Presentation is loading. Please wait.

Presentation is loading. Please wait.

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

Published byCecily Ferguson Modified over 9 years ago

Similar presentations

Presentation on theme: "Thermally Stimulated Currents Method Ioana Pintilie a) National Institute of Materials Physics, Bucharest-Magurele, P.O.Box MG-7, Romania b) Institute."— Presentation transcript:

1 Thermally Stimulated Currents Method Ioana Pintilie a) National Institute of Materials Physics, Bucharest-Magurele, P.O.Box MG-7, Romania b) Institute for Experimental Physics, Hamburg University, D-22761, Germany

2 Electrical properties of Point Defects in the space charge region Defect´ signature – emission rates 2) Leakage current density 1)Effective doping concentration -given by the steady state occupancy of the defect/impurity levels in SCR Effective generation centers (acceptor like)

3 Thermally Stimulated Currents Method 1.cooling the sample 2.filling of the traps: -during cooling under 0 bias (majority carriers) -or carrier injection at low T by biasing the diode/ illumination 3.recording the TSCurrent – the current due to charge emission from the traps is recorded as function of temperature during the heating of the sample with constant rate p + - n – n + diodes n + p + n Electrons in the conduction band Holes in the valence band I Current d

4 n t (T fill ), p t (T fill ): electrons injection n t (T fill ) = N t holes injection p t (T fill ) = N t forward injection/illumination under 0V p t (T fill ) = N t  c p /(c n +c p ) n t (T fill ) = N t  c n /(c n +c p )

5 Activation enthalpy - the thermal cleanning procedure For defects with e n (T) >> e p (T) (or viceversa) and for constant SCR width (x(T)=d) the increasing part of the TSC peak is ~ exp (  H n (p) /kT)   H n (p) can be determined from Arrhenius plots Concentration of defects – by integrating the TSC peak Capture cross sections – by fitting the TSC peaks

6 x = d x < d x =d Nt >20xNd Problems - Temperature variation of SCR width (x(T) < d)

7

8 Evaluation of temperature dependent capture cross sections Diodes with initial doping of N d = 5·10 11 cm -3, N t ~ 2·10 13 cm -3

9 P + N + Electrons in the conduction band Holes in the valence band N N A N D (+) (-) /0 Steady state occupancy in the SCR Emission from the filled traps Deep acceptors acting like Generation centers n T (T) ~ 80%N T  what can be detected is 20% N T emission of electrons 80% N T emission of holes

10 Thermally Stimulated Currents Method limitation: -TSC min > 0.1 pA -TSC max – given by the possibility of depleting the diodes thickness (RB max =500 V) during T scan -no direct measurement of the capture cross sections possible advantage: -investigation of diodes with high traps concentration N T >N D -N A - determination of ionisation energy (Thermal cleaning procedure) - suitable for the detection of donor activity (Poole-Frenkel effect) disadvantage: - no direct defect identification possible -combination with other methods (e.g. EPR, FTIR)

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

Similar presentations

ECSE-6230 Semiconductor Devices and Models I Lecture 4

ECSE-6230 Semiconductor Devices and Models I Lecture 4
Chapter 2-4. Equilibrium carrier concentrations

Chapter 2-4. Equilibrium carrier concentrations
P-N JUNCTION.

P-N JUNCTION.
Chapter 6-1. PN-junction diode: I-V characteristics

Chapter 6-1. PN-junction diode: I-V characteristics
ECE 663 P-N Junctions. ECE 663 So far we learned the basics of semiconductor physics, culminating in the Minority Carrier Diffusion Equation We now encounter.

ECE 663 P-N Junctions. ECE 663 So far we learned the basics of semiconductor physics, culminating in the Minority Carrier Diffusion Equation We now encounter.
© Electronics ECE 1312 Recall-Lecture 2 Introduction to Electronics Atomic structure of Group IV materials particularly on Silicon Intrinsic carrier concentration,

© Electronics ECE 1312 Recall-Lecture 2 Introduction to Electronics Atomic structure of Group IV materials particularly on Silicon Intrinsic carrier concentration,
Department of Aeronautics and Astronautics NCKU Nano and MEMS Technology LAB. 1 Chapter IV June 14, 2015June 14, 2015June 14, 2015 P-n Junction.

Department of Aeronautics and Astronautics NCKU Nano and MEMS Technology LAB. 1 Chapter IV June 14, 2015June 14, 2015June 14, 2015 P-n Junction.
CHAPTER 5 DEFECTS.

CHAPTER 5 DEFECTS.
Normalized plot of n 0 /N D as a function of temperature. This plot is for N D = 10 16 cm  3. Figure 2.20 2-20.

Normalized plot of n 0 /N D as a function of temperature. This plot is for N D = cm  3. Figure
Lecture #8 OUTLINE Generation and recombination Excess carrier concentrations Minority carrier lifetime Read: Section 3.3.

Lecture #8 OUTLINE Generation and recombination Excess carrier concentrations Minority carrier lifetime Read: Section 3.3.
Lecture Jan 31,2011 Winter 2011 ECE 162B Fundamentals of Solid State Physics Band Theory and Semiconductor Properties Prof. Steven DenBaars ECE and Materials.

Lecture Jan 31,2011 Winter 2011 ECE 162B Fundamentals of Solid State Physics Band Theory and Semiconductor Properties Prof. Steven DenBaars ECE and Materials.
Principle of operation and limits of application

Principle of operation and limits of application
Electron And Hole Equilibrium Concentrations 18 and 20 February 2015  Chapter 4 Topics-Two burning questions: What is the density of states in the conduction.

Electron And Hole Equilibrium Concentrations 18 and 20 February 2015  Chapter 4 Topics-Two burning questions: What is the density of states in the conduction.
Electron And Hole Equilibrium Concentrations 24 February 2014  Return and discuss Quiz 2  Chapter 4 Topics-Two burning questions: What is the density.

Electron And Hole Equilibrium Concentrations 24 February 2014  Return and discuss Quiz 2  Chapter 4 Topics-Two burning questions: What is the density.
Defects Maria Berdova maria.berdova@aalto.fi Postgraduate Course in Electron Physics I.

Defects Maria Berdova Postgraduate Course in Electron Physics I.
(Deep Level Transient Spectroscopy)

(Deep Level Transient Spectroscopy)
Stretched exponential transport transients in GaP alloys for high efficiency solar cells Dan Hampton and Tim Gfroerer, Davidson College, Davidson, NC Mark.

Stretched exponential transport transients in GaP alloys for high efficiency solar cells Dan Hampton and Tim Gfroerer, Davidson College, Davidson, NC Mark.
(Deep Level Transient Spectroscopy) II. Advanced Techniques

(Deep Level Transient Spectroscopy) II. Advanced Techniques
Lecture 5.0 Properties of Semiconductors. Importance to Silicon Chips Size of devices –Doping thickness/size –Depletion Zone Size –Electron Tunneling.

Lecture 5.0 Properties of Semiconductors. Importance to Silicon Chips Size of devices –Doping thickness/size –Depletion Zone Size –Electron Tunneling.
Drift and Diffusion Current

Drift and Diffusion Current

Similar presentations

Ads by Google