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 CONTENTS
 ABOUT ORIENTATION IMAGING
 Acknowledgements
 ... using circular polarization: crossed polarizers and two quarterwave plates
 ... using crossed polarizers
 ... using crossed polarizers and lambda plate
 ... using crossed polarizers, lambda plate and narrowband infrared filter
 ...more on the quartz veins from the Tonale fault
 Acknowledgements
 Acquiring
 Analysis of orientation gradient images
 Annealed regime 1, 2 and 3
 CALCULATING THE PRIMARY IMAGES
 Calculation of azimuth, inclination, and error images
 Carrara Marble
 Changes in Micro-shear zone rotation and length
 Checking the inclination image
 Checking the input
 CIP (computer-integrated microscopy) Orientation Imaging
 CIP input
 CIP output
 CIP References
 CIP Software
 Circular polarization micrographs, part I
 Circular polarization micrographs, part II
 Colour look-up tables
 Colour-coding the azimuth image
 Colour-coding the inclination image
 Comparing CIP and EBSD
 Correcting the inclination image
 Dynamic recrystallization of quartzite along deformation gradient
 First round: CIPD & INVPIMA
 Grain boundary detection based on misorientations
 Grain size analysis
 Grain size sensitive texture analysis
 High strain zones and Micro Shears
 Input images
 Introduction
 Lazy grain boundaries
 LAZY GRAIN SIZE ANALYSIS
 Lazy Grainboundaries (Grain boundary detection)
 Lazy LUT
 Lazy stack
 LIBRARY OF ORIENTATION AND MISORIENTATION IMAGES
 List of image sets
 LList of topics
 Making masks from the error and background images
 Making use of sample heterogeneity
 Misorientation analysis of grains undergoing dynamic recrystallization
 Misorientation analysis of host grain - recrystalled grain relation
 Misorientation with respect to reference direction
 Misorientations at grain boundaries
 More detail on the dynamic recrystallization of quartzite
 More detailon regime 1, 2 and 3 of dynamic recrystallization
 NATURAL EXAMPLES
 Optical orientation imaging
 ORIENTATION IMAGES OF EXPERIMENTALLY DEFORMED ROCKS
 Orientation imaging through the light microscope
 Principal misorientation images
 Quartz mylonite from the Corvatsch
 Quartz mylonite from the Simplon fault zone
 Quartz veins from the Tonale fault
 Quartz veins from theGlarus thrust
 Recording the input images
 References
 Regime 1, 2 and 3 of dynamic recrystallization
 Rematching the stack
 Saving input data
 Second round: running CIP2 & INVPIMA
 Setting up the microscope and the scanner
 Setting up the microscope, the scanner and the computer
 Shape - texture relations
 Shear and rotation behaviour on different scales
 SOFTWARE
 Starting material: Black Hills quartzite and Heavitree quartzite
 step 1
 step 1
 step 2
 step 2
 step 3
 step 3
 step 4
 step 5
 step 5
 step 6 7
 step 8 9
 step4
 StripStar
 SUMMARY CIP
 Technical requirements
 The azimuth image
 The c-axis orientation image (COI)
 The c-axis polefigure
 The error image
 The inclination image (amplitude)
 The inclination image (circular polarization)
 The misorientation images
 The orientation gradient images
 Various CLUTs for the c-axis orientation image
 Viewing the output of CIP2
 Viewing the output of CIPD
 VISUALIZING ORIENTATIONS
 WHAT IS ORIENTATION IMAGING ?
 WHERE CAN WE GO FROM HERE ?
 Glossary
 Goals
 Content
 Overview
 Experiments
 Microfabric
 Azimuth
 Configuration
 Domain SPO
 Domain Width
 Experimental Conditions
 Formation of micro-shear zones
 Grain and domain SPO controlled by Micro-shear zones
 Grain size
 Grain SPO
 HT-HS CPO Area
 HT-HS Deformation Mechanism Activity
 HT-HS Grain Size
 HT-HS Mechanism Activity
 HT-HS Microfabric Evolution
 HT-HS Particle Orientation (PAROR)
 HT-HS Textures
 HT-LS CPO Area
 HT-LS Deformation Mechanism Activity
 HT-LS Grain Size
 HT-LS High Strain Zone Evolution
 HT-LS Mechanism Activity
 HT-LS Microfabric Evolution
 HT-LS Particle Orientation (PAROR)
 HT-LS Strain
 HT-LS Surface Orientation (SURFOR)
 HT-LS Textural Evolution
 Inclinations
 IT-HS CPO area
 IT-HS Deformation Mechanism Activity
 IT-HS Grain Size
 It-HS Mechanism Activity
 IT-HS Microfabric Evolution
 IT-HS Particle Orientation (PAROR)
 IT-HS Shear Zone Evolution
 IT-HS Strain
 IT-HS Surface orientation (SURFOR)
 IT-HS Textures
 Localisation by experimental configuration
 LT-HS CPO area
 LT-HS Deformation Mechanism Activity
 LT-HS Grain Size
 LT-HS Mechanism Activity
 LT-HS Microfabric Evolution
 LT-HS Particle orientation (PAROR)
 LT-HS Shear Zones
 LT-HS Strain
 LT-HS Surface orientation (SURFOR)
 LT-HS Textures
 Micro-shear zone history
 Microfabric evolution
 Norcamphor
 Obliquity of Textural Skeleton
 Opening angle
 Rotation paths
 Stability Fields
 Steady state of microfabric elements
 Steady State Textures
 Strain distribution pattern
 Texture Evolution
 Traces of high strain
 Table of contents
 Dedication
 about the authors
 Deformation & reactions
 Deformation and reactions: anorthosites
 Deformation and reactions: granodiorites
 Figur 14
 Figure 1
 Figure 10
 Figure 100
 Figure 11
 Figure 12
 Figure 13
 Figure 15
 Figure 16
 Figure 18
 Figure 19
 Figure 2
 Figure 20
 Figure 21
 Figure 22
 Figure 23
 Figure 24
 Figure 25
 Figure 26
 Figure 27
 Figure 29
 Figure 3
 Figure 30
 Figure 32
 Figure 33
 Figure 34
 Figure 35
 Figure 36
 Figure 37
 Figure 38
 Figure 39
 Figure 4
 Figure 41
 Figure 42
 Figure 43
 Figure 44
 Figure 45
 Figure 46
 Figure 47
 Figure 5
 Figure 5
 Figure 49
 Figure 50
 Figure 51
 Figure 52
 Figure 53
 Figure 54
 Figure 55
 Figure 56
 Figure 57
 Figure 58
 Figure 59
 Figure 6
 Figure 61
 Figure 62
 Figure 63
 Figure 64
 Figure 65
 Figure 66
 Figure 67
 Figure 68
 Figure 69
 Figure 7
 Figure 70
 Figure 71
 Figure 72
 Figure 73
 Figure 74
 Figure 75
 Figure 76
 Figure 77
 Figure 78
 Figure 79
 Figure 8
 Figure 80
 Figure 81
 Figure 82
 Figure 83
 Figure 84
 Figure 85
 Figure 86
 Figure 87
 Figure 88
 Figure 89
 Figure 9
 Figure 90
 Figure 91
 Figure 92
 Figure 93
 Figure 94
 Figure 95
 Figure 96
 Figure 97
 Figure 98
 Figure 99
 Figure17
 Figure28
 Figure31
 Experiemntal qtz-fs: starting material &regime 1
 Experimental feldspar
 Experimental feldspar: cataclastic flow
 Experimental feldspar: regime 1
 Experimental feldspar: starting material
 Experimental pyroxenite & diabase
 Experimental pyroxenite & diabase
 Experimental qtz-fs
 Experimental qtz-fs: annealing & melting
 Experimental qtz-fs: regime2
 Experimental quartz
 Experimental quartz: annealing
 Experimental quartz: semibrittle & regime 1
 Experimental quartz: starting materials
 Experimental quartz: transition regime 2/3 & regime3
 Experimental quartz:regime 2
 Further reading
 Further reading
 Further reading
 Further reading
 Further reading
 Further reading
 Further reading
 How to navigate
 introduction
 Natural feldspar
 Natural feldspar: regime 1
 Natural feldspar: regime 2 highly deformed
 Natural feldspar: regime 2 weakly deformed
 Natural qtz-fs
 Natural qtz-fs: mylonites (Red bank)
 Natural qtz-fs: strong deformation (Mulwarree)
 Natural qtz-fs: ultramylonites (Red bank)
 Natural qtz-fs: weak deformation (Mulwarree)
 Natural quartz
 Natural quartz: GBM
 Natural quartz: Semibrittle & bulging
 Natural quartz: SGR
 Natural quartz: undeformed
 Reference list
 to use as book
 to use as slide collection