ART

Deep-level transient spectroscopy (DLTS) is an experimental tool for studying electrically active defects (known as charge carrier traps) in semiconductors. DLTS establishes fundamental defect parameters and measures their concentration in the material. Some of the parameters are considered as defect "finger prints" used for their identifications and analysis.

DLTS investigates defects present in a space charge (depletion) region of a simple electronic device. The most commonly used are Schottky diodes or p-n junctions. In the measurement process the steady-state diode reverse polarization voltage is disturbed by a voltage pulse. This voltage pulse reduces the electric field in the space charge region and allows free carriers from the semiconductor bulk to penetrate this region and recharge the defects causing their non-equilibrium charge state. After the pulse, when the voltage returns to its steady-state value, the defects start to emit trapped carriers due to the thermal emission process. The technique observes the device space charge region capacitance where the defect charge state recovery causes the capacitance transient. The voltage pulse followed by the defect charge state recovery are cycled allowing an application of different signal processing methods for defect recharging process analysis.

The DLTS technique has a higher sensitivity than almost any other semiconductor diagnostic technique. For example, in silicon it can detect impurities and defects at a concentration of one part in 1012 of the material host atoms. This feature together with a technical simplicity of its design made it very popular in research labs and semiconductor material production factories.

The DLTS technique was pioneered by David Vern Lang at Bell Laboratories in 1974.[1] A US Patent was awarded to Lang in 1975.[2]

DLTS methods
Conventional DLTS
Typical conventional DLTS spectra

In conventional DLTS the capacitance transients are investigated by using a lock-in amplifier[3] or double box-car averaging technique when the sample temperature is slowly varied (usually in a range from liquid nitrogen temperature to room temperature 300 K or above). The equipment reference frequency is the voltage pulse repetition rate. In the conventional DLTS method this frequency multiplied by some constant (depending on the hardware used) is called the "rate window". During the temperature scan, peaks appear when the emission rate of carriers from some defect equals the rate window. By setting up different rate windows in subsequent DLTS spectra measurements one obtains different temperatures at which some particular peak appears. Having a set of the emission rate and corresponding temperature pairs one can make an Arrhenius plot, which allows for the deduction of defect activation energy for the thermal emission process. Usually this energy (sometimes called the defect energy level) together with the plot intercept value are defect parameters used for its identification or analysis. On samples with low free carrier density conductance transients have also been used for a DLTS analysis.[4]

In addition to the conventional temperature scan DLTS, in which the temperature is swept while pulsing the device at a constant frequency, the temperature can be kept constant and sweep the pulsing frequency. This technique is called the frequency scan DLTS.[3] In theory the frequency and temperature scan DLTS should yield same results. Frequency scan DLTS is specifically useful when an aggressive change in temperature might damage the device. An example when frequency scan is shown to be useful is for studying modern MOS devices with thin and sensitive gate oxides.[3]

DLTS has been used to study quantum dots and perovskite solar cells.[5][6][7][8][9]
MCTS and minority-carrier DLTS

For Schottky diodes, majority carrier traps are observed by the application of a reverse bias pulse, while minority carrier traps can be observed when the reverse bias voltage pulses are replaced with light pulses with the photon energy from the above semiconductor bandgap spectral range.[10][11] This method is called Minority Carrier Transient Spectroscopy (MCTS). The minority carrier traps can be also observed for the p-n junctions by application of forward bias pulses, which inject minority carriers into the space charge region.[12] In DLTS plots the minority carrier spectra usually are depicted with an opposite sign of amplitude in respect to the majority carrier trap spectra.
Laplace DLTS

There is an extension to DLTS known as a high resolution Laplace transform DLTS (LDLTS). Laplace DLTS is an isothermal technique in which the capacitance transients are digitized and averaged at a fixed temperature. Then the defect emission rates are obtained with a use of numerical methods being equivalent to the inverse Laplace transformation. The obtained emission rates are presented as a spectral plot.[13][14] The main advantage of Laplace DLTS in comparison to conventional DLTS is the substantial increase in energy resolution understood here as an ability to distinguish very similar signals.

Laplace DLTS in combination with uniaxial stress results in a splitting of the defect energy level. Assuming a random distribution of defects in non-equivalent orientations, the number of split lines and their intensity ratios reflect the symmetry class[15] of the given defect.[13]

Application of LDLTS to MOS capacitors needs device polarization voltages in a range where the Fermi level extrapolated from semiconductor to the semiconductor-oxide interface intersects this interface within the semiconductor bandgap range. The electronic interface states present at this interface can trap carriers similarly to defects described above. If their occupancy with electrons or holes is disturbed by a small voltage pulse then the device capacitance recovers after the pulse to its initial value as the interface states start to emit carriers. This recovery process can be analyzed with the LDLTS method for different device polarization voltages. Such a procedure allows to obtain the energy state distribution of the interface electronic states at the semiconductor-oxide (or dielectric) interfaces.[16]
Constant-capacitance DLTS

In general, the analysis of the capacitance transients in the DLTS measurements assumes that the concentration of investigated traps is much smaller than the material doping concentration. In cases when this assumption is not fulfilled then the constant capacitance DLTS (CCDLTS) method is used for more accurate determination of the trap concentration.[17] When the defects recharge and their concentration is high then the width of the device space region varies making the analysis of the capacitance transient inaccurate. The additional electronic circuitry maintaining the total device capacitance constant by varying the device bias voltage helps to keep the depletion region width constant. As a result, the varying device voltage reflects the defect recharge process. An analysis of the CCDLTS system using feedback theory was provided by Lau and Lam in 1982.[18]
I-DLTS and PITS

There is an important shortcoming for DLTS: it cannot be used for insulating materials. (Note: an insulator can be considered as a very large bandgap semiconductor.) For insulating materials it is difficult or impossible to produce a device having a space region for which width could be changed by the external voltage bias and thus the capacitance measurement-based DLTS methods cannot be applied for the defect analysis. Basing on experiences of the thermally stimulated current (TSC) spectroscopy, the current transients are analyzed with the DLTS methods (I-DLTS), where the light pulses are used for the defect occupancy disturbance. This method in the literature is sometimes called the Photoinduced Transient Spectroscopy (PITS).[19] I-DLTS or PITS are also used for studying defects in the i-region of a p-i-n diode.
See also

Carrier generation and recombination
Bandgap
Effective mass
Schottky diode
Frenkel defect
Schottky defect
Semiconductor device
Vacancy (chemistry)
Capacitance voltage profiling
High-k dielectric

References

Lang, D. V. (1974). "Deep‐level transient spectroscopy: A new method to characterize traps in semiconductors". Journal of Applied Physics. AIP Publishing. 45 (7): 3023–3032. doi:10.1063/1.1663719. ISSN 0021-8979.
[1], "Method for measuring traps in semiconductors", issued 1973-12-06
Elhami Khorasani, Arash; Schroder, Dieter K.; Alford, T. L. (2014). "A Fast Technique to Screen Carrier Generation Lifetime Using DLTS on MOS Capacitors". IEEE Transactions on Electron Devices. Institute of Electrical and Electronics Engineers (IEEE). 61 (9): 3282–3288. doi:10.1109/ted.2014.2337898. ISSN 0018-9383. S2CID 5895479.
Fourches, N. (28 January 1991). "Deep level transient spectroscopy based on conductance transients". Applied Physics Letters. AIP Publishing. 58 (4): 364–366. doi:10.1063/1.104635. ISSN 0003-6951.
Lin, S. W.; Balocco, C.; Missous, M.; Peaker, A. R.; Song, A. M. (3 October 2005). "Coexistence of deep levels with optically active InAs quantum dots". Physical Review B. American Physical Society (APS). 72 (16): 165302. doi:10.1103/physrevb.72.165302. ISSN 1098-0121.
Antonova, Irina V.; Volodin, Vladimir A.; Neustroev, Efim P.; Smagulova, Svetlana A.; Jedrzejewsi, Jedrzej; Balberg, Isaac (15 September 2009). "Charge spectroscopy of Si nanocrystallites embedded in a SiO2 matrix". Journal of Applied Physics. AIP Publishing. 106 (6): 064306. doi:10.1063/1.3224865. ISSN 0021-8979.
Buljan, M.; Grenzer, J.; Holý, V.; Radić, N.; Mišić-Radić, T.; Levichev, S.; Bernstorff, S.; Pivac, B.; Capan, I. (18 October 2010). "Structural and charge trapping properties of two bilayer (Ge+SiO2)/SiO2 films deposited on rippled substrate". Applied Physics Letters. AIP Publishing. 97 (16): 163117. doi:10.1063/1.3504249. ISSN 0003-6951.
Nazeeruddin, Mohammad Khaja; Ahn, Tae Kyu; Shin, Jai Kwang; Kim, Yong Su; Yun, Dong-Jin; Kim, Kihong; Park, Jong-Bong; Lee, Jooho; Seol, Minsu (2017-05-17). "Deep level trapped defect analysis in CH3NH3PbI3 perovskite solar cells by deep level transient spectroscopy". Energy & Environmental Science. 10 (5): 1128–1133. doi:10.1039/C7EE00303J. ISSN 1754-5706.
Heo, Sung; Seo, Gabseok; Lee, Yonghui; Seol, Minsu; Kim, Seong Heon; Yun, Dong-Jin; Kim, Yongsu; Kim, Kihong; Lee, Junho (2019). "Origins of High Performance and Degradation in the Mixed Perovskite Solar Cells". Advanced Materials. 31 (8): 1805438. doi:10.1002/adma.201805438. ISSN 1521-4095. PMID 30614565.
Brunwin, R.; Hamilton, B.; Jordan, P.; Peaker, A.R. (1979). "Detection of minority-carrier traps using transient spectroscopy". Electronics Letters. Institution of Engineering and Technology (IET). 15 (12): 349. doi:10.1049/el:19790248. ISSN 0013-5194.
Hamilton, B.; Peaker, A. R.; Wight, D. R. (1979). "Deep‐state‐controlled minority‐carrier lifetime inn‐type gallium phosphide". Journal of Applied Physics. AIP Publishing. 50 (10): 6373–6385. doi:10.1063/1.325728. ISSN 0021-8979.
Markevich, V. P.; Hawkins, I. D.; Peaker, A. R.; Emtsev, K. V.; Emtsev, V. V.; Litvinov, V. V.; Murin, L. I.; Dobaczewski, L. (27 December 2004). "Vacancy–group-V-impurity atom pairs in Ge crystals doped with P, As, Sb, and Bi". Physical Review B. American Physical Society (APS). 70 (23): 235213. doi:10.1103/physrevb.70.235213. ISSN 1098-0121.
Dobaczewski, L.; Peaker, A. R.; Bonde Nielsen, K. (2004). "Laplace-transform deep-level spectroscopy: The technique and its applications to the study of point defects in semiconductors". Journal of Applied Physics. AIP Publishing. 96 (9): 4689–4728. doi:10.1063/1.1794897. ISSN 0021-8979.
Laplace transform Deep Level Transient Spectroscopy
Point Group Symmetry
Dobaczewski, L.; Bernardini, S.; Kruszewski, P.; Hurley, P. K.; Markevich, V. P.; Hawkins, I. D.; Peaker, A. R. (16 June 2008). "Energy state distributions of the Pb centers at the (100), (110), and (111) Si∕SiO2 interfaces investigated by Laplace deep level transient spectroscopy" (PDF). Applied Physics Letters. AIP Publishing. 92 (24): 242104. doi:10.1063/1.2939001. ISSN 0003-6951.
Johnson, N. M.; Bartelink, D. J.; Gold, R. B.; Gibbons, J. F. (1979). "Constant‐capacitance DLTS measurement of defect‐density profiles in semiconductors". Journal of Applied Physics. AIP Publishing. 50 (7): 4828–4833. doi:10.1063/1.326546. ISSN 0021-8979.
Lau, W. S.; Lam, Y. W. (1982). "Analysis of and some design considerations for the constant capacitance DLTS system". International Journal of Electronics. Informa UK Limited. 52 (4): 369–379. doi:10.1080/00207218208901442. ISSN 0020-7217.

Hurtes, Ch.; Boulou, M.; Mitonneau, A.; Bois, D. (15 June 1978). "Deep‐level spectroscopy in high‐resistivity materials". Applied Physics Letters. AIP Publishing. 32 (12): 821–823. doi:10.1063/1.89929. ISSN 0003-6951.

External links

Database of DLTS signals of defects in semiconductors
Database of defects in semiconductors

vte

Spectroscopy
Vibrational

FT-IR Raman Resonance Raman Rotational Rotational–vibrational Vibrational Vibrational circular dichroism

UV–Vis–NIR

Ultraviolet–visible Fluorescence Vibronic Near-infrared Resonance-enhanced multiphoton ionization (REMPI) Raman optical activity spectroscopy Raman spectroscopy Laser-induced

X-ray and
photoelectron

Energy-dispersive X-ray spectroscopy Photoelectron Atomic Emission X-ray photoelectron spectroscopy EXAFS

Nucleon

Gamma Mössbauer

Radiowave

NMR Terahertz ESR/EPR Ferromagnetic resonance

Others

Acoustic resonance spectroscopy Auger spectroscopy Astronomical spectroscopy Cavity ring-down spectroscopy Circular dichroism spectroscopy Coherent anti-Stokes Raman spectroscopy Cold vapour atomic fluorescence spectroscopy Conversion electron Mössbauer spectroscopy Correlation spectroscopy Deep-level transient spectroscopy Dual-polarization interferometry Electron phenomenological spectroscopy EPR spectroscopy Force spectroscopy Fourier-transform spectroscopy Glow-discharge optical emission spectroscopy Hadron spectroscopy Hyperspectral imaging Inelastic electron tunneling spectroscopy Inelastic neutron scattering Laser-induced breakdown spectroscopy Mössbauer spectroscopy Neutron spin echo Photoacoustic spectroscopy Photoemission spectroscopy Photothermal spectroscopy Pump–probe spectroscopy Saturated spectroscopy Scanning tunneling spectroscopy Spectrophotometry Time-resolved spectroscopy Time-stretch Thermal infrared spectroscopy Video spectroscopy Vibrational spectroscopy of linear molecules

Physics Encyclopedia

World

Index

Hellenica World - Scientific Library

Retrieved from "http://en.wikipedia.org/"
All text is available under the terms of the GNU Free Documentation License