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1-4-نظریه اوربیتال مولکولی هوکل

1-4-نظریه اوربیتال مولکولی هوکل. در مولکول های مسطح مزدوج، سیستم p را می توان مستقل از چارچوب s در نظر گرفت. (اسکلت s سیستم های مزدوج مسطح درصفحه گرهی سیستم p قرار دارد ودر نتیجه با هم برهم کنش ندارند.)

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1-4-نظریه اوربیتال مولکولی هوکل

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  1. 1-4-نظریه اوربیتال مولکولی هوکل • در مولکول های مسطح مزدوج، سیستم pرا می توان مستقل از چارچوب s در نظر گرفت. (اسکلت s سیستم های مزدوج مسطح درصفحه گرهی سیستم p قرار دارد ودر نتیجه با هم برهم کنش ندارند.) • سیستم پی در تعیین خواص شیمیایی و طیف نگاری پلی ان های مزدوج وترکیبات آروماتیک اهمیت ویژه دارد. • در تقریب HMO تابع موج الکترون های p به صورت ترکیب خطی اوربیتال های pبیان میشود. • ترازهای انرژی وضرایب اتمی از جمله اطلاعاتی هستند که از محاسبات بدست می آیند .

  2. Molecular orbitals for polyatomic systems The Hückel approximation Here, we investigate conjugated molecules in which there is an alternation of single and double bonds along a chain of carbon atoms. In the Hückel approach, the  orbitals are treated separately from the  orbitals, the latter form a rigid framework that determine the general shape of the molecule. All C are considered similar  only one type of coulomb integral  for the C2p atomic orbitals involved in the  molecular orbitals spread over the molecule. A. The secular determinant The  molecular orbitals are expressed as linear combinations of C2pz atomic orbitals (LCAO), which are perpendicular to the molecular plane. Ethene, CH2=CH2: =cAA + cBB, where A and B are the C2pz orbitals of each carbon atoms. Butadiene, CH2=CH-CH=CH2: =cAA + cBB+ccC + cDD The coefficients can be optimized by the same procedure described before: express the total energy E as a function of the ci and then minimize the E with respect to those coefficients ci. Inject the energy solutions in the secular equations and extract the coefficients minimizing E.

  3. Energy in the LCAO approach (1)  Numerator: 1 is a Coulomb integral: it is related to the energy of the e- when it occupies atome 1. ( < 0)  is a Resonance integral: it is zero if the orbital don’t overlap. (at Re, <0)  (1)  Denominator: (1) is the overlap integral related to the overlap of the 2 AO

  4. Let’s find the “zeros” or roots of the polynomial vs. cA and cB We want the cA minimizing E, we then impose: We want the cB minimizing E, we then impose: Secular equations In order to have a solution, other than the simple solution cA= cB= 0, we must have: Secular determinant should be zero The 2 roots give the energies of the bonding and antibonding molecular orbitals formed from the AOs

  5. Homonuclear diatomic molecules: =cAA + cBB with A= B  A= B=  (1) (2) bonding (1) (2) antibonding 0   antibonding= {2(1-S)}-1/2(A - B) bonding= {2(1+S)}-1/2(A + B)

  6. 0  Eantibonding= - E- Ebonding = E+- Since: 0 < S < 1  Eantibonding > Ebonding Note 1: He2 has 4 electrons  ground-state configuration: 12 2*2 He2 is not stable! Note 2: If we neglect the overlap integral (S=0), Eantibonding = Ebonding=   The resonance integral  is an indicator of the strength of covalent bonds

  7. i 2pz i+2 i+1 Following these methods and since A= B= , we obtain those secular determinants:  Ethene, CH2=CH2:  Butadiene, CH2=CH-CH=CH2: Hückel approximation: 1) All overlap integrals Sij= 0 (i j). 2) All resonance integrals between non-neighbors, i,i+n=0 with n 2 3) All resonance integrals between neighbors are equal, i,i+1= i+1,i+2 = Severe approximation, but it allows us to calculate the general picture of the molecular orbital energy levels.

  8. B. Ethene and frontier orbitals Within the Hückel approximation, the secular determinant becomes: E- =  -  energy of theLowest Unoccupied Molecular Orbital (LUMO) E+ =  +  energy of theHighest Occupied Molecular Orbital (HOMO) LUMO= 2* 2|| HOMO= 1  HOMO and LUMO are the frontier orbitals of a molecule.  those are important orbitals because they are largely responsible for many chemical and optical properties of the molecule. Note: The energy needed to excite electronically the molecule, from the ground state 12 to the first excited state 11 2*1is provided roughly by 2|| ( is often around -0.8 eV)  Chap 17

  9. Butadiene and delocalization energy  4th order polynomial  4 roots E There is 1e- in each 2pz orbital of the four carbon atoms  4 electrons to accommodate in the 4 -type molecular orbitals  the ground state configuration is 12 22  The greater the number of internuclear nodes, the higher the energy of the orbital  Butadiene C4H6: total -electron binding energy, E isE = 2E1+2E2= 4 + 4.48 with two -bonds  Ethene C2H4:E = 2 + 2 with one -bond  Two ethene molecules give: E = 4 + 4 for two separated -bonds.  The energy of the butadiene molecule with two -bonds lies lower by 0.48 (-36kJ/mol) than the sum of two individual -bonds: this extra-stabilization of a conjugated system is called the “delocalization energy” 3 nodes = E4 2 nodes = E3 LUMO= 3* = E2 1 node HOMO= 1 = E1 0 node Top view of the MOs

  10. اطلاعات بدست آمده از محاسبات • - ترتیب نسبی ترازهای انرژی • ضرایب اتمی = nتعداد اتم های کربن زنجیر = nتعداد اتم های کربن حلقه

  11. Energy Levels for Linear Polyenes a: Coulomb Integral • : Resonance Integral n: Number of Carbons j: Specified Carbon Number

  12. - ضرایب اتمی: • Orbital coefficients: are given by n - total number of atoms in the conjugated chain r - atom number ( i.e. 1, 2, …., n ) j - quantum number, identifying the MO ( = 1, 2, …., n )

  13. E =  + mj ترازهای انرژی • Note that the cosine function varies only between the limiting values of –1 and +1. = nتعداد اتم های کربن حلقه

  14. Energy Levels for 1,3,5-Hexatriene

  15. Delocalization Energy (DE) for 1,3,5-Hexatriene with Respect to Localized System 6pElectrons fill three Y1, Y2, andY3orbitals and therefore:

  16. Contribution Coefficient to of the 2p AO of Atom “r” to The jth MO r = 1 then j = 1,2,…n r = 2 then j = 1,2,…n .... …. ….. ….. …. r = n then j = 1,2,…n

  17. for n odd for n even Energy Levels for Planar and Conjugated Cyclic Systems

  18. Frost Circles • Frost circle: a graphic method for determining the relative order of pi MOs in planar, fully conjugated monocyclic compounds • inscribe a polygon of the same number of sides as the ring to be examined such that one of the vertices is at the bottom of the ring • the relative energies of the MOs in the ring are given by where the vertices touch the circle • Those MOs • below the horizontal line through the center of the ring are bonding MOs • on the horizontal line are nonbonding MOs • above the horizontal line are antibonding MOs

  19. Energy Diagram for cyclobutadiene and benzene, illustrating the application of Frost’s circle.

  20. 1. Cyclobutadiene: a) Triplet Ground State b) Etotal = 4a+4b then DE = 0 2. Benzene: a) Singlet Ground State b) Etotal= 6a+8bthen DE = 2b

  21. Musulin-Frost diagrams:MO diagrams without the maths Graphical device for constructing MO energy diagrams:Frost & MusulinJ. Chem. Phys. 1953, 21, 572 (DOI) & Zimmerman J. Am. Chem. Soc. 1966, 88, 1564 (DOI) HMO energy levels for cyclic polyene n = 3 to n = 8.

  22. a - 0 . 6 1 8 b a - b a + 0 . 6 1 8 b a + 2 b a + 2 b E n e r g y d i a g r a m f o r C H a n d C H s y s t e m s . 3 3 5 5 1. C3H3+ Cation: Etotal = 2a+4b then DE = 2b 2. C3H3- Anion: Etotal= 4a+ 2bthen DE = -2b 3. C5H5- Anion: Etotal = 6a+6.472b then DE = 0.472b 4. C5H5+ Cation: Etotal = 4a+5.236b then DE = 1.236b

  23. Applications of HMO calculations delocalization energy (DE)total pi energy compared to that of a localized reference system charge densityfor a given carbon atom, coefficient squared gives electron density in each MO

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