

J.Vaitkus et al. PC spectra. CERN RD50 Workshop, Ljubljana, The main features of the extrinsic photoconductivity spectrum: Positive (or specific): It depends: – on the photon capture cross-section dependence on the photon energy & on the deep level concentration The deep level photo-activation energy is bigger than the thermal activation. It is a supplementary method to the extrinsic luminescence, DLTS & TSC methods for the defect identification.

J.Vaitkus et al. PC spectra. CERN RD50 Workshop, Ljubljana, Traps and recombination centers: deep centre model Temperature dependencies of conductivity, DLTS, thermally stimulated conductivity allows to measure  E T,  E σ Photoconductivity spectra -  E Opt Luminescence spectra:  E lum The shape of spectral dependence of photo-ionization depends on electron-phonon coupling, but at low T this effect can be neglected, i.e. Luckovsky model can be used. (We perform K)

J.Vaitkus et al. PC spectra. CERN RD50 Workshop, Ljubljana, Lukovsky (  - potential ) model: I ~ m x  E M 0,5 (h -  E M ) 1,5 /(h )^ 3 ) This model (at low temperatures) does not valid: for the hydrogen type defect and for the inter-deep level state transitions Experimentally feature: If h >  E opt, there is a possibility for the two step excitation of the intrinsic photoconductivity (the additional effects).

J.Vaitkus et al. PC spectra. CERN RD50 Workshop, Ljubljana, What is possible to search? From earlier data (Ioana): The levels position in the bandgap The parameters for the zero field emission rates describing the experimental results are: E i 116K = E v eV (0.285eV * ) and  p 116K =4  (4  *)cm 2 E i 140K = E v eV and  p 140K =2.5  cm 2 E i 152K = E v eV (0.36eV * ) and  p 152K =2.3  (2  *) cm 2 Ec Eg/2 Ev V 2 -/0 VO -/0 P 0/ + H152K 0 /- H140K 0 /- H116K 0 /- C i O i + /0 * - aparent ionization energy and capture cross sections when no field dependence of emission rates is accounted At K these levels could cause the photoconductivity components at: h >E c – E i T, i.e., 116 K h > 0,84 eV (0,884 eV) 140 K h > 0,81 eV 152 K h > 0,75 eV (0,81 eV)

J.Vaitkus et al. PC spectra. CERN RD50 Workshop, Ljubljana, The method requirements: The correct measurement of photo-ionization spectrum is recommended to perform measurements: in the homogeneous samples with the Ohmic contacts and during measurement to keep the constant photocurrent. Then the intensity of excitation is proportional to the inverse photoionization cross-section that allows to measure the activation energy and the signal amplitude is related to the centre concentration. Our case is much more problematic: –The samples are diodes: the photo-e.m.f. appears; –The extraction of carriers and the remaining charge influence –The dependence on electric field in the sample possible changes during the treatment.

J.Vaitkus et al. PC spectra. CERN RD50 Workshop, Ljubljana, The samples peculiarities Si Diodes: WODEAN n-MCZ (OKMETIC), P- doped 900  cm, Neff = cm -3 Diode processing: CiS Erfurt, thinned to d = 95  m rear contact: P-implanted: Neff = cm -3 P-diffused: Neff = cm -3 (TD generation during thermal process) x E Ec EMEM Ev EFEF The problems (e.g., remaining space charge), can be transformed into the qualitative recognition of the sample structure.

J.Vaitkus et al. PC spectra. CERN RD50 Workshop, Ljubljana, Photovoltage in irradiated Si diode

J.Vaitkus et al. PC spectra. CERN RD50 Workshop, Ljubljana, Deep levels contribution to PC The main centres: 0,450 eV 0,575 eV 0,670 eV 0,720 eV 0,785-0,790 eV 1,09 eV

J.Vaitkus et al. PC spectra. CERN RD50 Workshop, Ljubljana, Processing: The prepositions for a further analyze: 1.To be not afraid of many deep levels (the neutron – semiconductor interaction modeling allows it); 2.To be careful in the evaluation of the theory & experiment comparison.

J.Vaitkus et al. PC spectra. CERN RD50 Workshop, Ljubljana, The spatial distribution of vacancies varies significantly from one event to the other.

J.Vaitkus et al. PC spectra. CERN RD50 Workshop, Ljubljana, K & 18 K Bias more than 40 V is enough for extraction of carriers

J.Vaitkus et al. PC spectra. CERN RD50 Workshop, Ljubljana, PC spectra in irradiated Si 1.The lifetime decreases as a square root on the fluence 2.The total impurities contribution increase by power law  =1/2 ÷ 1/3

J.Vaitkus et al. PC spectra. CERN RD50 Workshop, Ljubljana, PC at low and high bias

J.Vaitkus et al. PC spectra. CERN RD50 Workshop, Ljubljana, Decay time constant vs irradiation Why are the dependences on fluence of the decay constant and instantaneous lifetime different? That shows the additional process in the carrier capture, that is still hidden! Local field redistribution can also play role, but it appears only for the more shallow local levels

J.Vaitkus et al. PC spectra. CERN RD50 Workshop, Ljubljana, An example of analyse

J.Vaitkus et al. PC spectra. CERN RD50 Workshop, Ljubljana, Avoiding the accumulation of errors: analyze of the main features. Where are these levels in the bandgap?  E = K 1.07 eV, i.e. E M -E v > 0.1 eV 970 meV (???) E C -E M >0.2 eV 885 meV, i.e., E C -E M >0.285 eV 772 meV, i.e E C -E M >0.398 eV 660 meV, i.e E C -E M >0.51 eV 480 meV, i.e E C -E M >0.48 eV > to = If neglect the difference of  E Optical and  E Thermal

J.Vaitkus et al. PC spectra. CERN RD50 Workshop, Ljubljana, In a linear scale: a few main features Annealing does not influence Decreasing due to annealing Increasing due to annealing A peculiarity: a strange shape of the photoconductivity band: It is probable more complicated phenomena. The PC quenching effect due to the two step excitation is possible (IR quenching level could be at 970 meV) Intrinsic photoconductivity (~ absorption coefficient)

J.Vaitkus et al. PC spectra. CERN RD50 Workshop, Ljubljana, e14 cm 2 Increasing changes to decreasing at higher T of annealing

J.Vaitkus et al. PC spectra. CERN RD50 Workshop, Ljubljana, e-15 cm -2 & 1e-16 cm -2

J.Vaitkus et al. PC spectra. CERN RD50 Workshop, Ljubljana, Conclusions: Deep levels can be revealed by PC spectrum Relative concentration can be evaluated (a change during annealing) The homogeneous samples with the Ohmic contacts could allow the higher quality measurement of parameters. In the nearest future we will have a possibility to cover wider impurity spectrum (up to 70 meV)