Design and Construction of Low-Temperature Scanning Tunnelling Microscope for Spectroscopy
(1998)- Abstract
- This thesis discusses some of the fundamental requirements needed to be fulfilled when constructing a low temperature scanning tunnelling microscope (STM). Three different designs, two non-vacuum and one ultra-high vacuum (UHV), based on either inertial-mass or novel stepper motor principles are presented. The selection rules that forms the basis for designs are discussed in terms of thermophysical properties (such as thermal expansion and conductivity) and mechanical properties (such as stiffness and structural damping), and are exemplified by experimental results both known from literature and as found during the thesis work.
Furthermore, the application of STM as a local probe for investigation of optical properties... (More) - This thesis discusses some of the fundamental requirements needed to be fulfilled when constructing a low temperature scanning tunnelling microscope (STM). Three different designs, two non-vacuum and one ultra-high vacuum (UHV), based on either inertial-mass or novel stepper motor principles are presented. The selection rules that forms the basis for designs are discussed in terms of thermophysical properties (such as thermal expansion and conductivity) and mechanical properties (such as stiffness and structural damping), and are exemplified by experimental results both known from literature and as found during the thesis work.
Furthermore, the application of STM as a local probe for investigation of optical properties of low-dimensional III-V semiconductors at low-temperatures is discussed. Photon emission as a result from local injection of carriers using an STM tip, scanning tunnelling luminescence (STL), has been studied for three different low-dimensional systems: quantum wells (QW), quantum wires (QWR), and quantum dots (QD). It is demonstrated that it is possible to excite an individual low-dimensional structure, using the spatial resolution of the STM. Employed tips have been made of both wide bandgap semiconductors and metalls. (Less)
Please use this url to cite or link to this publication:
https://lup.lub.lu.se/record/18885
- author
- Lindahl, Joakim LU
- supervisor
- opponent
-
- Prof. Shih, C.K., University of Texas in Austin, USA.
- organization
- publishing date
- 1998
- type
- Thesis
- publication status
- published
- subject
- keywords
- mechanical properties, thermophysical properties, stepper motor, ultra-high vacuum, inertial-mass, low temperatures, scanning tunneling microscopy, optical propertie, Fysik, Semiconductory physics, Physics, scanning tunneling luminescence, local probe, photon emission, local carrier injection, Halvledarfysik, Fysicumarkivet A:1998:Lindahl
- pages
- 240 pages
- publisher
- Joakim Lindahl, Örnvägen 78:123, S-22731 Lund, Sweden.,
- defense location
- June 12 at 13.15, Lecture Hall A at Department of Physics.
- defense date
- 1998-06-12 13:15:00
- external identifiers
-
- other:ISRN: LUFTD2/(TFFF-0052)/1-240
- ISBN
- 91-628-3042-2
- language
- English
- LU publication?
- yes
- id
- a8a8a019-0fa3-4b59-950e-343cc188b0e3 (old id 18885)
- date added to LUP
- 2016-04-04 11:59:32
- date last changed
- 2018-11-21 21:08:23
@phdthesis{a8a8a019-0fa3-4b59-950e-343cc188b0e3, abstract = {{This thesis discusses some of the fundamental requirements needed to be fulfilled when constructing a low temperature scanning tunnelling microscope (STM). Three different designs, two non-vacuum and one ultra-high vacuum (UHV), based on either inertial-mass or novel stepper motor principles are presented. The selection rules that forms the basis for designs are discussed in terms of thermophysical properties (such as thermal expansion and conductivity) and mechanical properties (such as stiffness and structural damping), and are exemplified by experimental results both known from literature and as found during the thesis work.<br/><br> <br/><br> Furthermore, the application of STM as a local probe for investigation of optical properties of low-dimensional III-V semiconductors at low-temperatures is discussed. Photon emission as a result from local injection of carriers using an STM tip, scanning tunnelling luminescence (STL), has been studied for three different low-dimensional systems: quantum wells (QW), quantum wires (QWR), and quantum dots (QD). It is demonstrated that it is possible to excite an individual low-dimensional structure, using the spatial resolution of the STM. Employed tips have been made of both wide bandgap semiconductors and metalls.}}, author = {{Lindahl, Joakim}}, isbn = {{91-628-3042-2}}, keywords = {{mechanical properties; thermophysical properties; stepper motor; ultra-high vacuum; inertial-mass; low temperatures; scanning tunneling microscopy; optical propertie; Fysik; Semiconductory physics; Physics; scanning tunneling luminescence; local probe; photon emission; local carrier injection; Halvledarfysik; Fysicumarkivet A:1998:Lindahl}}, language = {{eng}}, publisher = {{Joakim Lindahl, Örnvägen 78:123, S-22731 Lund, Sweden.,}}, school = {{Lund University}}, title = {{Design and Construction of Low-Temperature Scanning Tunnelling Microscope for Spectroscopy}}, year = {{1998}}, }