Sub-wavelength optical phenomena and their applications in nano-fabrication

Shao, Dongbing

28 August 2008

Not available / text

Photonics

Near-field microscopy

Nanotechnology

A study on the complex evanescent focal region of a high numerical aperture objective and its applications

Jia, Baohua.

January 2006

Thesis (PhD) - Swinburne University of Technology, Faculty of Engineering and Industrial Sciences, Centre for Micro-Photonics, 2005. / A thesis submitted for the degree of Doctor of Philosophy, Centre for Micro-Photonics, Faculty of Engineering and Industrial Sciences, Swinburne University of Technology, 2005. Typescript. Bibliography: p. 129-142.

Nano-Raman spectroscopy and surface nanostructuring using near-field optics

Yi, Kaijun.

January 2008

Thesis (Ph.D.)--University of Nebraska-Lincoln, 2008. / Title from title screen (site viewed Mar. 10, 2009). PDF text: xv, 182 p. : ill. (some col.) ; 6 Mb. UMI publication number: AAT 3331444. Includes bibliographical references. Also available in microfilm and microfiche formats.

Sub-wavelength optical phenomena and their applications in nano-fabrication

Shao, Dongbing,

January 1900

Thesis (Ph. D.)--University of Texas at Austin, 2006. / Vita. Includes bibliographical references.

Morphology dependent resonance of a microscope and its application in near-field scanning optical microscopy

Morrish, Dru, DruMorrish@gmail.com

January 2005

In recent times, near-field optical microscopy has received increasing attention for its ability to obtain high-resolution images beyond the diffraction limit. Near-field optical microscopy is achieved via the positioning and manipulation of a probe on a scale less than the wavelength of the incident light. Despite many variations in the mechanical design of near-field optical microscopes almost all rely on direct mechanical access of a cantilever or a derivative form to probe the sample. This constricts the study to surface examinations in simple sample environments. Distance regulation between the sample surface and the delicate probe requires its own feedback mechanism. Determination of feedback is achieved through monitoring the shift of resonance of one arm of a 'tuning fork', which is caused by the interaction of the probes tip with the Van der Waals force. Van der Waals force emanates from atom-atom interaction at the top of the sample surface. Environmental contamination of the sample surface with additional molecules such as water makes accurate measurement of these forces particularly challenging. The near-field study of living biological material is extremely difficult as an aqueous environment is required for its extended survival. Probe-sample interactions within an aqueous environment that result in strong detectable signal is a challenging problem that receives considerable attention and is a focus of this thesis. In order to increase the detectible signal a localised field enhancement in the probing region is required. The excitation of an optically resonant probe by morphology dependent resonance (MDR) provides a strong localised field enhancement. Efficient MDR excitation requires important coupling conditions be met, of which the localisation of the incident excitation is a critical factor. Evanescent coupling by frustrated total internal reflection to a MDR microcavity provides an ideal method for localised excitation. However it has severe drawbacks if the probe is to be manipulated in a scanning process. Tightly focusing the incident illumination by a high numerical aperture objective lens provides the degree of freedom to enable both MDR excitation and remote manipulation. Two-photon nonlinear excitation is shown to couple efficiently to MDR modes due to the high spatial localisation of the incident excitation in three-dimensions. The dependence of incident excitation localisation by high numerical aperture objective on MDR efficiency is thoroughly examined in this thesis. The excitation of MDR can be enhanced by up to 10 times with the localisation of the incident illumination from the centre of the microcavity to its perimeter. Illuminating through a high numerical aperture objective enables the remote noninvasive manipulation of a microcavity probe by laser trapping. The transfer of photon momentum from the reflection and refraction of the trapping beam is sufficient enough to exert piconewtons of force on a trapped particle. This allows the particle to be held and scanned in a predictable fashion in all three-dimensions. Optical trapping removes the need for invasive mechanical access to the sample surface and provides a means of remote distance regulation between the trapped probe and the sample. The femtosecond pulsed beam utilised in this thesis allows the simultaneous induction of two-photon excitation and laser trapping. It is found in this thesis that a MDR microcavity can be excited and translated in an efficient manner. The application of this technique to laser trapped near-field microscopy and single molecule detection is of particular interest. Monitoring the response of the MDR signal as it is scanned over a sample object enables a near-field image to be built up. As the enhanced evanescent field from the propagation of MDR modes around a microcavity interacts with different parts of the sample, a measurable difference in energy leakage from the cavity modes occurs. The definitive spectral properties of MDR enables a multidimensional approach to imaging and sensing, a focus of this thesis. Examining the spectral modality of the MDR signal can lead to a contrast enhancement in laser trapped imaging. Observing a single MDR mode during the scanning process can increase the image contrast by up to 1:23 times compared to that of the integrated MDR fluorescence spectrum. The work presented in this thesis leads to the possibility of two-photon fluorescence excitation of MDR in combination with laser trapping becoming a valuable tool in near- field imaging, sensing and single molecule detection in vivo. It has been demonstrated that particle scanned, two-photon fluorescence excitation of MDR, by laser trapping 'tweezers' can provide a contrast enhancement and multiple imaging modalities. The spectral imaging modality has particular benefits for image contrast enhancements.

Laser manipulation (Nuclear physics)

Near-field microscopy

Development of near-field scanning optical microscopy for studies of heterogeneity in organic thin films

Kwak, Eun-soo.

January 2002

Thesis (Ph. D.)--University of Texas at Austin, 2002. / Vita. Includes bibliographical references. Available also from UMI Company.

Employing near-field scanning optical microscopy (NSOM) as a tool for interrogating a new conjugated polymer material, di-dodecyl poly(phenylene ethynylene)

Imhof, Joseph Michael

28 August 2008

Chemistry and Biochemistry / Not available / text

Near-field microscopy

Thin films

Polymers

Interference and laser feedback optical microscopy

Rea, Nigel P.

January 1995

This thesis concerns the development of simple, compact scanning optical microscopes which can obtain confocal and interference images. The effects of feeding the reflected signal back into the laser cavity of a confocal microscope are investigated and exploited. Monomode optical fibres are used to perform the spatial filtering required for confocal microscopy and, later, as the source of reference beams for interferometry. The theory describing the basic operation of the microscopes is developed. The optical systems are modelled using scalar diffraction theory and the effects of optical feedback into the laser cavity are described, with the practical implications emphasised. A fully reciprocal arrangement of the microscope is developed, in which a single mode optical fibre both launches the signal towards the object and then collects the reflected signal. The fibre is shown to exhibit the spatial filtering properties required for the source and detector in a confocal microscope. It is shown that a semiconductor laser can be used as a detector of the amplitude of the object signal. This is first demonstrated by directing the microscope signal back into the laser cavity and measuring the variation of the optical intensity in the cavity itself. Comparable results are obtained when the variation of the junction voltage across the cavity is measured. It is also shown that the optical fibre is redundant in this system, since the lasing mode of the cavity itself is sufficiently small to adequately spatially filter the reflected signal. When a Helium-Neon laser is used as the source of illumination the effect of the feedback on the laser is seen to be very different, resulting in interferometry. It is shown that high frequency modulation techniques can be used to obtain both confocal images and surface profiles from the same system. This is first demonstrated using an optical feedback scheme in which the modulation of the optical path length of the object beam is controlled electrooptically. In an alternative scheme the images are obtained by calculation, rather than by using a control loop system. In this case the modulation is achieved mechanically. The theoretical limits for the resolutions of the systems described are discussed. It is shown that the lateral resolution of the surface profile systems is inherently non-linear with feature height. Finally, a semiconductor laser based microscope is developed which can obtain confocal images and surface profiles independently. The dependence of the wavelength on the injection current is exploited as a convenient means of introducing a phase shift into the feedback signal by which profilometry can be achieved. All the systems are described theoretically and demonstrated experimentally.

535

Optical properties of zinc oxide nanostructure materials using near-field scanning optical microscopy /

Xiao, Zhizhao.

January 2007

Thesis (M.Phil.)--Hong Kong University of Science and Technology, 2007. / Includes bibliographical references (leaves 41-42). Also available in electronic version.

Characterisation of near-field optical trapping and biological applications

Varghese, Smitha.

January 2007

Thesis (PhD) - Swinburne University of Technology, Faculty of Engineering and Industrial Sciences, Centre for Micro-Photonics, 2007. / A thesis submitted for the degree of Doctor of Philosophy, Centre for Micro-Photonics, Faculty of Engineering and Industrial Sciences, Swinburne University of Technology, 2007. Typescript. Bibliography: p. 135-153.