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Solid State Physics (1) Phys3710 Crystal structure 4 Lecture 4

Solid State Physics (1) Phys3710 Crystal structure 4 Lecture 4. Department of Physics. Dr Mazen Alshaaer Second semester 2013/2014. Ref.: Prof. Charles W. Myles, Department of Physics, Texas Tech University. THE MOST IMPORTANT CRYSTAL STRUCTURES. Sodium Chloride Structure Na + Cl -

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Solid State Physics (1) Phys3710 Crystal structure 4 Lecture 4

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  1. Solid State Physics (1) Phys3710 Crystal structure 4 Lecture 4 Department of Physics Dr Mazen Alshaaer Second semester 2013/2014 Ref.: Prof. Charles W. Myles, Department of Physics, Texas Tech University

  2. THE MOST IMPORTANT CRYSTAL STRUCTURES Sodium Chloride Structure Na+Cl- Cesium Chloride Structure Cs+Cl- Hexagonal Closed-Packed Structure Diamond Structure Zinc Blende Crystal Structure 2

  3. 1 – Sodium Chloride Structure Sodium chloride also crystallizes in a cubic lattice, but with a different unit cell. The sodium chloride structure consists of equal numbers of sodium & chlorine ions placed at alternate points of a simple cubic lattice. Each ion has six of the other kind of ions as its nearest neighbors. Crystal Structure 3

  4. NaCl Structure

  5. This structure can also be considered as a face-centered-cubic Bravais lattice with a basis consisting of a sodium ion at 0 and a chlorine ion at the center of the conventional cell, at position LiF,NaBr,KCl,LiI, have this structure. The lattice constants are of the order of 4-7 Angstroms.

  6. Take the NaCl unit cell & remove all “red” Cl ions, leaving only the “blue” Na. Comparing this with the fcc unit cell, it is found to be that they are identical. So, the Na ions are on a fcc sublattice. NaCl Structure Crystal Structure 7

  7. NaCl Type Crystals

  8. 2 - CsCl Structure

  9. Cesium chloride crystallizes in a cubic lattice.  The unit cell may be depicted as shown.(Cs+  is teal, Cl- is gold). Cesium chloride consists of equal numbers of cesium and chlorine ions, placed at the points of a body-centered cubic lattice so that each ion has eight of the other kind as its nearest neighbors.  2 - CsCl Structure Crystal Structure 10

  10. CsCl Structure The translational symmetry of this structure is that of the simple cubic Bravais lattice, and is described as a simple cubic lattice with a basis consisting of a cesium ion at the origin 0 and a chlorine ion at the cube center CsBr,CsI crystallize in this structure.The lattice constants are of the order of 4 angstroms.

  11. CsCl Structure 8 cells

  12. CsCl Crystals

  13. 4 - Diamond Structure The diamond lattice consists of 2 interpenetrating FCC lattices. 8 atoms in the unit cell. Each atom bonds covalently to 4 others equally spaced about a given atom. The Coordination Number = 4. The diamond lattice is not a Bravais lattice. C, Si, Ge and Sn crystallize in the diamond structure. Crystal Structure 14

  14. The Zincblende Structurehas equal numbers of zinc and sulfur ions distributed on a diamond lattice, so that each has 4 of the opposite kind as nearest-neighbors. This structure is an example of a lattice with a basis, both because of the geometrical position of the atoms& because two types of atoms occur. Some compounds with this structure are: AgI,GaAs,GaSb,InAs, .... 5 – Zinc Blende or ZnS Lattice

  15. 5 – Zinc Blende or ZnS Structure

  16. Each of the unit cells of the 14 Bravais lattices has one or more types of symmetry properties, such as inversion, reflection or rotation,etc. ELEMENTS OF SYMMETRY Crystal Structure 17

  17. Typical symmetry properties of a lattice. That is, some types of operations that can leave a lattice invariant. Crystal Structure 18

  18. Inversion A center of inversion: A point at the center of the molecule. (x,y,z) --> (-x,-y,-z) A center of inversion can only occur in a molecule. It is not necessary to have an atom in the center (benzene, ethane). Tetrahedral, triangles, pentagons don't have centers of inversion symmetry. All Bravais lattices are inversion symmetric. Mo(CO)6 Crystal Structure 19

  19. A plane in a cell such that, when a mirror reflection in this plane is performed, the cell remains invariant. Reflection Through a Plane Crystal Structure 20

  20. Examples A triclinic lattice has no reflection plane. A monoclinic lattice has one plane midway between and parallel to the bases, and so forth. Crystal Structure 21

  21. Rotation Symmetry There are always a finite number of rotational symmetries for a lattice. • A single molecule can have any degree of rotational symmetry, but an infinite periodic lattice – can not. Crystal Structure 22

  22. 90° Rotational Symmetries 120° 180° • This is an axis such that, if the cell is rotated around it through some angles, the cell remains invariant. • The axis is called n-fold if the angle of rotation is 2π/n. Crystal Structure 23

  23. Axes of Rotation Crystal Structure 24

  24. Axes of Rotation Crystal Structure 25

  25. 5-Fold Symmetry This type of symmetry is not allowed because it can not be combined with translational periodicity! Crystal Structure 26

  26. Group Discussion Kepler wondered why snowflakes have 6 corners,never5 or 7. By considering the packing of polygons in 2 dimensions, demonstrate why pentagons and heptagons shouldn’t occur. Empty space is not allowed Crystal Structure 27

  27. Examples A Triclinic Lattice has no axis of rotation. A Monoclinic Lattice has a 2-fold axis (θ= 2π/2 =π) normal to the base. 90° Crystal Structure 28

  28. Examples Crystal Structure 29

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