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Dive into the world of symmetry, where invisible operations on atomic points create aesthetically pleasing patterns. Explore topics including point symmetry, rotation elements, mirror planes, and chiral molecules. Understand how symmetry operations like rotations, mirrors, inversions, and improper rotations affect molecular arrangements. Discover the fascinating uses and consequences of symmetry in chemistry and aesthetics, unraveling the secrets of hidden transformations that shape the beauty around us.
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SYMMETRY SYMMETRY A Science of Aesthetics Transformations You Cannot See.
Topics • Point Symmetry Operations, E C i S • Classes • Point Groups • Identification Scheme • Uses and Consequences
Symmetry Operations on Points • The nuclei of molecules are the points. • Symmetry operations transform identical nuclei into themselves. • After such operations, the molecule looks absolutely unchanged. • Nature finds all these ways to fool you, so symmetry has Entropy consequences! • We must be able to identify the operations too.
The Identity Operation, E • One way of finding a molecule is after nothing has been done to it! That counts. • 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.” • CBrClFI, bromochlorofluoroiodomethane, has E as its only symmetry operation, for example.
The Rotation Element, Cn • Axes can often be found in molecules around which rotation leaves the atoms identical. • An n-fold rotation, if present, is symbolized by the elementCn., and represents n–1 rotational operations about the axis. • Each operation is a rotation through yet another 360°/n, but the operation C1 is merely E.
Finding Rotations • Symmetrical molecules often have rotation axes through their atoms. • SF6 is octahedral and has fourfold axes through the atoms F–S–F that invisibly cycle the remaining 4 fluorine atoms. • But the axes need not pierce any atom! • The crown-shaped S8 molecule also has a C4, but it goes through the empty center.
Molecules may have many rotation axes. E.g., S8 has four C2 axes, one through each pair of bonds opposing across the middle. Only one of these is shown in the molecular model above. But the axis with the highest n is designated as the principal axis. It is used to find other operations, and often lends its name to the symmetry of the molecule. In S8, that would be the C4 axis. Principal Axis
Remember the trick for drawing tetrahedra like that for CCl4? The chlorines occupy opposite corners on opposite faces of the cube. Like this … That purple C3 axis is one of 4 diagonals of the cube on which you could spin the molecular top. But what about the 3 C2 axes straight through each face? Only 1 shown here. Inobvious Axes
Mirror Planes, • Reflection in a mirror leaves some molecules looking identical to themselves. • What distinguishes these operations is the physical placement of the mirror so that the image coincides with the original molecule! • There are 3 types of mirror planes: • Vertical, horizontal, and dihedral?!?
Vertical Mirrors, v • If the reflection plane contains the Principle Axis, it is called a “vertical mirror plane.” • Just as rotation axes need not pierce atoms, neither do v, but they often do. E.g., in SF4, the principle axis is C2. The two reflection planes are both “vertical” and happen to contain all of the atoms in the molecule.
Horizontal Mirror, h • Horizontal is to vertical so you can infer that h is to the Principle Axis. • While a molecule might have several vertical mirrors, it can have only one h. In PCl5, the horizontal plane is obvious. It’s what we’ve been calling the equatorial plane that contains the three 120° separated chlorines. (The polar axis is C3.)
Dihedral Mirror, d • Greek “two-sided” doesn’t help. • All planes are two-sided! • In symmetry it means vertical planes that lie between the C2 axes the Principal Axis. • E.g., in S8 above, one of S8’s four dihedral planes contains the C4 Principal Axis and bisects the adjacent C2 axes. • The plane contains opposite sulfur atoms,
The Magic of Mirrors • Rotations and the identity operation do not rearrange a molecule in any way. • But mirrors (and inverse and improper rotations) do. • Mirror planes reflect a mirror image whose “handedness” has changed. Left right. • “Chiral” molecules have mirror images that cannot be superimposed on the original! So they cannot have a . You’d see the change.
Caraway flavor agent S-Carvone Spearmint flavor agent R-Carvone Chiral Molecules These molecules cannot be aligned.
SF6 Inversion, i • Mirrors merely transpose along one axis (their axis), but inversion transposes atoms along all 3 axes at once. • i is like xyz so points (x,y,z)(–x,–y,–z) • Therefore, there must be identical atoms opposite one another through the center of the molecule.
Improper Rotation, Sn • Proper rotations (Cn) do not rearrange the molecule, but improper rotations (Sn) do; they are rotations by 360°/nfollowed byreflection in a plane to the Sn axis. • For Sn to be, neither Cn nor the need exist! • To see that, consider the molecule S8 above; believe it or not, it has an S8 axis coincident with the C4 Principle Axis. Clearly there are seven S8 operations.
Point Groups • “Point” refers to atoms, and “Group” refers to the collection of symmetry operations a molecule obeys. • The group is complete because no sequences of operations ever generates one notin the group! • E.g., H2O, besides E, C2 v and C2. has v and v’ It’s clear that C2•C2 = E, but C2•v=v’needs a little thought. v’
Motivational Factors • The reason we want to know the Point Group of a molecule is that all symmetry consequences are encoded in the Group. • The nature and degeneracies 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.
Common Point Groups • Cs molecules have only E and one . • flat and asymmetrical. • Cnv besides E have Cn and n v planes. • NH3, for example. • Dnh has E, Cn, n C2 axes lying in a h. • like BF3. • Td, Oh, and I are the Groups for • tetrahedral, octahedral, and icosahedral molecules • like CH4, SF6, and C60, for example.
The Grand Scheme, Part I • Is the molecule linear? • If so, does it have inversion, i? • If so, then it is in the group Dh. • If no i, then it’s Ch. • If not linear, has it 2 or more Cn with n>2? • If so, does it have inversion, i? • If noi, then it is Td. • If it has i, then is there a C5? • That C5 means it’s the icosahedral group, I. • But if C5 is absent, it’s the octahedral group, Oh. • If n<2 or there aren’t 2 or more Cn, go to Part II.
The Grand Scheme, Part II • OK, does it have anyCn? • No? How about any? • Has a , thank Lewis, it’s a Cs molecule. • If no , then has it an inversion, i? • If an i, then it’s Ci. • But without the i, it’s only C1 (and it has only E left)! • There is a Cn? OK, pick the highest n and proceed to Part III.
The Grand Scheme, Part III • to the (highest n) Cn, are there n C2 axes? • If so, a h guarantees it’s Dnh. • Without h, are there n d planes? • The dihedrals identify Dnd, without them it’s Dn. • If no C2, • A h makes it Cnh, but without h, • n v would make it Cnv, but if n h are missing, • Is there a 2n-fold improper rotation, S2n? • If so, it’s S2n, but if not, it’s just Cn. • In fewer than 8 questions, we have it!
What we’ve bought. • Cn or Cnv (n>1) means no dipole to axis. • If no polarity along axis, molecule isn’t polar! • No Cnh or D group molecule can be polar. • Molecule can’t be chiralwith an Sn! • But inversion, iisS2; so i counts. • Also a Cn and its h is alsoSn; so they both count too. If present, they deny chirality.
Group Name Pair of C3 operations Order of the Group (# of operations) Identity Trio of v Double Degeneracy Symmetry Species Functions transforming as the symmetry species (e.g. orbitals) Anatomy of a Character Table
y z z z y y y x x x x x x x Motion in NH3, a C3v Molecule What part of a coordinate survives each symmetry operation? E leaves all 12 coordinates alone. Therefore 12 survive. C3 leaves only Nz and –½ each of Nx and Ny. So 1–½–½=0. v leaves only Nx, Nz, H1x, & H1z but makes –1 each for Ny and H1y. So 1+1+1+1–1–1=2.
ammonia motion = 12 0 2 A1 = 1(12) + 2(1)(0) + 3(1)(2) = 18/h = 3A1 A2 = 1(12) + 2(1)(0) + 3(–1)(2) = 6/h = 1A2 E = 2(12) + 2(–1)(0) + 3(0)(2) = 24/h = 4 E
Ammonia Motion = 3A1+A2+4E • Since E is doubly degenerate, that means 3+1+8 = 12 motions (3 coords for 4 atoms). • Since x+y+z+Rx+Ry+Rz = A1+A2+2E, the six vibrations in NH3 must be 2A1+2E.