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Physical Chemistry

Physical Chemistry. Chapter IV Molecular Symmetry and Point Group. Reference Books : F. Albert, Cotton, Chemical Application of Group Theory , Wiley Press, New York, 1971. ( 中译本 : 群论在化学中的应用 , 科学出版社 ,1984) (2) David M. Bishop, Group Theory and Chemistry , Clarendon Press, Oxford, 1973.

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Physical Chemistry

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  1. Physical Chemistry

  2. Chapter IV Molecular Symmetry and Point Group • Reference Books: • F. Albert, Cotton, Chemical Application of Group Theory, Wiley Press, New York, 1971. • (中译本:群论在化学中的应用,科学出版社,1984) • (2) David M. Bishop, Group Theory and Chemistry, Clarendon Press, Oxford, 1973. • (中译本:群论与化学,高等教育出版社,1984)

  3. Symmetry is all around us and is a fundamental property of nature.

  4. Motivational Factors • The nature and degeneracy of vibrations. • The legitimate AO combinations for MOs. • The appearances and absences of lines in a molecule’s spectrum. • The polarity and chirality of a molecule.

  5. §4-1. Symmetry Elements and Operations The term symmetry is derived from the Greek word “symmetria” which means “measured together”. We require a precise method to describe how an object or molecule is symmetric.

  6. Symmetry Operation A symmetry operation is a movement of a body such that, after the movement has been carried out, every point of the body is coincident with an equivalent point (or perhaps the same point) of the body in its original orientation. Symmetry Element A symmetry element is a geometrical entity such as a line, a plane, or a point, with respect to which one or more symmetry operations may be carried out.

  7. §4-1-1. Symmetry Elements and Operations Required in Specifying Molecular Symmetry

  8. 1. The Identity Operation E Ê • No matter how asymmetrical a molecule is, it must have an identity operation, E • The symbol “E” comes from the German, “eigen,” meaning “the same”

  9. 2. Proper Axes and Proper Rotations Cn • An n-fold rotation is symbolized by the element Cn, and represents n–1 rotational operations about the axis.

  10. Molecules may have many rotation axes. But the axis with the highest n is designated as theprincipal axis • The operation C1 is merely E.

  11. 3. Symmetry Planes and Reflections  • There are 3 types of planes: • Vertical, horizontal and dihedral

  12. Vertical v If the reflection plane contains the Principle Axis, it is called a “vertical plane.”

  13. C h Horizontal plane h If the reflection plane is perpendicular to the Principle Axis, it is called a “horizontal plane.” A molecule can have only one h

  14. Dihedral d Vertical planes which bisect the angles between adjacent pairs of C2 axes perpendicular to the principle axis

  15. 4. Improper Axes and Improper Rotations Sn=Cn h • Rotations by 2/nfollowed byreflection in a plane  to the Sn axis.

  16. 5. The Inversion Center i i = S2 = C2h=hC2 (x, y, z)  (-x, -y, -z)

  17. §4-1-2. Multiplication Table Multiplication Table of H2O C2v E C2sxzsyz E E C2sxzsyz C2 C2 E syzsxz sxzsxzsyz E C2 syzsyzsxz C2 E Operate first Operate second

  18. §4-1-3. General Relations Among Symmetry Elements and Operations (1) The product of two reflections, intersecting at an angle of = 2/2n, is a rotation by 2 about the axis defined by the line of intersection 1. Products

  19. (2) When there is a rotation axis, Cn, and a plane containing it, there must be n such planes separated by angles of 2/2n; (3)The product of two C2 rotations about axes which intersect at an angle  is a rotation by 2 about an axis perpendicular to the plane of the C2 axes; (4) A proper rotation axis of even order and a perpendicular reflection plane generate an inversion center.

  20. 2. Commutation • The identity operation and the inversion with any operations; • Two rotations about the same axis; • Reflections through planes perpendicular to each other; • Two C2 rotations about perpendicular axes; • Rotation and reflection in a plane perpendicular to the rotation axis.

  21. §4-2. Molecular Point Group §4-2-1. Definitions and Theorems of Group Theory 1. Definitions A group is a collection of elements which are interrelated according to certain rules.

  22. The product of any two elements in the group must be an element in the group; • AB=C (2)One element in the group must commute with all others and leave them unchanged; E----the identity elementEX=XE=X (3)The associative law of multiplication must hold; A(BC)=(AB)C (4)Every element must have a reciprocal, which is also an element of the groupAA-1= A-1A= E

  23. 2. Theorems of Group (1) For a certain element, there is only one reciprocal in the group (2)There is only one identity element in one group. (3)The reciprocal of a product of two or more elements is equal to the product of the reciprocals, in reverse order. (ABC·····XY)-1 = Y-1X-1····C-1B-1A-1 (4) If A1, A2 and A3····· are group elements, their product, says B, must be a group element, A1A2A3····· =B

  24. 3. Some Important Conceptions Order----the number of elements in a finite group Finite groups; Infinite groups Subgroup---the smaller groups,whose elements are taken from the larger group {1,-1,i,-i } {1,-1 } 矩阵乘法

  25. Similarity Transform A, B and X are elements of a group, if B=X-1AX We say B is conjugate with A. Class---A complete set of elements which are conjugate to one another

  26. Point group-----All symmetry elements in a molecule intersect at a common point, which is not shifted by any of the symmetry operations. Schoenflies Symbols §4-2-2. Molecular Point Groups

  27. Cn groups---only one Cn Axis n Cn symmetry operations, g=n C1 CFClBrI

  28. C2 (E, C2)

  29. C3 C3 C3, (E, C3, C32)

  30. 2. Cnh groups: Cn add a horizontal plane h g=2n n=1, C1h= Cs Cnh =Sn

  31. Cs H2TiO HOCl CH3OH

  32. C2h (E, C2, h, i) Trans-C2H2Cl2 

  33. C3h(E, C3, C32, h, S3, S32) B(OH)3, planar

  34. 3. Cnv groups: g=2n Cn add a vertical plane v C2v (E, C2, 1, 2) H2O

  35. C3 staggered-C2H3F3 C3v (E, 2C3, 3v) NH3

  36. C4v C6v OXeF4

  37. Cv: C+v AB type of diatomic molecules C v

  38. 4. Sn groups---with only one Sn Axis • When n is odd, Sn = Cnh • When n is even, the group is called Sn and consists of n elements • S2=Ci, S4, S6

  39.  i trans-C2H2F2Cl2Br2 Ci

  40. S4 S4

  41. 5. Dn groups Cn axis add n C2 axes perpendicular to Cn (g=2n) D3

  42. 6. Dnh groups Dn group + h nC2Cn, h Cnh =Sn C2h = n v g=4n

  43. D2h E, 3C2, s2=i, h, 2v ethylene B4(CO)2

  44. D3h Ph(Ph)3

  45. D4h PtCl4 2- CAl4- Mn2(CO)10

  46. D6h D5h

  47. Dh: C v+h A2 type of diatomic molecules C h

  48. 7. Dnd groups Dn + d d Cn n d d C2 S2n g=4n

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