symmetry elements and operations ppt
TRANSCRIPT
- 1. SYMMETRY ELEMENTS AND OPERATIONS PROF. SOURABH MUKTIBODH OLD GDC, INDORE The symmetry properties of molecules can be used to predict vibrational spectra, hybridization, optical activity, simplifying calculations in quantum mechanics etc. SOURABH MUKTIBODH
- 2. THE TERM SYMMETRY IS ASSOCIATED WITH- 1. Beauty 2. Regularity 3. Periodicity 4. Harmonicity and 5. Systemization In geometrical objects. (molecules for chemist) SOURABH MUKTIBODH
- 3. GEOMETRICAL OBJECTS SOURABH MUKTIBODH
- 4. AND THE MONUMENTS SOURABH MUKTIBODH
- 5. THE EIFFIL TOWER SOURABH MUKTIBODH
- 6. BEAUTIFUL COLLOIDAL NANO-PARTICES - LOOK HOW BEAUTIFUL THEY ARE. SOURABH MUKTIBODH
- 7. THE QUESTION IS- How to quantify this beauty aspect ? and The answer is. SOURABH MUKTIBODH
- 8. SYMMETRY ELEMENTS AND OPERATIONS Symmetry elements are geometrical entities such as a plane, an axis (of rotation), centers (of inversion), etc., through which a symmetry operation can be performed. A molecule has a given symmetry element if the operation leaves the molecule looks as if nothing has changed (even though atoms and bonds may have been moved). A symmetry operation produces a superimposable configuration. (equivalent or identical configuration.) SOURABH MUKTIBODH
- 9. SYMMETRY ELEMENTS Element Symmetry Operation Symbol Identity E n-fold axis Rotation by 2/n Cn Mirror plane Reflection Center of in- Inversion i version n-fold axis of Rotation by 2/n Sn improper rotation followed by reflection perpendicular to the axis of rotation
- 10. IDENTITY, E All molecules have Identity. This operation leaves the entire molecule unchanged. A highly asymmetric molecule such as a tetrahedral carbon with 4 different groups attached has only identity, and no other symmetry elements. It also signifies operation of doing nothing. It is there for mathematical reasons., such as in Group theory. Note- some chemists do not consider this as an operation. SOURABH MUKTIBODH
- 11. N-FOLD AXIS OF ROTATION Ammonia has a C3 axis. Note that there are two operations associated with the C3 axis. Rotation by 120o in a clockwise or a counterclockwise direction provide two different orientations of the molecule. SOURABH MUKTIBODH
- 12. LET US ROTATE BENZENE MOLECULE BY 60 DEGREE, PERPENDICULAR TO THE MOLECULAR PLANE C6 1 = C6 1 C6 2 = C3 1 C6 3 = C2 1 C6 4 = C3 2 C6 5 = C6 5 C6 6 = E Thus a C6 axis generates only two genuine C6 operations. Others can be seen as lower order operations. A C6 thus generates- 2 C6 ,2 C3 , 1C2 1 2 6 3 5 4 6 1 5 2 4 3 5 6 4 1 3 2 4 5 3 6 2 1 3 4 2 5 1 6 2 3 1 4 5 SOURABH MUKTIBODH
- 13. A MOLECULE MAY CONTAIN SEVERAL AXES ( HIGHEST ORDER AXIS IS KNOWN AS PRINCIPAL AXIS), SAY FOR EXAMPLE IN BORON TRIFLUORIDE MOLECULE- C3 1 , C3 2 ,3 C2 B F 2 F 1 F 3 SOURABH MUKTIBODH
- 14. FIND THE HIGHEST ORDER AXIS IN THE FOLLOWING MOLECULES- Choloromethane ferrocynide ion H ClH Cl SOURABH MUKTIBODH
- 15. Cl B Cl Cl Cl O O O O O O biphenyl 18-crown-6 SOURABH MUKTIBODH
- 16. MIRROR PLANES/ SYMMETRY The reflection of the water molecule in either of its two mirror planes results in a molecule that looks unchanged. A plane of reflection bisects the molecule into equal halves. This operation is denoted by . SOURABH MUKTIBODH
- 17. REFLECTING TWICE BY THE SAME PLANE OF COURSE GIVES ORIGINAL CONFIGURATION - Plane of symmetry or mirror plane does not generate number of symmetry operations. As it is obvious that- 1 = 2 = E 3 = 4 = E Thus n = if n= odd and n = E if n = even SOURABH MUKTIBODH
- 18. TYPES OF MIRROR PLANES- THEY HAVE BEEN CLASSIFIED AS OF THREE TYPES- 1. vertical plane of reflection- denoted by v 2. Horizontal plane of of reflection - denoted by h 3. Dihedral plane of reflection - denoted by d SOURABH MUKTIBODH
- 19. MIRROR PLANES / SYMMETRY The subscript v in v, indicates a vertical plane of symmetry. This indicates that the mirror plane includes the principal axis of rotation (C2). SOURABH MUKTIBODH
- 20. MIRROR PLANES- HORIZONTAL PLANE The benzene ring has a C6 axis as its principal axis of rotation. The molecular plane is perpendicular to the C6 axis, and is designated as a horizontal plane, h. All planar molecules have horizontal plane of reflection. C6 . SOURABH MUKTIBODH
- 21. MIRROR PLANES- DIHEDRAL PLANE The vertical planes, v, go through the carbon atoms, and include the C6 axis. The planes that bisect the bonds are called dihedral planes, d. A dihedral plane passes between two mutually perpendicular C2 C6 . SOURABH MUKTIBODH
- 22. XENON TETRAFLUORIDE MOLECULE CONTAINS ALL THREE TYPES OF PLANES- Xe F F F F Xe F F F F Xe F F F F SOURABH MUKTIBODH
- 23. CENTRE OF INVERSION/ CENTER OF SYMMETRY The inversion operation projects each atom through the center of inversion, and across to the other side of the molecule. This operation is symbolized by i . SOURABH MUKTIBODH
- 24. INVERSION CENTRE We proceed to identify centre of symmetry as following- 1. choose a centre within the molecule. 2. draw lines in the direction where the atoms are located. 3. if the same atom in equal and opposite direction is seen, true for every situation, than the molecule possesses a centre of symmetry. SOURABH MUKTIBODH
- 25. IDENTIFY THE MOLECULES WHICH CONTAIN POINT OF INVERSION H ClH Cl B Cl Cl Cl Cl ClCl SOURABH MUKTIBODH
- 26. IMPROPER ROTATION An improper rotation is rotation, followed by reflection in the plane perpendicular to the axis of rotation. Thus Sn = Cn * i = i * Cn both independent symmetry operations commute. Essentially Cn SOURABH MUKTIBODH
- 27. IMPROPER ROTATION The staggered conformation of ethane has an S6 axis that goes through both carbon atoms. SOURABH MUKTIBODH
- 28. IMPROPER ROTATION Note that an S1 axis doesnt exist; it is same as a mirror plane. S1 = C1 1 * 1 = E * 1 = SOURABH MUKTIBODH
- 29. NOTE THAT SIMILAR TO PROPER ROTATION, IMPROPER ROTATION ALSO GENERATES N-1 OPERATIONS, N BEING THE ORDER OF AXIS-S4 1 = C4 1 * 1 = S4 1 S4 2 = C4 2 * 2 = C2 * E = C2 1 S4 3 = C4 3 * 3 = S4 3 S4 4 = C4 4 * 4 = E * E = E Out of four such combinations, only two are true S4 representations. Thus a S4 axis generates only two genuine symmetry operations. SOURABH MUKTIBODH
- 30. IMPROPER ROTATION Likewise, an S2 axis is a center of inversion. S 2= i SOURABH MUKTIBODH
- 31. EX. IDENTIFY ALL SYMMETRY ELEMENTS AND OPERATIONS OF THE FOLLOWING MOLECULES- O HH N H H H E C2 v v` E C3 3v SOURABH MUKTIBODH
- 32. SIMILARLY IDENTIFY ALL ELEMENTS AND OPERATIONS FOR SYMMETRIC BF3 MOLECULE E C3 1 and C3 2 C2 (Along BF1 bond) C2 (Along BF2 bond) C2 (Along BF3 bond) v (Along BF1 bond) v ` (Along BF2 bond) v (Along BF3 bond) h ( molecular plane) S3 1 and S3 2 B F 2 F 1 F 3 SOURABH MUKTIBODH
- 33. SUMMARY 1. Symmetry elements and operations are though, two slightly different terms, but are often treated collectively. 2. A symmetry operation produces superimposable configuration. 3. There are five fundamental symmetry elements and operations. They are 1. identity (E) 2. proper rotation ( Cn) 3. mirror symmetry or reflection () 4. centre of symmetry or inversion centre (i) and 5. improper rotation.(Sn) 4. A molecule may or may not contain all symmetry elements and operations. More operations present assures more symmetric nature. 5. Symmetry elements and operations allow us to identify point group of the molecule and then detailed applications of group theory can be explored. SOURABH MUKTIBODH
- 34. REFERENCES A.F.Cotton Chemical Applications of Group Theory ISBN 0471510947 Next- Molecular point group SOURABH MUKTIBODH