Raw data for following PhD thesis:

Author:		Enrik Nako
Title:		Identification and Characterisation of Point Defects in CVD Diamond
Institution:	The University of Warwick
Submission:	January 2020

Chapter 4:
	Figure 4-5: surveyData.mat
		All non-wavelength columns represent Intensity (arbitrary units)
		Col 1 - Wavelength (nm)
		Col 2 - N-doped (very low)
		Col 3 - N-doped (low)
		Col 4 - N-doped (high) 
		Col 5 - HPHT annealed (2400 degC, low [N])
		Col 6 - HPHT annealed (1600 degC, high [N])
		Col 7 - Si-doped
		Col 8 - B-doped annealed (1500 degC)
		Col 9 - N/Si-doped
Chapter 5:
	Note: 110/111 = applied stress hkl direction
	Figure 5-2: polarisationData110.mat, polarisationData111.mat
		Note: Excitation and detection directions are denoted by 0 = parallel to stress direction, 1 = perpendicular to stress direction
		All non-wavelength columns represent Intensity (arbitrary units)
		Col 1 - Wavelength (nm)
		Col 2 - 00
		Col 3 - Wavelength (nm)
		Col 4 - 10
		Col 5 - Wavelength (nm)
		Col 6 - 01
		Col 7 - Wavelength (nm)
		Col 8 - 11
	Figure 5-3: Dataset across range of stress pressures in GPa of the form date_SiV_946_pressure_temperature_excitation/detection.txt for 110 and 111 stress directions
		Note: Excitation and detection directions are denoted by N = normal (parallel) to stress direction, O = orthogonal (perpendicular) to stress direction
		Col 1 - Wavelength (nm)
		Col 2 - Intensity (arbitrary units)
	Figure 5-4 and 5-5: Dataset across range of temperatures in Kelvin of the form date_SiV_946_pressure_temperature_excitation/detection.txt for 110 stress direction
		Note: Excitation and detection directions are denoted by N = normal (parallel) to stress direction, O = orthogonal (perpendicular) to stress direction
		Col 1 - Wavelength (nm)
		Col 2 - Intensity (arbitrary units)
	Figure 5-6: Similar dataset to Figure 5-3, except that the peak of interest in 976 nm rather than 946 nm
	Figure 5-7: naturalAbundance.mat, enrichedAbundance.txt
		Col 1 - Wavelength (nm)
		Col 2 - Intensity (arbitrary units)
Chapter 6:
	Note: 001/110 = applied stress hkl direction
	Figure 6-2: FTIR.mat, PL.mat
		Col 1: Energy (cm-1), Wavelength (nm)
		Col 2: Absorbance (A), Intensity (arbitrary units)
	Figure 6-3: Dataset (all .mat) with varying treatment (untreated, optical, or thermal) and polarisation (para, perp) relative to growth direction
		Col 1: Energy (cm-1)
		Col 2: Absorbance (A)
	Figure 6-4: Dataset (all .mat) with as-grown/post 1500 degC annealing and polarisation (para, perp) relative to growth direction 
		Col 1: Energy (cm-1)
		Col 2: Absorbance (A)
	Figure 6-5: chargeTransfer7354.mat
		Col 1 - Energy (cm-1)
		Col 2 - Absorbance (A) - Optical treatment
		Col 3 - Energy (cm-1)
		Col 4 - Absorbance (A) - Thermal treatment
		Col 5 - Energy (cm-1)
		Col 6 - Absorbance (A) - Optical treatment
		Col 7 - Energy (cm-1)
		Col 8 - Absorbance (A) - Thermal treatment
	Figure 6-6, 6-7, 6-8, 6-9, 6-10, 6-11 and 6-14: Dataset with varying stress direction, pressures, and polarisations
		Note: Excitation and detection directions are denoted by 0 = parallel to stress direction, 1 = perpendicular to stress direction
		Absorption: Data of the form date_source-grating-detector_polarisation_pressure.dpt (similar to .txt file format)
			Col 1 - Energy (cm-1)
			Col 2 - Absorbance (A)
		Photoluminescence: Data of the form date_detector_1359nm_temperature_pressure_excitation/detection.txt
			Col 1 - Wavelength (nm)
			Col 2 - Intensity (arbitrary units)
	Figure 6-11: See Figure 7-12b
Chapter 7:
	Figure 7-3: C1.mat, C2.mat
		Col 1: Energy (cm-1)
		Col 2: Absorbance (A)
	Figure 7-4: C1/C2-Optical/Thermal.mat
		Col 1: Energy (cm-1)
		Col 2: Absorbance (A)
	Figure 7-5 and 7-6: Dataset across different temperatures and laser on/off of the form sample-temperature-on/off 	
		Col 1: Energy (cm-1)
		Col 2: Absorbance (A)
	Figure 7-7: C1/C2-Para/Perp.mat
		Col 1: Energy (cm-1)
		Col 2: Absorbance (A)	
	Figure 7-9, 7-10 and 7-11: C1/C2-As-grown/annealing_temperature(degC).mat
		Col 1: Energy (cm-1)
		Col 2: Absorbance (A)
	Figure 7-12:
		a: C1-As-grown/annealing_temperature(degC).mat
			Col 1: Energy (cm-1)
			Col 2: Absorbance (A)
		b: C1-As-grown/annealing_temperature(degC)-Para/Perp.mat
			Col 1: Energy (cm-1)
			Col 2: Absorbance (A)		
	Figure 7-13, 7-14 and 7-15: C1/C2_UVVis_AsGrown/annealing_temperature(degC).mat
		Col 1 - Wavelength (nm)
		Col 2 - Absorption Coefficient (cm-1)
	Figure 7-16, 7-18: C1/C2_442and514_Brown
		Col (2n+1, n=0:4) - Wavelength (nm) (442 nm excitation)
		Col (2n+1, n=5:9) - Wavelength (nm) (514 nm excitation)
		Col 2/12 - As-grown
		Col 4/14 - 1000 degC
		Col 6/16 - 1200 degC
		Col 8/18 - 1400 degC
		Col 10/20 - 1500 degC
	Figure 7-17: C1/C2_442and514_Substrate
		Col (2n+1, n=0:4) - Wavelength (nm) (442 nm excitation)
		Col (2n+1, n=5:9) - Wavelength (nm) (514 nm excitation)
		Col 2/12 - As-grown
		Col 4/14 - 1000 degC
		Col 6/16 - 1200 degC
		Col 8/18 - 1400 degC
		Col 10/20 - 1500 degC
	Figure 7-19: C1_442and514_Blue
		Col (2n+1, n=0:4) - Wavelength (nm) (442 nm excitation)
		Col (2n+1, n=5:9) - Wavelength (nm) (514 nm excitation)
		Col 2/12 - As-grown
		Col 4/14 - 1000 degC
		Col 6/16 - 1200 degC
		Col 8/18 - 1400 degC
		Col 10/20 - 1500 degC