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Crystallography

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AvinashAvi110
AvinashAvi110

brief about crystals that helps to read very well

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CRYSTALLOGRAPHY
Matter • Any substance which has mass and occupies space • All physical objects are composed of matter.
Solids: • Objects with definite size and shape are known as solids.  • Incompressible, Rigid, Mechanically strong, Atoms are closely packed. Liquids & Gases: • Atoms or molecules are not fixed and cannot form any shape and size. They gain the shape and size of the container. • Atoms are loosely packed.
i) Crystalline Solids: The solids in which atoms or molecules are arranged in a regular and orderly manner in three dimension are called Crystalline Solids. Ex: i) Metallic: Gold, Silver, Aluminium ii) Non-Metallic: Diamond, Silicon, Quartz,Graphite etc., Solids are classified into two categories
ii) Amorphous Solids The solids in which atoms or molecules are not arranged in a regular and orderly manner in three dimension are called Amorphous Solids Ex: Glass, Plastic, rubber
Crystalline Solids Amorphous Solids 1.Atoms or molecules have regular periodic arrangements 2.They are anisotropic in nature. 3. They exhibit directional properties. 4.They have sharp melting points. 5. Crystal breaks along regular crystal planes and hence the crystal pieces have regular shape Ex: Copper, Silver, Aluminium etc Atoms or molecules are not arranged in a regular periodic manner. They have random arrangement. They are isotropic in nature. They do not exhibit directional properties. They do not possess sharp melting points Amorphous solids breaks into irregular shape due to lack of crystal plane. Ex: Glass, Plastic, rubber, etc. Differences between Crystalline solid and Amorphous solid
CRYSTAL STRUCTURE
Crystal lattice (Space lattice) Defined as 3-dimensional array of points are spatially arranged in specific pattern. Or It is geometric arrangement of matters (atoms, ions, molecules) Characters of lattice
Unit Cell • The smallest possible portion or geometrical figure of crystal lattice and which buildup by repetition in three dimensions, is called unit cell. (or) • It is a fundamental elementary pattern. • This unit cell is basic structural unit or building blocks of the crystal structure
Characters of unit cell
UNIT CELL TYPESUNIT CELL TYPES Primitive lattice (P) Centered lattice (I): • Primitive lattice (P) : In this lattice the unit cell consists of eight corner atoms.
Centered lattice (I): • Body Centered Unit Cells • Face Centered Unit Cells • End Centered Unit Cells Body Centered Unit Cells(B)
• Face Centered lattice (F):
• Base Centered lattice (C): • In this lattice along with the corner atoms, the base and opposite face will have centre atoms
Crystal Element Face Edge Solid angle These 3 crystal elements be an a mathematical relationship is called a Euler’s Formula Euler’s formula is F + A=E+2
Euler’s Formula: F+A=E+2 Where, F=Number of Face. A=Number of solid angle. E=Number of Edges. Name Faces Solid angles Edges F+A=E+2 Tetrahedron 4 4 6 8=8 Cube 6 8 12 14=14 Octahedron 8 6 12 14=14 Dodecahedro 12 20 30 32=32
The angle found between a pair of adjacent faces of a crystal.. Interfacial angle
Crystal Symmetry It explains how similar atoms or group of atoms (motif) repeated symmetrically in space to produce ordered structure . It can be studied with the help of operation than can be operated on the crystals known as Symmetry Operation
Symmetry operation Is an operation that can be performed either physically or imaginatively on crystal with reference to Plane, Axis, Point within its mass. Symmetry operation achieved by •Rotating the crystal in particular axis •Select the plane which shows mirror image •Select the point which shows equidistance
This is a line about which the crystal may be rotated so as to show the same view of the crystal more than once per rotation.
There are four axis of symmetry :- • On the rotation about the axis, if the same faces or same view occurs 2 times, the axis termed as Diad axis or two fold axis. D:2fold.avi • On the rotation about the axis, , if the same faces or same view occurs 3 times, the axis termed as Triad axis or three fold axis. D:3 fold.avi • On the rotation about the axis, if the same faces or same view occurs 4 times, the axis termed as Tetrad axis or four fold axis. D:4 fold.avi • On the rotation about the axis, , if the same faces or same view occurs 6 times, the axis termed as Hexad axis or six fold axis.
Symmetry CharactersSymmetry Characters Centre of SymmetryCentre of Symmetry Plane of SymmetryPlane of Symmetry Axes of SymmetryAxes of Symmetry PresentPresent 0909 II fold axesII fold axes III fold axesIII fold axes IV fold axesIV fold axes VI fold axesVI fold axes 0606 0404 0303 --
Centre of Symmetry:- It is a imaginary point in the crystal that any line drawn through it intersects the surface of the crystal at equal distance on either side Center of symmetry is the point from which all similar faces are equidistant.
Crystallographic Axes A set of reference axes in a crystal that are used to describe the crystal systems
Crystal System or Lattice system: Crystal system refers to Geometry of crystal and crystal structure and which can be described by set of reference axes (crystallographic axes) . Types Of Crystal System
ISOMETRIC OR CUBIC SYSTEM Symmetry CharactersSymmetry Characters Centre of SymmetryCentre of Symmetry Plane of Symmetry Plane of Symmetry Axes of SymmetryAxes of Symmetry PresentPresent 0909 II fold axesII fold axes III fold axesIII fold axes IV fold axesIV fold axes VI fold axesVI fold axes 0606 0404 0303 --
TETRAGONAL CRYSTAL SYSTEMS Symmetry CharactersSymmetry Characters Centre of SymmetryCentre of Symmetry Plane of Symmetry Plane of Symmetry Axes of SymmetryAxes of Symmetry PresentPresent 0505 II fold axesII fold axes III fold axesIII fold axes IV fold axesIV fold axes VI fold axesVI fold axes 0404 -- 0101 --
ORTHORHOMBIC CRYSTAL SYSTEMS Symmetry CharactersSymmetry Characters Centre of SymmetryCentre of Symmetry Plane of Symmetry Plane of Symmetry Axes of SymmetryAxes of Symmetry PresentPresent 0303 II fold axesII fold axes III fold axesIII fold axes IV fold axesIV fold axes VI fold axesVI fold axes 0303 -- -- --
MONOCLINIC CRYSTAL SYSTEMS Symmetry CharactersSymmetry Characters Centre of Symmetry Centre of Symmetry Plane of Symmetry Plane of Symmetry Axes of SymmetryAxes of Symmetry PresentPresent 0101 II fold axes II fold axes III fold axes III fold axes IV fold axes IV fold axes VI fold axes VI fold axes 0101 -- -- --
TRICLINIC CRYSTAL SYSTEMS Symmetry CharactersSymmetry Characters Centre of Symmetry Centre of Symmetry Plane of Symmetry Plane of Symmetry Axes of SymmetryAxes of Symmetry PresentPresent -- II fold axesII fold axes III fold axes III fold axes IV fold axes IV fold axes VI fold axes VI fold axes -- -- -- --
HEXAGONAL CRYSTAL SYSTEMS Symmetry CharactersSymmetry Characters Centre of SymmetryCentre of Symmetry Plane of Symmetry Plane of Symmetry Axes of SymmetryAxes of Symmetry PresentPresent 0707 II fold axesII fold axes III fold axesIII fold axes IV fold axesIV fold axes VI fold axesVI fold axes 0606 -- -- 0101 Symmetry Characters(trigonal)Symmetry Characters(trigonal) Centre of SymmetryCentre of Symmetry Plane of Symmetry Plane of Symmetry Axes of SymmetryAxes of Symmetry PresentPresent 0303 II fold axesII fold axes III fold axesIII fold axes IV fold axesIV fold axes VI fold axesVI fold axes 0303 0101 -- ----
CRYSTALLOGRAPHIC PLANES z x y a b c Crystal plane may be defined as imaginary plane (or indeed any parallel plane) in the crystal which intersects the main crystallographic axes of the crystal
CRYSTALLOGRAPHIC NOTATION Crystallographic notation is the method or symbolic representation of relationship of any crystal face to crystallographic axes . This crystallographic notation system can be explained by two methods. • Weiss parameter • Miller indices
WEISS PARAMETER (Weiss notation/ Weiss indices) These are the relative numbers of at which given crystal face cuts the crystallographic axes. Or The distance from the origin at which crystal face intercept the crystallographic axes. z x y a b c
The most general expression for Weiss parameter is na:mb:pc Where n, m, p are the length cut off by the face on the a, b, & c axes respectively
• Miller Indices are a symbolic representation for the orientation of plane in a crystal & are defined as the reciprocals of the fractional intercepts which the plane makes with the crystallographic axes. • Most common Millerian symbol is h,k,l
To find the Miller indices of a plane, take the following steps: 1. Determine the intercepts of the plane along each of the three crystallographic directions. 2. Take the reciprocals of the intercepts. 3. If fractions result, multiply each by the denominator of the smallest fraction.
61 CRYSTALLOGRAPHIC PLANES example a b c z x y a b c 4. Miller Indices (200) 1. Intercepts 1/2 ∞ ∞ 2. Reciprocals 1/½ 1/∞ 1/∞ 2 0 0 3. Reduction 2 0 0 z x y a b c 4. Miller Indices (110) 1. Intercepts 1 1 ∞ 2. Reciprocals 1/1 1/1 1/∞ 1 1 0 3. Reduction 1 1 0 example a b c
62 Axis X Y Z Intercept points 1 ∞ ∞ Reciprocals 1/1 1/ ∞ 1/ ∞ Smallest Ratio 1 0 0 Miller İndices (100) Example-1 (1,0,0)
63 Axis X Y Z Intercept points 1 1 ∞ Reciprocals 1/1 1/ 1 1/ ∞ Smallest Ratio 1 1 0 Example-2 (1,0,0) (0,1,0)
64 Axis X Y Z Intercept points 1 1 1 Reciprocals 1/1 1/ 1 1/ 1 Smallest Ratio 1 1 1 (1,0,0) (0,1,0) (0,0,1) Example-3
65 Axis X Y Z Intercept points 1/2 1 ∞ Reciprocals 1/(½) 1/ 1 1/ ∞ (1/2, 0, 0) (0,1,0) Example-4
Crystal formA crystal form is a set of crystal faces that are related to each other by symmetry.   Types of crystal form Crystal forms are broadly classified into two types 1. Closed Forms 2. Open Forms
There are 48 possible forms, those are mainly classified as 1.Common form in non-isomeric system (38) 2.Common form in isometric system(10)  
1. Pedions 2. Pinacoids 3. Domes (dihedron) 4. Sphenoids 5. Prisms(7) 6. Pyramids(7) 7. Dipyramids or Bipyramids(7) 8. Trapezohedron(3) 9. Scalenohedrons(2) 10. Rhombohedrons Common form in non-isomeric system Trigonal prism:  Ditrigonal prism:  Rhombic prism:  Tetragonal prism: Ditetragonal prism: Hexagonal prism:  Dihexagonal prism: Trigonal pyramid: Ditrigonal pyramid: Rhombic pyramid: Tetragonal pyramid: Ditetragonal pyramid: Hexagonal pyramid; Dihexagonal pyramid: Trigonal dipyramid: Ditrigonal dipyramid: Rhombic dipyramid: Tetragonal dipyramid: Ditetragonal dipyramid: Hexagonal dipyramid: Dihexagonal dipyramid: Trigonal Trapezohedron: Tetragonal Trapezohedron: Hexagonal Trapezohedron Tetragonal Scalenohedron: Hexagonal Scalenohedron Tetragonal Disphenoid
Common form in isometric system 1. Hexahedron or cube 2. Dodecahedron (rhombic dodecahedron) 3. Octahedron 4. Tetra hexahedron 5. Trapezohedron 6. Tetrahedron 7. Gyroid 8. Pyritohedron 9. Diploid 10. Tetartoid
1. Pyramids(7) Trigonal pyramid:   Ditrigonal pyramid: Rhombic pyramid:  Tetragonal pyramid:  Ditetragonal pyramid: Hexagonal pyramid; Dihexagonal pyramid:   Rhombic pyramid:  A pyramid is a open form composed 3, 4, 6, 8 or 12 non-parallel face, where all faces in the form meet at common point and each face intersect all three crystallographic axis
Trigonal pyramid:   Ditrigonal pyramid: Rhombic pyramid:  Tetragonal pyramid:  Ditetragonal pyramid: Hexagonal pyramid; Dihexagonal pyramid:   Trigonal pyramid:  3-faced form where all faces are related by a 3-fold rotation axis. Ditrigonal pyramid: 6-faced form where all faces are related by a 3-fold rotation axis.
Trigonal pyramid:   Ditrigonal pyramid: Rhombic pyramid:  Tetragonal pyramid:  Ditetragonal pyramid: Hexagonal pyramid; Dihexagonal pyramid:    Rhombic pyramid: 4-faced form where the faces are related by mirror planes..  Tetragonal pyramid: 4-faced form where the faces are related by a 4 axis. In the drawing the small triangular faces that cut the corners represent the tetragonal pyramid.
 Ditetragonal pyramid: 8-faced form where all faces are related by a 4 axis.  In the drawing shown here, the upper 8 faces belong to the ditetragonal pyramid form.  • Hexagonal pyramid: 6-faced form where all faces are related by a 6 axis. If viewed from above, the hexagonal pyramid would have a hexagonal shape. • Dihexagonal pyramid: 12-faced form where all faces are related by a 6-fold axis. This form results from mirror planes that are parallel to the 6-fold axis.
pyramids or Bipyramids(7) Trigonal dipyramid:  Ditrigonal dipyramid:  Rhombic dipyramid Tetragonal dipyramid:  Ditetragonal dipyramid: Hexagonal dipyrami Dihexagonal dipyramid:  Rhombic dipyramid: Dipyramids are closed forms consisting of 6, 8, 12, 16, or 24 faces.  Dipyramids are pyramids that are reflected across a mirror plane. 
Pyramids(7)
Prisms(7) Trigonal prism:  Ditrigonal prism:  Rhombic prism:  Tetragonal prism: Ditetragonal prism: Hexagonal prism:  Dihexagonal prism: Rhombic prism
Trigonal prism:   3 - faced form with all faces parallel to a 3 -fold rotation axis Trigonal prism:  Ditrigonal prism:  Rhombic prism:  Tetragonal prism: Ditetragonal prism: Hexagonal prism:  Dihexagonal prism: Ditrigonal prism:  6 - faced form with all 6 faces parallel to a 3-fold rotation axis.  i.e. it does not have 6-fold rotational symmetry.
Rhombic prism:  4 - faced form with all faces parallel to a line that is not a symmetry element.  In the drawing to the right, the 4 shaded faces belong to a rhombic prism.    Trigonal prism:  Ditrigonal prism:  Rhombic prism:  Tetragonal prism: Ditetragonal prism: Hexagonal prism:  Dihexagonal prism: Tetragonal prism: 4 - faced open form with all faces parallel to a 4-fold rotation axis.  The top and bottom faces make up the a form called the top/bottom pinacoid.
Trigonal prism:  Ditrigonal prism:  Rhombic prism:  Tetragonal prism: Ditetragonal prism: Hexagonal prism:  Dihexagonal prism: • Ditetragonal prism: 8 - faced form with all faces parallel to a 4-fold rotation axis.  In the drawing, the 8 vertical faces make up the ditetragonal prism. • Hexagonal prism:  6 - faced form with all faces parallel to a 6-fold rotation axis. Again the faces on top and bottom are the top/bottom pinacoid form.
Dihexagonal prism: 12 - faced form with all faces parallel to a 6- fold rotation axis. Note that a horizontal cross-section of this model would have apparent 12-fold rotation symmetry.  The dihexagonal prism is the result of mirror planes parallel to the 6-fold rotation axis. Trigonal prism:  Ditrigonal prism:  Rhombic prism:  Tetragonal prism: Ditetragonal prism: Hexagonal prism:  Dihexagonal prism:
8. Scalenohedrons(2) Tetragonal Scalenohedron: Hexagonal Scalenohedron Tetragonal Scalenohedron: Hexagonal Scalenohedron
8. Trapezohedron(3) Trigonal Trapezohedron: Tetragonal Trapezohedron: Hexagonal Trapezohedron Trigonal Trapezohedron: Tetragonal Trapezohedron: Hexagonal Trapezohedron
Common form in isometric system 1. Hexahedron or cube 2. Dodecahedron (rhombic dodecahedron) 3. Octahedron 4. Tetra hexahedron 5. Trapezohedron 6. Tetrahedron 7. Gyroid 8. Pyritohedron 9. Diploid 10. Tetartoid
Hexahedron or cube A hexahedron is a general form with 6 squares at 900 angle to each other. Each faces intersection crystallographic axis and parallel to others.  4-fold axes are perpendicular to the face of the cube. Octahedron An octahedron is an 8-faced form, faces are equilateral triangle shape, and these are meeting at common point. That results form a three 4-fold axes with perpendicular mirror planes.    Common form in isometric system
  Dodecahedron (rhombic dodecahedron) A dodecahedron is a closed 12- rhomb shape faced form. Each faces intersect two crystallographic axes are parallel to other one axis.  Tetra hexahedron The tetra hexahedron is a 24-isosceles triangular faced form with all faces are parallel to one of the a axes, and intersect the other 2 axes at different lengths.   Common form in isometric system
Trapezohedron An isometric trapezohedron is a 12-faced closed form with all faces intersect two of the a axes at equal length and intersect the third a axis at a different length.  Tetrahedron The tetrahedron is a form composed 4equilateral triangular faces, each of which intersects all the three crystallographic axes at equal lengths.   Common form in isometric system
Gyroid A gyroid is a form in the crystal that has note no mirror planes and This form has no center of symmetry. Pyritohedron The pyritohedron is a 12-faced form that occurs in the crystal and each of the faces that make up the form have 5 sides.   Common form in isometric system
Diploid The diploid is the general form for the diploid.  Tetartoid Tetartoids are general forms in the tetartoidal class which only has 3-fold axes and 2-fold axes with no mirror planes.  Common form in isometric system

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Crystallography

  • 2. Matter • Any substance which has mass and occupies space • All physical objects are composed of matter.
  • 3. Solids: • Objects with definite size and shape are known as solids.  • Incompressible, Rigid, Mechanically strong, Atoms are closely packed. Liquids & Gases: • Atoms or molecules are not fixed and cannot form any shape and size. They gain the shape and size of the container. • Atoms are loosely packed.
  • 4. i) Crystalline Solids: The solids in which atoms or molecules are arranged in a regular and orderly manner in three dimension are called Crystalline Solids. Ex: i) Metallic: Gold, Silver, Aluminium ii) Non-Metallic: Diamond, Silicon, Quartz,Graphite etc., Solids are classified into two categories
  • 5. ii) Amorphous Solids The solids in which atoms or molecules are not arranged in a regular and orderly manner in three dimension are called Amorphous Solids Ex: Glass, Plastic, rubber
  • 6.
  • 7. Crystalline Solids Amorphous Solids 1.Atoms or molecules have regular periodic arrangements 2.They are anisotropic in nature. 3. They exhibit directional properties. 4.They have sharp melting points. 5. Crystal breaks along regular crystal planes and hence the crystal pieces have regular shape Ex: Copper, Silver, Aluminium etc Atoms or molecules are not arranged in a regular periodic manner. They have random arrangement. They are isotropic in nature. They do not exhibit directional properties. They do not possess sharp melting points Amorphous solids breaks into irregular shape due to lack of crystal plane. Ex: Glass, Plastic, rubber, etc. Differences between Crystalline solid and Amorphous solid
  • 9. Crystal lattice (Space lattice) Defined as 3-dimensional array of points are spatially arranged in specific pattern. Or It is geometric arrangement of matters (atoms, ions, molecules) Characters of lattice
  • 10.
  • 11.
  • 12. Unit Cell • The smallest possible portion or geometrical figure of crystal lattice and which buildup by repetition in three dimensions, is called unit cell. (or) • It is a fundamental elementary pattern. • This unit cell is basic structural unit or building blocks of the crystal structure
  • 14. UNIT CELL TYPESUNIT CELL TYPES Primitive lattice (P) Centered lattice (I): • Primitive lattice (P) : In this lattice the unit cell consists of eight corner atoms.
  • 15. Centered lattice (I): • Body Centered Unit Cells • Face Centered Unit Cells • End Centered Unit Cells Body Centered Unit Cells(B)
  • 16. • Face Centered lattice (F):
  • 17. • Base Centered lattice (C): • In this lattice along with the corner atoms, the base and opposite face will have centre atoms
  • 18.
  • 19. Crystal Element Face Edge Solid angle These 3 crystal elements be an a mathematical relationship is called a Euler’s Formula Euler’s formula is F + A=E+2
  • 20.
  • 21. Euler’s Formula: F+A=E+2 Where, F=Number of Face. A=Number of solid angle. E=Number of Edges. Name Faces Solid angles Edges F+A=E+2 Tetrahedron 4 4 6 8=8 Cube 6 8 12 14=14 Octahedron 8 6 12 14=14 Dodecahedro 12 20 30 32=32
  • 22. The angle found between a pair of adjacent faces of a crystal.. Interfacial angle
  • 23. Crystal Symmetry It explains how similar atoms or group of atoms (motif) repeated symmetrically in space to produce ordered structure . It can be studied with the help of operation than can be operated on the crystals known as Symmetry Operation
  • 24. Symmetry operation Is an operation that can be performed either physically or imaginatively on crystal with reference to Plane, Axis, Point within its mass. Symmetry operation achieved by •Rotating the crystal in particular axis •Select the plane which shows mirror image •Select the point which shows equidistance
  • 25.
  • 26.
  • 27.
  • 28. This is a line about which the crystal may be rotated so as to show the same view of the crystal more than once per rotation.
  • 29. There are four axis of symmetry :- • On the rotation about the axis, if the same faces or same view occurs 2 times, the axis termed as Diad axis or two fold axis. D:2fold.avi • On the rotation about the axis, , if the same faces or same view occurs 3 times, the axis termed as Triad axis or three fold axis. D:3 fold.avi • On the rotation about the axis, if the same faces or same view occurs 4 times, the axis termed as Tetrad axis or four fold axis. D:4 fold.avi • On the rotation about the axis, , if the same faces or same view occurs 6 times, the axis termed as Hexad axis or six fold axis.
  • 30. Symmetry CharactersSymmetry Characters Centre of SymmetryCentre of Symmetry Plane of SymmetryPlane of Symmetry Axes of SymmetryAxes of Symmetry PresentPresent 0909 II fold axesII fold axes III fold axesIII fold axes IV fold axesIV fold axes VI fold axesVI fold axes 0606 0404 0303 --
  • 31. Centre of Symmetry:- It is a imaginary point in the crystal that any line drawn through it intersects the surface of the crystal at equal distance on either side Center of symmetry is the point from which all similar faces are equidistant.
  • 32. Crystallographic Axes A set of reference axes in a crystal that are used to describe the crystal systems
  • 33. Crystal System or Lattice system: Crystal system refers to Geometry of crystal and crystal structure and which can be described by set of reference axes (crystallographic axes) . Types Of Crystal System
  • 34.
  • 35. ISOMETRIC OR CUBIC SYSTEM Symmetry CharactersSymmetry Characters Centre of SymmetryCentre of Symmetry Plane of Symmetry Plane of Symmetry Axes of SymmetryAxes of Symmetry PresentPresent 0909 II fold axesII fold axes III fold axesIII fold axes IV fold axesIV fold axes VI fold axesVI fold axes 0606 0404 0303 --
  • 36. TETRAGONAL CRYSTAL SYSTEMS Symmetry CharactersSymmetry Characters Centre of SymmetryCentre of Symmetry Plane of Symmetry Plane of Symmetry Axes of SymmetryAxes of Symmetry PresentPresent 0505 II fold axesII fold axes III fold axesIII fold axes IV fold axesIV fold axes VI fold axesVI fold axes 0404 -- 0101 --
  • 37. ORTHORHOMBIC CRYSTAL SYSTEMS Symmetry CharactersSymmetry Characters Centre of SymmetryCentre of Symmetry Plane of Symmetry Plane of Symmetry Axes of SymmetryAxes of Symmetry PresentPresent 0303 II fold axesII fold axes III fold axesIII fold axes IV fold axesIV fold axes VI fold axesVI fold axes 0303 -- -- --
  • 38. MONOCLINIC CRYSTAL SYSTEMS Symmetry CharactersSymmetry Characters Centre of Symmetry Centre of Symmetry Plane of Symmetry Plane of Symmetry Axes of SymmetryAxes of Symmetry PresentPresent 0101 II fold axes II fold axes III fold axes III fold axes IV fold axes IV fold axes VI fold axes VI fold axes 0101 -- -- --
  • 39. TRICLINIC CRYSTAL SYSTEMS Symmetry CharactersSymmetry Characters Centre of Symmetry Centre of Symmetry Plane of Symmetry Plane of Symmetry Axes of SymmetryAxes of Symmetry PresentPresent -- II fold axesII fold axes III fold axes III fold axes IV fold axes IV fold axes VI fold axes VI fold axes -- -- -- --
  • 40. HEXAGONAL CRYSTAL SYSTEMS Symmetry CharactersSymmetry Characters Centre of SymmetryCentre of Symmetry Plane of Symmetry Plane of Symmetry Axes of SymmetryAxes of Symmetry PresentPresent 0707 II fold axesII fold axes III fold axesIII fold axes IV fold axesIV fold axes VI fold axesVI fold axes 0606 -- -- 0101 Symmetry Characters(trigonal)Symmetry Characters(trigonal) Centre of SymmetryCentre of Symmetry Plane of Symmetry Plane of Symmetry Axes of SymmetryAxes of Symmetry PresentPresent 0303 II fold axesII fold axes III fold axesIII fold axes IV fold axesIV fold axes VI fold axesVI fold axes 0303 0101 -- ----
  • 41.
  • 42.
  • 43.
  • 44.
  • 45.
  • 46.
  • 47.
  • 48.
  • 49.
  • 50.
  • 51.
  • 52.
  • 53.
  • 54.
  • 55. CRYSTALLOGRAPHIC PLANES z x y a b c Crystal plane may be defined as imaginary plane (or indeed any parallel plane) in the crystal which intersects the main crystallographic axes of the crystal
  • 56. CRYSTALLOGRAPHIC NOTATION Crystallographic notation is the method or symbolic representation of relationship of any crystal face to crystallographic axes . This crystallographic notation system can be explained by two methods. • Weiss parameter • Miller indices
  • 57. WEISS PARAMETER (Weiss notation/ Weiss indices) These are the relative numbers of at which given crystal face cuts the crystallographic axes. Or The distance from the origin at which crystal face intercept the crystallographic axes. z x y a b c
  • 58. The most general expression for Weiss parameter is na:mb:pc Where n, m, p are the length cut off by the face on the a, b, & c axes respectively
  • 59. • Miller Indices are a symbolic representation for the orientation of plane in a crystal & are defined as the reciprocals of the fractional intercepts which the plane makes with the crystallographic axes. • Most common Millerian symbol is h,k,l
  • 60. To find the Miller indices of a plane, take the following steps: 1. Determine the intercepts of the plane along each of the three crystallographic directions. 2. Take the reciprocals of the intercepts. 3. If fractions result, multiply each by the denominator of the smallest fraction.
  • 61. 61 CRYSTALLOGRAPHIC PLANES example a b c z x y a b c 4. Miller Indices (200) 1. Intercepts 1/2 ∞ ∞ 2. Reciprocals 1/½ 1/∞ 1/∞ 2 0 0 3. Reduction 2 0 0 z x y a b c 4. Miller Indices (110) 1. Intercepts 1 1 ∞ 2. Reciprocals 1/1 1/1 1/∞ 1 1 0 3. Reduction 1 1 0 example a b c
  • 62. 62 Axis X Y Z Intercept points 1 ∞ ∞ Reciprocals 1/1 1/ ∞ 1/ ∞ Smallest Ratio 1 0 0 Miller İndices (100) Example-1 (1,0,0)
  • 63. 63 Axis X Y Z Intercept points 1 1 ∞ Reciprocals 1/1 1/ 1 1/ ∞ Smallest Ratio 1 1 0 Example-2 (1,0,0) (0,1,0)
  • 64. 64 Axis X Y Z Intercept points 1 1 1 Reciprocals 1/1 1/ 1 1/ 1 Smallest Ratio 1 1 1 (1,0,0) (0,1,0) (0,0,1) Example-3
  • 65. 65 Axis X Y Z Intercept points 1/2 1 ∞ Reciprocals 1/(½) 1/ 1 1/ ∞ (1/2, 0, 0) (0,1,0) Example-4
  • 66.
  • 67. Crystal formA crystal form is a set of crystal faces that are related to each other by symmetry.   Types of crystal form Crystal forms are broadly classified into two types 1. Closed Forms 2. Open Forms
  • 68. There are 48 possible forms, those are mainly classified as 1.Common form in non-isomeric system (38) 2.Common form in isometric system(10)  
  • 69. 1. Pedions 2. Pinacoids 3. Domes (dihedron) 4. Sphenoids 5. Prisms(7) 6. Pyramids(7) 7. Dipyramids or Bipyramids(7) 8. Trapezohedron(3) 9. Scalenohedrons(2) 10. Rhombohedrons Common form in non-isomeric system Trigonal prism:  Ditrigonal prism:  Rhombic prism:  Tetragonal prism: Ditetragonal prism: Hexagonal prism:  Dihexagonal prism: Trigonal pyramid: Ditrigonal pyramid: Rhombic pyramid: Tetragonal pyramid: Ditetragonal pyramid: Hexagonal pyramid; Dihexagonal pyramid: Trigonal dipyramid: Ditrigonal dipyramid: Rhombic dipyramid: Tetragonal dipyramid: Ditetragonal dipyramid: Hexagonal dipyramid: Dihexagonal dipyramid: Trigonal Trapezohedron: Tetragonal Trapezohedron: Hexagonal Trapezohedron Tetragonal Scalenohedron: Hexagonal Scalenohedron Tetragonal Disphenoid
  • 70. Common form in isometric system 1. Hexahedron or cube 2. Dodecahedron (rhombic dodecahedron) 3. Octahedron 4. Tetra hexahedron 5. Trapezohedron 6. Tetrahedron 7. Gyroid 8. Pyritohedron 9. Diploid 10. Tetartoid
  • 71.
  • 72.
  • 73.
  • 74. 1. Pyramids(7) Trigonal pyramid:   Ditrigonal pyramid: Rhombic pyramid:  Tetragonal pyramid:  Ditetragonal pyramid: Hexagonal pyramid; Dihexagonal pyramid:   Rhombic pyramid:  A pyramid is a open form composed 3, 4, 6, 8 or 12 non-parallel face, where all faces in the form meet at common point and each face intersect all three crystallographic axis
  • 75. Trigonal pyramid:   Ditrigonal pyramid: Rhombic pyramid:  Tetragonal pyramid:  Ditetragonal pyramid: Hexagonal pyramid; Dihexagonal pyramid:   Trigonal pyramid:  3-faced form where all faces are related by a 3-fold rotation axis. Ditrigonal pyramid: 6-faced form where all faces are related by a 3-fold rotation axis.
  • 76. Trigonal pyramid:   Ditrigonal pyramid: Rhombic pyramid:  Tetragonal pyramid:  Ditetragonal pyramid: Hexagonal pyramid; Dihexagonal pyramid:    Rhombic pyramid: 4-faced form where the faces are related by mirror planes..  Tetragonal pyramid: 4-faced form where the faces are related by a 4 axis. In the drawing the small triangular faces that cut the corners represent the tetragonal pyramid.
  • 77.  Ditetragonal pyramid: 8-faced form where all faces are related by a 4 axis.  In the drawing shown here, the upper 8 faces belong to the ditetragonal pyramid form.  • Hexagonal pyramid: 6-faced form where all faces are related by a 6 axis. If viewed from above, the hexagonal pyramid would have a hexagonal shape. • Dihexagonal pyramid: 12-faced form where all faces are related by a 6-fold axis. This form results from mirror planes that are parallel to the 6-fold axis.
  • 78. pyramids or Bipyramids(7) Trigonal dipyramid:  Ditrigonal dipyramid:  Rhombic dipyramid Tetragonal dipyramid:  Ditetragonal dipyramid: Hexagonal dipyrami Dihexagonal dipyramid:  Rhombic dipyramid: Dipyramids are closed forms consisting of 6, 8, 12, 16, or 24 faces.  Dipyramids are pyramids that are reflected across a mirror plane. 
  • 80.
  • 81.
  • 82. Prisms(7) Trigonal prism:  Ditrigonal prism:  Rhombic prism:  Tetragonal prism: Ditetragonal prism: Hexagonal prism:  Dihexagonal prism: Rhombic prism
  • 83. Trigonal prism:   3 - faced form with all faces parallel to a 3 -fold rotation axis Trigonal prism:  Ditrigonal prism:  Rhombic prism:  Tetragonal prism: Ditetragonal prism: Hexagonal prism:  Dihexagonal prism: Ditrigonal prism:  6 - faced form with all 6 faces parallel to a 3-fold rotation axis.  i.e. it does not have 6-fold rotational symmetry.
  • 84. Rhombic prism:  4 - faced form with all faces parallel to a line that is not a symmetry element.  In the drawing to the right, the 4 shaded faces belong to a rhombic prism.    Trigonal prism:  Ditrigonal prism:  Rhombic prism:  Tetragonal prism: Ditetragonal prism: Hexagonal prism:  Dihexagonal prism: Tetragonal prism: 4 - faced open form with all faces parallel to a 4-fold rotation axis.  The top and bottom faces make up the a form called the top/bottom pinacoid.
  • 85. Trigonal prism:  Ditrigonal prism:  Rhombic prism:  Tetragonal prism: Ditetragonal prism: Hexagonal prism:  Dihexagonal prism: • Ditetragonal prism: 8 - faced form with all faces parallel to a 4-fold rotation axis.  In the drawing, the 8 vertical faces make up the ditetragonal prism. • Hexagonal prism:  6 - faced form with all faces parallel to a 6-fold rotation axis. Again the faces on top and bottom are the top/bottom pinacoid form.
  • 86. Dihexagonal prism: 12 - faced form with all faces parallel to a 6- fold rotation axis. Note that a horizontal cross-section of this model would have apparent 12-fold rotation symmetry.  The dihexagonal prism is the result of mirror planes parallel to the 6-fold rotation axis. Trigonal prism:  Ditrigonal prism:  Rhombic prism:  Tetragonal prism: Ditetragonal prism: Hexagonal prism:  Dihexagonal prism:
  • 87.
  • 88. 8. Scalenohedrons(2) Tetragonal Scalenohedron: Hexagonal Scalenohedron Tetragonal Scalenohedron: Hexagonal Scalenohedron
  • 89. 8. Trapezohedron(3) Trigonal Trapezohedron: Tetragonal Trapezohedron: Hexagonal Trapezohedron Trigonal Trapezohedron: Tetragonal Trapezohedron: Hexagonal Trapezohedron
  • 90.
  • 91. Common form in isometric system 1. Hexahedron or cube 2. Dodecahedron (rhombic dodecahedron) 3. Octahedron 4. Tetra hexahedron 5. Trapezohedron 6. Tetrahedron 7. Gyroid 8. Pyritohedron 9. Diploid 10. Tetartoid
  • 92. Hexahedron or cube A hexahedron is a general form with 6 squares at 900 angle to each other. Each faces intersection crystallographic axis and parallel to others.  4-fold axes are perpendicular to the face of the cube. Octahedron An octahedron is an 8-faced form, faces are equilateral triangle shape, and these are meeting at common point. That results form a three 4-fold axes with perpendicular mirror planes.    Common form in isometric system
  • 93.   Dodecahedron (rhombic dodecahedron) A dodecahedron is a closed 12- rhomb shape faced form. Each faces intersect two crystallographic axes are parallel to other one axis.  Tetra hexahedron The tetra hexahedron is a 24-isosceles triangular faced form with all faces are parallel to one of the a axes, and intersect the other 2 axes at different lengths.   Common form in isometric system
  • 94. Trapezohedron An isometric trapezohedron is a 12-faced closed form with all faces intersect two of the a axes at equal length and intersect the third a axis at a different length.  Tetrahedron The tetrahedron is a form composed 4equilateral triangular faces, each of which intersects all the three crystallographic axes at equal lengths.   Common form in isometric system
  • 95. Gyroid A gyroid is a form in the crystal that has note no mirror planes and This form has no center of symmetry. Pyritohedron The pyritohedron is a 12-faced form that occurs in the crystal and each of the faces that make up the form have 5 sides.   Common form in isometric system
  • 96. Diploid The diploid is the general form for the diploid.  Tetartoid Tetartoids are general forms in the tetartoidal class which only has 3-fold axes and 2-fold axes with no mirror planes.  Common form in isometric system