Photoluminescence and Raman Spectroscopy on truncated Nano Pyramids

Similar documents
GeSi Quantum Dot Superlattices

Luminescence basics. Slide # 1

Fabrication of Efficient Blue Light-Emitting Diodes with InGaN/GaN Triangular Multiple Quantum Wells. Abstract

Temperature Dependent Optical Band Gap Measurements of III-V films by Low Temperature Photoluminescence Spectroscopy

Ultrafast single photon emitting quantum photonic structures. based on a nano-obelisk

Self-Assembled InAs Quantum Dots

Luminescence Process

Multi-color broadband visible light source via GaN hexagonal. annular structure

Optical Investigation of the Localization Effect in the Quantum Well Structures

interband transitions in semiconductors M. Fox, Optical Properties of Solids, Oxford Master Series in Condensed Matter Physics

Supplementary Figure 1 Comparison of single quantum emitters on two type of substrates:

External (differential) quantum efficiency Number of additional photons emitted / number of additional electrons injected

Fall 2014 Nobby Kobayashi (Based on the notes by E.D.H Green and E.L Allen, SJSU) 1.0 Learning Objectives

Optical Characterization of Self-Assembled Si/SiGe Nano-Structures

Chapter 17. λ 2 = 1.24 = 6200 Å. λ 2 cutoff at too short a wavelength λ 1 cutoff at to long a wavelength (increases bandwidth for noise reduces S/N).

vapour deposition. Raman peaks of the monolayer sample grown by chemical vapour

A Plasmonic Photocatalyst Consisting of Silver Nanoparticles Embedded in Titanium Dioxide. Ryan Huschka LANP Seminar February 19, 2008

Supplementary Figure 1 XRD pattern of a defective TiO 2 thin film deposited on an FTO/glass substrate, along with an XRD pattern of bare FTO/glass

Lecture 20 Optical Characterization 2

Ultrafast carrier dynamics in InGaN MQW laser diode

Lecture 15: Optoelectronic devices: Introduction

Fig. 1: Raman spectra of graphite and graphene. N indicates the number of layers of graphene. Ref. [1]

Raman spectroscopy of self-assembled InAs quantum dots in wide-bandgap matrices of AlAs and aluminium oxide

Influence of excitation frequency on Raman modes of In 1-x Ga x N thin films

Supporting Information. Davydov Splitting and Excitonic Resonance Effects

Infrared Reflectivity Spectroscopy of Optical Phonons in Short-period AlGaN/GaN Superlattices

Progress Report to AOARD

Optical properties of strain-compensated hybrid InGaN/InGaN/ZnO quantum well lightemitting

Naser M. Ahmed *, Zaliman Sauli, Uda Hashim, Yarub Al-Douri. Abstract

T he group III-nitrides, as representative materials for light-emitting diodes (LEDs), has attracted a wide range

Cathodoluminescence of Rare Earth Ions in Semiconductors and Insulators

Vibrational Spectroscopies. C-874 University of Delaware

LASER. Light Amplification by Stimulated Emission of Radiation

Abnormal PL spectrum in InGaN MQW surface emitting cavity

Supplementary Information. for. Controlled Scalable Synthesis of Uniform, High-Quality Monolayer and Fewlayer

Supplementary Information for

Lecture #2 Nanoultrasonic imaging

Laser Diodes. Revised: 3/14/14 14: , Henry Zmuda Set 6a Laser Diodes 1

3-1-2 GaSb Quantum Cascade Laser

solidi current topics in solid state physics InAs quantum dots grown by molecular beam epitaxy on GaAs (211)B polar substrates

Optical Properties of Solid from DFT

Exciton spectroscopy

Spontaneous Emission and Ultrafast Carrier Relaxation in InGaN Quantum Well with Metal Nanoparticles. Meg Mahat and Arup Neogi

Electron leakage effects on GaN-based light-emitting diodes

Structural and Optical Properties of III-III-V-N Type

Model Answer (Paper code: AR-7112) M. Sc. (Physics) IV Semester Paper I: Laser Physics and Spectroscopy

4. Inelastic Scattering

3.1 Absorption and Transparency

Physics 214 Midterm Exam Spring Last Name: First Name NetID Discussion Section: Discussion TA Name:

OPTICAL PROPERTIES AND SPECTROSCOPY OF NANOAAATERIALS. Jin Zhong Zhang. World Scientific TECHNISCHE INFORMATIONSBIBLIOTHEK

Supplementary Information Our InGaN/GaN multiple quantum wells (MQWs) based one-dimensional (1D) grating structures

Nanomaterials for Photovoltaics (v11) 14. Intermediate-Band Solar Cells

Colloidal Single-Layer Quantum Dots with Lateral Confinement Effects on 2D Exciton

Ultraviolet-Visible and Infrared Spectrophotometry

Using Visible Laser Based Raman Spectroscopy to Identify the Surface Polarity of Silicon Carbide

Lecture 21: Lasers, Schrödinger s Cat, Atoms, Molecules, Solids, etc. Review and Examples. Lecture 21, p 1

Chapter 6 Photoluminescence Spectroscopy

Correlations between spatially resolved Raman shifts and dislocation density in GaN films

PHOTOVOLTAICS Fundamentals

Emission Spectra of the typical DH laser

Optics and Quantum Optics with Semiconductor Nanostructures. Overview

Supplementary Information

Optical Properties of Semiconductors. Prof.P. Ravindran, Department of Physics, Central University of Tamil Nadu, India

Methods of surface analysis

Energy Spectroscopy. Ex.: Fe/MgO

SUPPLEMENTARY INFORMATION

Investigation of the formation of InAs QD's in a AlGaAs matrix

Chapter 3 Properties of Nanostructures

The design of an integrated XPS/Raman spectroscopy instrument for co-incident analysis

Effects of Si doping on optical properties of GaN epitaxial layers

Abstract. Introduction

Semiconductor Disk Laser on Microchannel Cooler

Chapter 1 Overview of Semiconductor Materials and Physics

Electron Energy, E E = 0. Free electron. 3s Band 2p Band Overlapping energy bands. 3p 3s 2p 2s. 2s Band. Electrons. 1s ATOM SOLID.

CHEM6416 Theory of Molecular Spectroscopy 2013Jan Spectroscopy frequency dependence of the interaction of light with matter

Multiple Exciton Generation in Quantum Dots. James Rogers Materials 265 Professor Ram Seshadri

Auger Electron Spectroscopy

Review of Optical Properties of Materials

Magnetic measurements (Pt. IV) advanced probes

III-V nanostructured materials synthesized by MBE droplet epitaxy

AP 5301/8301 Instrumental Methods of Analysis and Laboratory

Understanding Semiconductor Lasers

Cover Page. The handle holds various files of this Leiden University dissertation

Fabrication / Synthesis Techniques

Quantum Dots for Advanced Research and Devices

Due to the quantum nature of electrons, one energy state can be occupied only by one electron.

Chemistry Instrumental Analysis Lecture 5. Chem 4631

Combined Excitation Emission Spectroscopy of Europium ions in GaN and AlGaN films

Practical 1P4 Energy Levels and Band Gaps

CHAPTER 3. OPTICAL STUDIES ON SnS NANOPARTICLES

X-ray Energy Spectroscopy (XES).

Solar Cell Materials and Device Characterization

Temperature dependence studies of Er optical centers in GaN epilayers grown by MOCVD

Practical 1P4 Energy Levels and Band Gaps

Excess carriers: extra carriers of values that exist at thermal equilibrium

FMM, 15 th Feb Simon Zihlmann

Potential and Carrier Distribution in AlGaN Superlattice

IR Spectrography - Absorption. Raman Spectrography - Scattering. n 0 n M - Raman n 0 - Rayleigh

Magnetic measurements (Pt. IV) advanced probes

The Role of Hydrogen in Defining the n-type Character of BiVO 4 Photoanodes

Transcription:

Photoluminescence and Raman Spectroscopy on truncated Nano Pyramids Physics of low Dimensions, FFF042 Josefin Voigt & Stefano Scaramuzza 10.12.2013, Lund University 1

Introduction In this project truncated GaN nano pyramids containing one or more InGaN quantum wells are examined by using photoluminescence (PL) spectroscopy and Raman spectroscopy. InGaN/GaN quantum wells are interesting because depending on the composition of the InGaN or the quantum well width they are able to emit light from the whole visible spectrum. Structures like nanopyramids containing such quantum wells are quite novel and thus it is interesting to study them. Sample An illustration and a SEM image of the examined samples is shown in Figure 1. After applying a GaN layer on a Si substrate a SiN mask is deposited on the GaN featuring holes. The GaN grown is continued on this spots which results in a formation of the truncated pyramids. The quantum wells are made by depositing a thin layer of InGaN on top of the pyramids and by covering it again with GaN. The pyramids have less strain between the InGaN and the GaN compared to pyramids grown on a single flat surface. The examined samples are presented in Table 1. Sample 249 is a reference sample containing no InGaN. Figure 1: SEM image [4] (left) and Illustration (right) of a truncated nanopyramid. Table 1: Samples and their properties. TEG and TMI stand for the flow rates in sccm of the precursors triethylgallium and trimethylindium. 2

Techniques In photoluminescence spectroscopy a sample is illuminated by a light source of a defined wavelength. The incident light gives enough energy to the electrons to lift them from the valence band into the conduction band leaving a hole in the valence band. If the electrons occupy a higher state than the ground state in the conduction band they will relax into the ground state under emission of phonons. The same happens with the holes in the valence band. Once electrons and holes are in their ground state, they recombine under emission of a photon of a characteristic energy for the considered material. This way materials and their properties can be studied. In Raman spectroscopy a sample is illuminated by a certain wavelength laser where due to the Raman effect a photon is absorbed exciting an electron to a virtual energy level. The subsequent relaxation of the electron to a different vibrational or rotational state, causes a photon of different energy to be emitted. This difference in energy between the original photon and the emitted photon causes a frequency shift, calculated as 1/λ 0 1/λ R where λ 0 is the wavelength of the laser and λ R is the wavelength of the Raman radiation. These shifts are material specific, since only certain modes are allowed for the state after recombinations for electrons, according to certain selection rules. The shifts can thus be used to decide which materials can be found in certain samples. Results Photoluminescence Spectroscopy A PL spectrum has been acquired for each sample. Figure 2 shows the PL spectrum of the reference sample 249 and 278. It has been acquired with a laser of 325 nm wavelength. According to [2] a narrow peak from the GaN around 3.48 ev and a broader peak from the InGaN quantum well around 3.1 ev is expected. According to [3] the InGaN well peak is expected to be in the range between 2.9 ev and 3.1 ev. The GaN signal should stay constant for each sample while the InGaN peak depends on different factors as e.g. the size of the quantum well and is thus expected to slightly vary between the samples. There are other peaks in the spectrum which might result from other materials (Si substrate) or impurities in the different materials used in the sample. The important difference between the presented plots in Figure 2 is the peak in sample 278 at 2.95 ev. It is assumed to belong to the InGaN well for different reasons. First it is not visible in the reference sample. Second according to [3] and [4] we should expect it in this energy region. Third it is the only peak varying its position depending on the sample. Since it is assumed that several peaks in the region 3.0 3.5 ev belong to impurities in the GaN a new laser wavelength of 375 nm is used. The impurity peaks are expected to decrease since the lasers energy (3.3 ev) is slightly below the GaN bandgap of 3.47 ev ([1]). 3

The obtained result is presented in Figure 3. Again the reference sample 249 and the sample 278 are presented. Energies over 3.2 ev are neglected since the laser light could not be filtered before it reached the detector and its energy is around 3.3 ev. Thus we would have too much contribution around these energies. The spectrum of the reference sample is similar to the one obtained with the previous wavelength. The spectrum of sample 278 although shows that the peak around 2.95 ev is better defined than with the previous laser. Figure 2: PL spectrum of sample 249 and 278 acquired with a 325 nm laser. Figure 3: PL spectra of sample 249 and 278 acquired with a 375 nm laser. 4

After acquiring the PL spectra with the new wavelength the peak corresponding to the InGaN well for each plot is determined. This information can be further used to estimate the size of the quantum well. Under assumption of different parameters one can plot the energy of the quantum well peak as a function of the well width L. Since the composition x of the In x Ga 1 x N is not known the calculations are made for x=0.2, 0.4, 0.6 and 0.8. The plot is shown in Figure 4. Figure 4: PL peak energy of the quantum well in dependence of its thickness for different compositions x. By comparing the found energies of the PL spectrum with the plot in Figure 4 we can estimate the size of the quantum well in the pyramids. The results are summarized in Table 2. Table 2: PL peak energies of the quantum wells and the resulting estimated quantum well widths. Assuming an InGaN monolayer thickness of 5 Å we get a thickness of 1 10 monolayers per well. Either high well times or flow rates seem to be required to gain a bigger quantum well, assuming an increase of material leads to more growth. It is possible to be the opposite way as well but it seems unlikely to increase the layer thickness when growing for a longer time. Another way to determine the composition of the samples is to measure the well sizes using SEM. When analysing the SEM images the wells appear to be around 2nm 4nm even though the resolution of the SEM images makes it hard to find an exact value. Comparing this well size with figure 4 we can estimate a composition around In 20 Ga 80 N. For a more exact value of the composition we would need a more exact value of the sizes of the quantum wells, which could be achieved by using TEM. 5

Results Raman Spectroscopy To correctly calculate the width of the wells from the position of the peaks in the PL spectrum a correct value of the composition of the InGaN is desirable, as mentioned before. As has been shown in [6] and [7] this can be obtained by studying the Raman spectrum. Therefore Raman spectroscopy was performed on the samples. When using a laser of 632.5 nm the Raman spectra for the samples were as shown in Figure 5. Figure 5: Raman spectra for the different samples, obtained using a 632.5 nm laser. These peaks of approximately 525 cm 1 and 570 cm 1 correspond well to the expected values found in [8] of peaks from the GaN substrate for cross sectional insidence. The first peak correspond to the A 1 (LO) vibrational mode and the second peak correspond to the E 1 (TO) and E 2 vibrational modes. It is also possible that Si from the substrate contribute to the peak at around 525 cm 1, since Si has a TO shift of 521 cm 1 for zincblende structure, which makes up the substrate. As can be seen all the spectra are approximately equivalent, even that of sample 249, this indicates that we do not get a signal from the quantum well since this spectra does not differ from the others. From [6] we expect a frequency shift in the range of 600 cm 1 to 750 cm 1 for a thin film of InGaN, which can not be seen in figure 5. The reasons for this could be several. One major cause could be that the layer of InGaN is very thin and when exposing the sample the laser is focused on a very tiny spot, thus exposing very little of the thin InGaN layer and more of the surroundings. To see if the laser was too low in energy or penetrated too deep into the sample to actually detect the quantum wells close to the surface, another setup, with a laser of 532 nm, was tried. We did not however see any peaks from quantum wells in this case either. 6

Conclusion Using PL spectroscopy and the assumption that the composition of the quantum well was between In 20 Ga 80 N and In 80 Ga 20 N the wells of the samples were estimated to be 0.20 nm 5.60 nm, with some differences for the different wells (see table 2). This corresponds to a thickness of 3 18 monolayers per well. The size of the well seems to be clearly influenced by the well time and the flow rates of the precursors during growth. Had we been able to measure the sizes of the quantum wells with a good certainty it would have been possible to determine the composition of the wells. However SEM showed to have to low resolution to be able to do this and we would have to use TEM. The sizes of the wells would also have been possible to determine if we had succeeded in determining the composition using raman spectroscopy. Unfortunately this did not work, probably due to the small amount of material constituting the quantum well not giving enough signal. Sources [1] John H. Davies, The physics of low dimensional semiconductors, Cambridge University Press, 1997. [2] Chul Woo Lee, Sung Taek Kim, Ki Soo Lim, Photoluminescence Studies of GaN and InGaN/GaN Quantum Wells, Journal of the Korean Physical Society, Vol. 35, No. 3, pp. 280 285, 1999. [3] M. S. Minsky, S. B. Fleischer, A. C. Abare, J. E. Bowers, E. L. Hu, Characterization of high quality InGaN/GaN multiquantum wells with time resolved photoluminescence, Applied Physics Letters, Vol. 72, No. 9, pp. 1066 1068, 1998. [4] Ioffe Physico Technical Institute, Electronic archive: New Semiconductor Materials. Characteristics and Properties, Accessed: 9.10.2013, http://www.ioffe.ru/sva/nsm/. [5] Zhaoxia Bi, Presentation: MQW on truncated GaN pyramids, Lund University, 2013. [6] Robert Oliva Vidal, Master thesis: Optical emission and Raman scattering in InGaN thin films grown by molecular beam epitaxy, Raman Spectroscopy Group, ICTJA, CSIC Lluis Solé i Sabarís, Barcelona [7] S. Hernández, R. Cuscó, D. Pastor, L. Artúsa, K. P. O Donnell, R. W. Martin, I. M. Watson, Y. Nanishi, E. Calleja, Raman scattering study of the InGaN alloy over the whole composition range, Journal of applied physics 98, 013511, 2005 [8] Z. C. Feng, W. Wang, S. J. Chua, P. X. Zhang, K. P. J. Williams, G. D. Pitt, Raman scattering properties of GaN thin films grown on sapphire under visible and ultraviolet excitation, J. Raman Spectrosc., 32, 840 846, 2001 7

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback