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Transmission Electron Microscopy of Semiconductor Nanowires

Larsson, Magnus LU (2007)
Abstract
Semiconductor nanowires are studied by using transmission electron microscopy (TEM) based methods in this work. In the first section, the growth mechanism of gallium arsenide nanowires grown by chemical beam epitaxy is investigated. The nanowires are epitaxially grown from a gallium arsenide substrate by using gold seed particles as catalysts. The growth of gold particle catalysed nanowires is often described by the vapour-liquid-solid mechanism with the gold seed particle as a eutectic alloy in the liquid state. Here, in-situ heating microscopy together with varied growth procedures and nanoscale analysis on the constituents shows that the gold seed particle is in a solid state during growth. Based on a mass transport model, it is also... (More)
Semiconductor nanowires are studied by using transmission electron microscopy (TEM) based methods in this work. In the first section, the growth mechanism of gallium arsenide nanowires grown by chemical beam epitaxy is investigated. The nanowires are epitaxially grown from a gallium arsenide substrate by using gold seed particles as catalysts. The growth of gold particle catalysed nanowires is often described by the vapour-liquid-solid mechanism with the gold seed particle as a eutectic alloy in the liquid state. Here, in-situ heating microscopy together with varied growth procedures and nanoscale analysis on the constituents shows that the gold seed particle is in a solid state during growth. Based on a mass transport model, it is also demonstrated here that the diffusion of gallium through a solid gold seed particle occurs at fast enough rates to support the observed growth rates. The gold seed particle is believed to act as a sink for growth species and the interface between the particle and the substrate becomes a preferred nucleation site, resulting in higher growth rate of the nanowires compared to the growth on the surrounding substrate surface.



More complex structures can be created by using nanowires as building blocks to create branched, and possibly interconnecting, structures. Here, branched nano structures, named ?nanotrees? due to their resemblance to trees in nature, are produced by sequential seeding of nano particles. The described method offers a high level of control in each growth step in terms of diameter, length, position and composition. Positioning the height of the branches on the trunk can be precisely controlled by the developed technique which is based on a spun on polymer film masking the lower part of the trunk. This also prevents growth of branches on the substrate surface. This technique is fundamentally material independent. The crystallographic orientation of the branches in relation to the trunk and the substrate surface is also investigated.



Heterostructured nanowires are a key component of newly developed electronic and optical devices based on the nanowire technology. It is possible to grow heterostructures with a large lattice mismatch without dislocations due to lateral relaxation. The strain at the interfaces affects the bandgap of the structure locally which directly changes the properties of the device. The strain in InAs/InP nanowire heterostructures has been measured and modelled using high resolution TEM techniques and finite element calculations as well as multi slice simulations. The TEM experimental measurement results correspond well with the finite element model which also generates simulated HRTEM images verifying the image processing technique. For a 20 nm thick wire a 10 nm long dislocation free region over the interface is strained with the rest of the wire having a relaxed crystal structure.



The in-situ microscopy applied in this work is utilising a scanning tunneling microscopy (STM) sample holder combined with TEM imaging to characterise the electrical properties of InAs nanowires. Ohmic contact between the STM-tip and the nanowires has been achieved and electrical measurements have been performed. The current-voltage measurement results are in good agreement with the data obtained by traditional measurements based on lithographic processing techniques. (Less)
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author
supervisor
opponent
  • Professor Hull, Robert, University of Virginia, USA
organization
publishing date
type
Thesis
publication status
published
subject
keywords
Nanowires, magnetic resonance, supraconductors, magnetic and optical properties, electrical, Condensed matter:electronic structure, fasjämvikt, kristallografi, egenskaper (termiska och mekaniska), crystallography, phase equilibria, Kondenserade materiens egenskaper:struktur, akustik, Condensed matter:stucture, thermal and mechanical properties, optics, acoustics, Elektromagnetism, optik, Electromagnetism, Scanning Tunneling Microscopy, Nanomaterials, III-V Semiconductors, Transmission Electron Microscopy, Inorganic chemistry, Oorganisk kemi, relaxation, spectroscopy, Kondenserade materiens egenskaper:elektronstruktur, egenskaper (elektriska, magnetiska och optiska), supraledare, magnetisk resonans, spektroskopi, materialteknik, Material technology, Materiallära, Semiconductory physics, Halvledarfysik
pages
145 pages
publisher
Polymer och Materialkemi Kemiska Institutionen
defense location
Kemicentrum Sal K:B Getingevägen 60 Lunds Tekniska Högskola
defense date
2007-03-02 09:15:00
ISBN
978-91-7422-149-7
language
English
LU publication?
yes
additional info
The information about affiliations in this record was updated in December 2015. The record was previously connected to the following departments: Polymer and Materials Chemistry (LTH) (011001041)
id
3f66cdc4-96c1-4ed4-b100-935600c3e0ce (old id 548079)
date added to LUP
2016-04-04 12:16:28
date last changed
2018-11-21 21:10:01
@phdthesis{3f66cdc4-96c1-4ed4-b100-935600c3e0ce,
  abstract     = {{Semiconductor nanowires are studied by using transmission electron microscopy (TEM) based methods in this work. In the first section, the growth mechanism of gallium arsenide nanowires grown by chemical beam epitaxy is investigated. The nanowires are epitaxially grown from a gallium arsenide substrate by using gold seed particles as catalysts. The growth of gold particle catalysed nanowires is often described by the vapour-liquid-solid mechanism with the gold seed particle as a eutectic alloy in the liquid state. Here, in-situ heating microscopy together with varied growth procedures and nanoscale analysis on the constituents shows that the gold seed particle is in a solid state during growth. Based on a mass transport model, it is also demonstrated here that the diffusion of gallium through a solid gold seed particle occurs at fast enough rates to support the observed growth rates. The gold seed particle is believed to act as a sink for growth species and the interface between the particle and the substrate becomes a preferred nucleation site, resulting in higher growth rate of the nanowires compared to the growth on the surrounding substrate surface.<br/><br>
<br/><br>
More complex structures can be created by using nanowires as building blocks to create branched, and possibly interconnecting, structures. Here, branched nano structures, named ?nanotrees? due to their resemblance to trees in nature, are produced by sequential seeding of nano particles. The described method offers a high level of control in each growth step in terms of diameter, length, position and composition. Positioning the height of the branches on the trunk can be precisely controlled by the developed technique which is based on a spun on polymer film masking the lower part of the trunk. This also prevents growth of branches on the substrate surface. This technique is fundamentally material independent. The crystallographic orientation of the branches in relation to the trunk and the substrate surface is also investigated.<br/><br>
<br/><br>
Heterostructured nanowires are a key component of newly developed electronic and optical devices based on the nanowire technology. It is possible to grow heterostructures with a large lattice mismatch without dislocations due to lateral relaxation. The strain at the interfaces affects the bandgap of the structure locally which directly changes the properties of the device. The strain in InAs/InP nanowire heterostructures has been measured and modelled using high resolution TEM techniques and finite element calculations as well as multi slice simulations. The TEM experimental measurement results correspond well with the finite element model which also generates simulated HRTEM images verifying the image processing technique. For a 20 nm thick wire a 10 nm long dislocation free region over the interface is strained with the rest of the wire having a relaxed crystal structure.<br/><br>
<br/><br>
The in-situ microscopy applied in this work is utilising a scanning tunneling microscopy (STM) sample holder combined with TEM imaging to characterise the electrical properties of InAs nanowires. Ohmic contact between the STM-tip and the nanowires has been achieved and electrical measurements have been performed. The current-voltage measurement results are in good agreement with the data obtained by traditional measurements based on lithographic processing techniques.}},
  author       = {{Larsson, Magnus}},
  isbn         = {{978-91-7422-149-7}},
  keywords     = {{Nanowires; magnetic resonance; supraconductors; magnetic and optical properties; electrical; Condensed matter:electronic structure; fasjämvikt; kristallografi; egenskaper (termiska och mekaniska); crystallography; phase equilibria; Kondenserade materiens egenskaper:struktur; akustik; Condensed matter:stucture; thermal and mechanical properties; optics; acoustics; Elektromagnetism; optik; Electromagnetism; Scanning Tunneling Microscopy; Nanomaterials; III-V Semiconductors; Transmission Electron Microscopy; Inorganic chemistry; Oorganisk kemi; relaxation; spectroscopy; Kondenserade materiens egenskaper:elektronstruktur; egenskaper (elektriska; magnetiska och optiska); supraledare; magnetisk resonans; spektroskopi; materialteknik; Material technology; Materiallära; Semiconductory physics; Halvledarfysik}},
  language     = {{eng}},
  publisher    = {{Polymer och Materialkemi Kemiska Institutionen}},
  school       = {{Lund University}},
  title        = {{Transmission Electron Microscopy of Semiconductor Nanowires}},
  year         = {{2007}},
}