School of Physics - Theses

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    Developing and applying quantum sensors based on optically addressable spin defects
    Healey, Alexander Joseph ( 2023-04)
    Quantum sensing aims to further our understanding of the natural world and support an upcoming technological revolution by exploiting quantum properties or systems to exceed the performance of classical sensing. Owing to their convenient modes of operation and strong room temperature quantum properties, optically active spin defects hosted within solid state materials have come to prominence as one of the foremost tools of choice in this landscape. Many applications now aim to leverage dense ensembles of such defects to boost measurement sensitivity or scale up, which places greater emphasis on the quality of the host material and sensor production methods since cherry-picking individual defects is no longer an option. The prototypical example of such a defect is the nitrogen-vacancy (NV) centre in diamond, which exhibits remarkable room temperature spin coherence, bestowed upon it by diamond's material properties. In this thesis, we first look at optimising the production of NV ensembles for quantum sensing, aiming to efficiently and cost-effectively produce sensors capable of performing high sensitivity measurements in two key regimes that will be central to the experimental applications explored later. The topics examined are hyperpolarisation of a nuclear spin ensemble on the diamond surface through coupling to an ultra-near-surface NV layer, and investigating the properties of a van der Waals antiferromagnet through widefield NV microscopy. The demands placed on the NV layer for these applications are diverse from one another, with charge stability and quantum coherence properties being vital for the former, and the ability to scalably and reproducibly create layers of known thickness crucial to the latter. In light of these studies, we finally consider whether a different spin system housed within an entirely separate materials system, the boron-vacancy defect in hexagonal boron nitride, may be a suitable alternative to the well-established NV diamond system. We find that the distinct properties of the new host material provide both advantages and disadvantages compared to diamond, and that this system could allow quantum sensing to find even broader scope in the future. By investigating the link between host material properties and the suitability of a quantum sensor for given applications, this thesis provides a unique perspective on the future of the field, which will likely demand more highly specialised and varied sensors.
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    Quantum technology for 3D imaging of single molecules
    Perunicic, Viktor ( 2018)
    Biochemical processes are conducted by interactions of individual molecules that comprise cells. It is the transient physical shape of proteins that dictates their specific functionality. However, imaging individual instances of single molecular structures is one of the notable challenges in structural biology. Presently available protein structure reconstruction techniques, Nuclear Magnetic Resonance (NMR) spectroscopy, X-ray crystallography and cryogenic Electron microscopy (cryo-EM), cannot provide images of individual molecules. Despite their power and their complementary capabilities, said techniques produce only average molecular information. They achieve this by sampling large ensembles of molecules in nearly identical conformational states. As a result, individual instances of a generic, inhomogeneous or unstable atomic structures presently remain beyond reach. We seek to address this problem in a novel way by leveraging quantum technologies. In quantum computing, qubits are usually arranged in grids and coupled to one another in a highly organised manner. However, what if a qubit was coupled to an organic cluster of nuclear spins instead, e.g. that of a single molecule? What can be done with such a system in the context of quantum control and 3D imaging of individual molecular systems? What are its ultimate limits and possibilities? We explore those questions in stages throughout the chapters of this thesis. We begin in Chapter 2 by investigating dipole-dipole interactions present between the nuclear spins in a target molecule, on one side, and between an electron-spin based qubit and each of the nuclear target spins on the other. We consider the Nitrogen Vacancy (NV) centre in diamond as an example of a suitable qubit with an active community interest as a biocompatible nano-magnetometer. Our intention is to lay down foundations that will help us advance from magnetometry to 3D molecular imaging. Our inspiration comes from drawing parallels between the single molecule sensing in the qubit-target system and the clinical Magnetic Resonance Imaging (MRI). An MRI machine directly images a single, specific sample in its native state regardless of its characteristics. That is precisely what we would like to achieve on the molecular level. In Chapter 3, we develop a framework that allows a spin qubit to serve as a platform for 3D atomic imaging of molecules with Angstrom resolution. It uses an electron spin qubit simultaneously as a detector and as a gradient field provider for MRI-style imaging. We develop a theoretical quantum control methodology that allows dipole-dipole decoupling sequences used in solid-state NMR to be interleaved with the gradient field provided by the qubit. In Chapter 4, we propose group-V donors in silicon as a novel qubit platform for bioimaging. Actively researched for quantum computing purposes, such qubits have not been considered in the biological context. A prime example of this class of qubits is the phosphorus donor in silicon (Si:P). We show how its specific set of properties, including long coherence times, large wave function and low operational temperatures can be leveraged for the purposes of atomic level imaging. Finalising the work in Chapter 5, we simulate the imaging process for one transmembrane protein of the influenza virus embedded in a lipid membrane. This demonstration highlights the potential of silicon spin qubits in the future development of in situ single molecule imaging at sub-Angstrom resolution.
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    Flexible electrodes for neural recording, stimulation and neurochemical sensing
    Hejazi, Maryam Alsadat ( 2020)
    This thesis focuses on the development of implantable neural interfaces to perform multifunctional neural recording, neural stimulation and biochemical sensing. Neural interfacing devices using penetrating electrodes have emerged as an important tool in both neuroscience research and medical applications. These implantable electrodes enable communication between man-made devices and the nervous system by detecting and/or evoking neuronal activities. Recent years have seen a rapid development of electrodes fabricated using flexible, ultrathin microwires/microfibers. Compared to the arrays fabricated with rigid materials and larger cross sections, these microwires/microfibers have been shown to reduce foreign body response after implantation, with improved signal-to-noise ratio for neural recording and enhanced resolution for neural stimulation. Carbon fibers (CFs) are considered for implant into particular tissue types since they have small size, cause less tissue damage, and are flexible. CF recording electrodes have shown promise as recording electrodes and have the properties necessary to form sensing electrodes. Micron-scale electrodes such as CFs are expected to evoke localized neural responses due to localized electric fields. CFs are traditionally used with fast-scan cyclic voltammetry to study rapid neurotransmitter changes in vivo and in vitro, as they allow real-time detection of catecholamines with high sensitivity and selectivity. However, they possess narrow usable voltage range, which limits their application for neural stimulation. Additionally, surface fouling occurs with certain neurochemicals potentially obstructing further neurotransmitter adsorption onto the electrode surface. Therefore, they need to be coated with other materials to boost their electrochemical properties for neural stimulation. In this thesis, diamond and diamond-like materials, in particular nitrogen doped ultrananocrystalline diamond (NUNCD) hybrid and boron doped carbon nanowall (B-CNW) are considered as coatings for CFs to enhance properties towards neural interface applications. A focus is finding acceptable properties for recording, stimulation and neurochemical sensing. Novel fabrication techniques were developed to deposit the films onto the surface of CFs. Firstly, the surface of CFs was amine-functionalised and covalent bonds were formed with oxygen terminated nanodiamonds. Films were grown on the treated/seeded fibers using plasma-assisted chemical vapor deposition. To fabricate single fiber electrodes, individual fibers were insulated with capillary glass with 100 micrometer of fiber exposed. The physical and chemical properties of NUNCD hybrid and B-CNW were characterized and studied. The results from electrochemical characterization, in conjunction with both in vitro and in vivo assessments, suggest that these electrodes offer a highly functional alternative to conventional electrode materials for both recording and stimulation, yielding safe charge injection capacities up to 25.08 +-12.37 mC/cm2. To test the capability of electrodes for neural stimulation in vitro, explanted wholemount rat retina was used. The electrodes could elicit localized stimulation responses in the explanted retina. These electrodes with micron -scale cross sections have the potential to improve the spatial resolution for stimulation while minimizing axon bundle activation. In vivo and in vitro single-unit recording showed that the electrodes could detect signals with high signal-to-noise ratios up to 8.7. NUNCD hybrid coated CFs were able to electrochemically detect dopamine with high sensitivity and selectivity. Such electrodes are needed for the next generation of miniaturized, closed-loop implants that can self-tune therapies by monitoring both electrophysiological and biochemical biomarkers.
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    Practical Aspects of the Preparation of NV Centers In Diamond for Quantum Applications and Magnetometry
    Genish, Hadar ( 2018)
    This thesis present the result of four experimental projects, that revolve around the practical aspects of using NV centers for quantum applications. The core of the this work deals with the coherence time of NV centers and how it is affected by damage introduced into the diamond lattice by ion implantation where we have discovered that while the emission of the NV center is sensitive to the damage the coherence time is not. The other topics of this work cover a novel method to deposit isolated nano diamond using aerosols and a method to secure the nano diamonds into silicon substrates using self-assembled mono layers. Finally, the work concludes with a proposal to use the magnetic field produced by spin vortices to increase the coherence time of NV centers where some preliminary result of the spin vortices fabrication are presented.
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    Optimizing diamond for a better neural interface
    Tong, Wei ( 2016)
    This thesis focuses on the optimization of the biological and electrochemical properties of diamond for a better neural interface. Neural interfaces create links between the nervous system and the outside world and are promising for restoring and enhancing the function of neural tissues lost or damaged due to neural diseases or injuries. Neural interfaces built by diamond aim to function reliably and effectively for a long period of time. In comparison with existing materials used for neural interfaces, diamond has some attractive properties in terms of its well-known chemical and mechanical stability. However, the biological and electrochemical properties of the stimulation and recording electrodes can also determine the success of the devices. The electrodes are required to provide safe, sufficient charge injection for stimulation and exhibit low impedance for high quality recording. The biocompatibility requirements of the electrode materials are also demanding, in order to form close contact with the targeted neurons to decrease the charge injection threshold and to increase the signal amplitude for recording. Unfortunately, the reported diamond electrochemical properties are unsuitable for neural stimulation and recording. Furthermore, the investigation of neuron growth on diamond surfaces is limited. In this thesis, I consider the use of diamond, in particular nitrogen doped ultrananocrystalline diamond (N-UNCD), for neural interfaces by assessing its biocompatibility using in vitro cell culture, and by measuring its electrochemical properties. Both the biocompatibility and electrochemical properties of the as-grown N-UNCD were shown to require improvement before it can be used as a neural interface material. To optimize the diamond surfaces for neural interfaces, I propose and discuss several different strategies. The first set of strategies involve the use of five different surface treatments that are often used as part of sterilization procedures. The resulting change of neuron response and electrochemical properties of N-UNCD was studied, combining the characterization of the physical and chemical properties of N-UNCD. A two-step sterilization method, short oxygen plasma treatment followed by hydrogen peroxide sterilization, was found to be the most useful. Then, I investigated the effect of low-power oxygen plasma on the biological and electrochemical properties of N-UNCD. N-UNCD substrates with low surface roughness and activated by oxygen plasma for 3 hours, were found to show optimal biocompatibility and electrochemical properties for neural interfaces. Finally, the fabrication of diamond electrodes with optimized surface properties for neural interfaces was investigated. A microelectrode pair was fabricated composed of two microelectrodes before and after surface optimization, with the aim of demonstrating the different efficacies for in vitro neural stimulation and recording. Prolonged oxygen plasma treatment was shown to improve the charge injection capacities of electrodes on the Bionic Vision Australia High-Acuity device, beneficial for its application in Epi-retinal stimulation. A diamond electrode array was finally fabricated with low surface roughness. This low roughness diamond electrode array after long time oxygen plasma activation is expected to work as a neural interface with high efficacy and long-term stability.
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    Characterization of silicon and diamond semiconductor devices in the low temperature regime
    Eikenberg, Nina ( 2015)
    At ultra low temperatures, materials reveal interesting behaviours that become evident due to the freezing out of thermal vibrations. We report studies of two important group IV material systems using a newly-commissioned dilution refrigerator at temperatures of less than 50 mK, and under axial magnetic fields of up to 7 Tesla and 1 Tesla in the lateral plane. We realized these magnetic fields with a 3D vector magnet and calibrated the system using well-known test samples. The first material studied in detail was nitrogen enhanced grown ultranano- crystalline diamond (N-UNCD). Diamond displays a combination of many extreme physical properties such as a high thermal conductivity, the highest number density of atoms, and a wide optical band gap, and is in addition to these properties also biocompatible [1]. The ultra-nanocrystalline form of diamond is composed of small, 3-5 nm diameter grains of diamond and shares many of the desirable properties of the single crystal form, but is much easier to produce in thin form and can be used in wide variety of applications [2], especially for nanomechanics due to its strength and high Young's modulus [3]. When doped with boron, nano-crystalline diamond (B-NCD) displays superconducting properties below a critical temperature of less than a few Kelvin [4, 5]. The nitrogen doped form has found application in biomedical devices [6], but its superconducting behaviour at very low temperatures has not yet been demonstrated [7]. We fabricated N-UNCD thin films using microwave-enhanced CVD growth and used optical lithography to create Hall bar designs. We found that the conductivity of N-UNCD decreased with decreasing temperature, and between 36 mK and 4.9 K, a negative magneto-resistance was observed. Fitting the temperature and magnetic field dependent data with the 3D weak localization model developed by Kawabata [8], we found that 3D weak localization indeed plays a main role in the conduction mechanism of N-UNCD films even at ultra low temperatures. The second project was on the characterization of erbium doped silicon (Si:Er) semiconductor devices. Erbium has long been known to be important for use in optical fibre amplification in silica [9], and it also shows strong luminescent properties when it is added to Si as a dopant [10]. As such, Er is also of interest as optoelectronic semiconductor material [11]. Since the recent demonstration that it is possible to optically address single erbium ions in the silicon lattice [12] interest in Si:Er has increased. We studied silicon doped with erbium using ion implantation and report on our attempts to create CMOS devices with Er doped channels. The implanted material was characterized by optical spectroscopy, deep level transient spectroscopy, and measured both electrically and magnetically at low temperatures in the dilution refrigerator. Deep level transient spectroscopy performed on devices with varying anneal temperatures showed the emergence of electronically active traps with the minimum trap density occurring at annealing temperatures above 700 °C. Our results reveal that a rapid thermal anneal at 900 °C activates the luminescence from the implanted erbium ions. This effect remains, even if the sample is subjected to subsequent high temperature treatments. MOS devices co-doped with Er and P were fabricated and characterised to the extent they could be, based on the processing issues that arose.
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    An all-diamond hermetic encapsulation for a high-acuity retinal prosthesis
    LICHTER, SAMANTHA ( 2014)
    Bionic vision through electrical stimulation of the retina is fast becoming a reality. To date, clinical trials have allowed blind patients to see a lover’s smile and navigate night scenes. (K Stingl et al, 2013) This kind of data has encouraged an abundance of research activity. Bionic Vision Australia, among others, is developing a retinal prosthesis to restore high visual acuity. One of its flagship technologies is a diamond electrode array, which will form part of the encapsulation for the implanted electronics. The remainder of the encapsulation also needs to be constructed from leak-proof, or hermetic, materials. The aim of this work was to design and test feasibility of a hermetic encapsulation that incorporated the diamond electrode array. An all-diamond hermetic encapsulation design was proposed, in which a diamond box-shaped capsule was bonded to the diamond array, with the electronics contained inside. Diamond capsules were made from polycrystalline diamond. Laser micromachining was found to be the optimal fabrication method. Hermetic joints were made in diamond using vacuum brazing with precious metal braze alloys. Several brazes were investigated for their ability to wet and form strong bonds with diamond. Bond interfaces were studied for morphology, chemical composition and hermeticity. Brazed diamond capsules were sealed at room temperature using laser microwelding. Welds were optimised for smooth surface morphology and hermeticity. The results demonstrated a hermetic all-diamond encapsulation. Combining the hermetic capsule, the brazing technique, and the welding technique with the diamond electrode array formed a retinal prosthesis technology that can protect against degradation for the lifetime of the patient.
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    Principles and applications of quantum decoherence in biological, chemical, and condensed matter systems
    Hall, Liam Terres ( 2013)
    This thesis focuses on the use of the Nitrogen-Vacancy (NV) defect centre in diamond as a single spin sensor of nanoscale magnetic fields. The NV system has attracted considerable interest in recent years due to its unique combination of sensitivity, nanoscale resolution, room temperature operation, and stable fluorescence, together with the inherent biocompatibility of diamond; making it ideal for measuring coherent quantum processes in biological, chemical and condensed matter systems. Existing NV-based sensing techniques, however, are ultimately limited by sources of magnetic noise that act to destroy the very resource required for their operation: the quantum phase coherence between NV spin levels. We address this problem by showing that this noise is a rich source of information about the dynamics of the environment we wish to measure. We develop protocols by which to extract dynamical environmental parameters from decoherence measurements of the NV spin, and a detailed experimental verification is conducted using diamond nanocrystals immersed in a MnCl2 electrolyte. We then detail how sensitivities can be improved by employing sophisticated dynamic decoupling techniques to remove the decoherence effects of the intrinsic noise, whilst preserving that of the target sample. To characterise the effects of pulse errors, we describe the full coherent evolution of the NV spin under pulse-based microwave control, including microwave driven and free precession intervals. This analysis explains the origin of many experimental artifacts overlooked in the literature, and is applied to three experimentally relevant cases, demonstrating remarkable agreement between theoretical and experimental results. We then analyse and discuss two important future applications of decoherence sensing to biological imaging. The first involves using a single NV centre in close proximity to an ion channel in a cell membrane to monitor its switch-on/switch-off activity. This technique is expected to have wide ranging implications for nanoscale biology and drug discovery. The second involves using an array of NV centres to image neuronal network dynamics. This technique is expected to yield significant insight into the way information is processed in the brain. In both cases, we find the temporal resolution to be of millisecond timescales, effectively allowing for real time imaging of these systems with micrometre spatial resolution. We analyse cases in which environmental frequencies are sufficiently high to result in a mutual exchange of energy with the NV spin, and discuss how this may be used to reconstruct the corresponding frequency spectrum. This analysis is then applied to two ground-breaking experiments, showing remarkable agreement. Protocols for in-situ monitoring of mobile nanodiamonds in biological systems are developed. In addition to obtaining information about the local magnetic environment, these protocols allow for the determination of both the position and orientation of the nanocrystal, yielding information about the mechanical forces to which it is subjected. These techniques are applied in analysing a set of experiments in which diamond nanocrystals are taken up endosomally by human cervical cancer cells. Finally, we focus our attention on understanding the microscopic dynamics of the spin bath and its effect on the NV spin. Many existing analytic approaches are based on simplified phenomenological models in which it is difficult to capture the complex physics associated with this system. Conversely, numerical approaches reproduce this complex behaviour, but are limited in the amount of theoretical insight they can provide. Using a systematic approach based on the spatial statistics of the spin bath constituents, we develop a purely analytic theory for the NV central spin decoherence problem that reproduces the experimental and numerical results found in the literature, whilst correcting the limitations and inaccuracies associated with existing analytical approaches.
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    TEM and structural investigations of synthesized and modified carbon materials
    Lai, Pooi-Fun ( 1999-08)
    Due to the extreme properties of diamond, such as extreme hardness, high thermal conductivity, high electrical breakdown strength, high electron and hole mobilities and large band gap, it is of interest to study this material in detail. Before advantage can be taken of diamond’s properties for high-temperature, high-power electronic applications successful doping/ion implantation of diamond must be achieved. This requires an understanding of the types of defects produced during ion irradiation. In the present work, type IIa diamond has been irradiated with various doses of 320keV Xe ions at room temperature. Analytical techniques used are electron spin resonance spectroscopy, Raman spectroscopy, transmission electron microscopy and electron energy loss spectroscopy. Previous models have suggested that upon ion impact, amorphous and/or graphitized clusters are formed in diamond, which will overlap at a critical dose to form a semi-continuous graphitized layer. (For complete abstract open document)
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    The study of defect and trapping levels in CVD polycrystalline diamond with applications to ultraviolet dosimetry
    TRAJKOV, ELIZABETH ( 2004-05)
    The unique properties of diamond make it an excellent material for electronic and optical applications. It is particularly attractive for ultraviolet radiation dosimetry due to its intrinsic properties, which include biological tissue equivalence and visible blindness. Importantly, the advent of synthetic diamond, especially Chemical Vapour Deposition (CVD) diamond, has made it more economically viable for such applications. A thorough understanding of the electronic properties of diamond is needed before these applications can be fully explored. Consequently, this thesis investigates charge carrier trapping states in CVD polycrystalline diamond for the optimization of ultraviolet radiation dosimetry. The technique of Thermally Stimulated Conductivity (TSC) is used to probe electrically active defects and is also applied for dosimetric read-out. A range of as-grown CVD polycrystalline diamond films are studied to determine attributes that favour dosimetric-related TSC. In doing so, we establish that dosimetric TSC in these films originate from defects at the grain boundaries with a correlation to high crystalline quality. With this finding in hand, we then investigate the possibility of optimising diamond for dosimetry by controllably introducing extrinsic dosimetric defects using ion implantation. However, it is shown that these defects are not suitable for dosimetry and have a detrimental effect on the indigenous TSC signal. This study verifies the importance of crystalline quality on the indigenous dosimetric properties of CVD polycrystalline diamond. The possibility of doping CVD diamond during growth is also investigated as a means for intentionally introducing extrinsic dosimetric defects. Sulphur is selected as the dopant based on the theoretical energy levels formed by this defect, and because the prospect of S doping in diamond remains an actively debated issue in the literature. We report for the first time defect levels extracted from TSC analysis of S-doped CVD diamond and find consistency with theoretical predications. In addition, the dominant TSC trap level in S-doped diamond shows promise for radiation dosimetry with certain properties exceeding many current radiation dosimeters. The experimental results in this thesis lead to a deeper understanding of defect and trapping mechanisms in CVD polycrystalline diamond and establish attributes that favour TSC and related dosimetric properties in such films. This knowledge is fundamental to the realisation of diamond for ultraviolet dosimetry.