Properties, processes and surface chemistry at diamond interfaces

Bennett, Andrew Michael

January 2005

No description available.

549.27

Investigations on the origin of brown colouration in diamond

Hounsome, Luke Sebastian

January 2007

No description available.

549.27

Spectroscopic studies of defects in diamond including their formation and dissociation

De Weerdt, Filip

January 2007

No description available.

549.27

Transition metal point defects in diamond

Watkins, Matthew Benjamin

January 2005

No description available.

549.27

The role of fluid in the growth of fibrous diamond : a study of African and Canadian coated diamonds

Tomlinson, Emma Louise

January 2006

This multi-disciplinary study determines the composition and structure of mantle fluid inclusions in natural fibrous diamonds, and their role in diamond growth. Coated diamonds from Mbuji Mayi (Democratic Republic of Congo) and Panda (Canada) were analysed by electron microprobe, laser ablation inductively coupled mass spectrometry and infrared spectroscopy. Carbonate and KC1 are important components of the complex fluid. Therefore, KCI-K2CO3 was used as a solvent catalyst for graphite in high-pressure high-temperature diamond growth experiments. Grown diamonds have skeletal morphologies growth was rapid and occurred at temperatures as low as 1050 °C. Fluid-inclusions in Panda and Mbuji Mayi diamond coats are dominated by liquid water and carbonate. The absence of silicate melt indicates fibrous diamond growth occurred below or close to the host rock solidus. Three end-member fluid compositions are recognised: Fe-Mg-Ca carbonate, KC1 and alumnosilicate. The trace element composition of the Mbuji Mayi coat fluids is consistent with K-rich carbonatite. The carbonate fluid component was derived externally before infiltration into peridotitic and eclogitic growth environments. The silicate fluid is restricted to eclogitic samples and is thought to have been derived locally by reactions between the oxidising fluid and more reduced mantle minerals. Carbonate reduction and crystallisation concentrated KC1. Panda diamond coats contain silicate inclusions whose chemistries indicate formation in eclogitic and peridotitic (lherzolitic) hosts. There fore, diamond coats grow in the same paragenetic environments as octahedral diamonds. Inclusion geothermobarometry indicates that peridotitic inclusions equilibrated at 930-1010 °C and 4.2-4.6 GPa. These conditions are below the lherzolite solidus and are 200 °C lower than inclusions in Panda Octahedral diamonds. A model is presented in which fibrous diamonds grow in a solid host rock containing older octahedral diamonds, following the influx of H2O-rich carbonate melt. This melt metasomatised and fertilised the host rock. Diamond was precipitated by the reduction of carbonate and nucleated on diamond cores.

549.27

A quantum mechanical study of dopants in diamond

Lombardi, Enrico Bruno

11 1900

Physics / D.Phil (Physics)

549.27

Diamonds

Doped semiconductors

Quantum theory

Integrated circuits -- Passivation

A quantum mechanical study of dopants in diamond

Lombardi, Enrico Bruno

11 1900

Physics / D.Phil (Physics)

549.27

Diamonds

Doped semiconductors

Quantum theory

Integrated circuits -- Passivation

Hydrogen and Muonium behaviour in diamond

Joseph, Sithole Makgamathe

31 March 2005

This work is aimed at the understanding of the dynamical behavior of hydrogen in diamond. The investigation was carried out using Transverse Field muon Spin Rotation (TF-SR) and the Longitudinal Field muon Spin Relaxation (LF-SR) techniques. The chemical analogy between hydrogen (p+e-) and muonium (u+e-) enabled the study of the indirect dynamical behavior of hydrogen in diamond. The TF-SR and LF-SR measurements were carried out in an isotopically pure 13C diamond in the temperature ranges 11 mK - 320 K and 10 K - 400 K, respectively. In the TF-SR results, the Prompt Absolute Fraction (PAF) of both diamagnetic and the paramagnetic states are temperature independent. The spin relaxation rate for the state is non-zero and temperature independent, while that of the Mux state is non-zero and temperature dependent. The behavior of indicates that the u+d is immobile, while that of MuT indicates the mobility in diamond. The LF-SR results provide hop rate and associated nuclear hyperfine interaction parameters of the Mut state in diamond. / Physics / M.Sc. (Physics)

Diamond

Muonium

Hydrogen

Diffusion

Relaxation rate

Prompt fraction

Hop rate

Power law dependence

549.27

Diamonds -- Research

Hydrogen -- Isotopes

Muonium

Hydrogen and Muonium behaviour in diamond

Joseph, Sithole Makgamathe

31 March 2005

This work is aimed at the understanding of the dynamical behavior of hydrogen in diamond. The investigation was carried out using Transverse Field muon Spin Rotation (TF-SR) and the Longitudinal Field muon Spin Relaxation (LF-SR) techniques. The chemical analogy between hydrogen (p+e-) and muonium (u+e-) enabled the study of the indirect dynamical behavior of hydrogen in diamond. The TF-SR and LF-SR measurements were carried out in an isotopically pure 13C diamond in the temperature ranges 11 mK - 320 K and 10 K - 400 K, respectively. In the TF-SR results, the Prompt Absolute Fraction (PAF) of both diamagnetic and the paramagnetic states are temperature independent. The spin relaxation rate for the state is non-zero and temperature independent, while that of the Mux state is non-zero and temperature dependent. The behavior of indicates that the u+d is immobile, while that of MuT indicates the mobility in diamond. The LF-SR results provide hop rate and associated nuclear hyperfine interaction parameters of the Mut state in diamond. / Physics / M.Sc. (Physics)

Diamond

Muonium

Hydrogen

Diffusion

Relaxation rate

Prompt fraction

Hop rate

Power law dependence

549.27

Diamonds -- Research

Hydrogen -- Isotopes

Muonium