Presentation is loading. Please wait.

Presentation is loading. Please wait.

A Comparison of Recoupled Pair Bonding in Carbon and Sulfur: States of CX and CX 2 (X=H,F) Lu Xu Lu Xu, D. E. Woon, T. H. Dunning, Jr. TI13.

Published byBathsheba Melton Modified over 8 years ago

Similar presentations

Presentation on theme: "A Comparison of Recoupled Pair Bonding in Carbon and Sulfur: States of CX and CX 2 (X=H,F) Lu Xu Lu Xu, D. E. Woon, T. H. Dunning, Jr. TI13."— Presentation transcript:

1 A Comparison of Recoupled Pair Bonding in Carbon and Sulfur: States of CX and CX 2 (X=H,F) Lu Xu Lu Xu, D. E. Woon, T. H. Dunning, Jr. TI13

2 Outline X=H,F  Recoupled Pair Bonding in Sulfur  Recoupled Pair Bonding in Carbon: compare and contrast with Sulfur  Substituent effects: H and F C, S CX, SFCX 2, SF 2

3  RCCSD(T) and CASSCF/MRCI(+Q)  Basis sets: aug-cc-pV(T,Q,5)Z  GVB diagrams/orbitals  Molpro Methodology

4 Overview of Recoupled Pair Bonding (RPB) in SF n S normal covalent bond F + F + S Recoupled Pair Bond S F 2Π2Π S F 4Σ-4Σ-  SF, SF 2 excited states, SF 3 -SF 6 ground states  RPB explains the hypervalency of S Woon, D. E.; Dunning, T. H., Jr. J. Phys. Chem. A 2009, 133, 7915 Carbon? RPB: 3 e - process

5 C vs. S RHF S 3s 2 3p x 1 3p y 1 3p z 2 C 2s 2 2p x 1 2p y 1 (2s 2 - c 2 2 2p z 2 )2p x 1 2p y 1 0.737 0.862 Overlap 3s 2 3p x 1 3p y 1 (3p z 2 - c 1 2 3d z2 2 ) GVB (MCSCF) + C X X (X=H,F) 4Σ-4Σ- Recoupled Pair Bond ? CX

6 4Σ-4Σ- 2Π2Π Potential energy curves of the low lying 2 Π and 4 Σ - states of SH, SF, CH and CF at MRCI+Q/AV5Z level (energies in E h, bond lengths in Å) Similarity:  All have 2 Π ground states; Three have bound 4 Σ - excited states CX and SX (X=H,F): Potential Energy Curves Differences:  SH has repulsive 4 Σ - state  ∆E( 4 Σ - - 2 Π )  ∆r e ( 4 Σ - - 2 Π )

7 CX and SX (X=H,F): Potential Energy Curves Two questions: 1. Are the 4 Σ - states in CH and CF Recoupled Pair Bonding states? 2. What causes the differences between the curves? What are the differences between C and S Recoupled Pair Bonding?

8 CX and SX (X=H,F): Potential Energy Curves Two questions: 1. Are the 4 Σ - states in CH and CF Recoupled Pair Bonding states? 2. What causes the differences between the curves? What are the differences between C and S Recoupled Pair Bonding?

9 SF, CH and CF 4 Σ - GVB Orbital Animations SF σσLσL σRσR RPB: 3 e - process SFSFSF CH CH C HC H CF CF CF CF

10 SFSF SF SF and CF 4 Σ - GVB Orbital Snapshots S-FC-F The orbitals distinctly exhibit recoupling in both cases! C F Woon, D. E.; Dunning, T. H., Jr. J. Phys. Chem. A 2009, 133, 7915 σ σLσL σRσR σσLσL σRσR C F

11 CX and SX (X=H,F): Potential Energy Curves Two questions: 1.Are the 4 Σ - states in CH and CF Recoupled Pair Bonding states? C has similar Recoupled Pair Bonding as S, CH and CF 4 Σ - states are recoupled states

12 CX and SX (X=H,F): Potential Energy Curves Two questions: 1.Are the 4 Σ - states in CH and CF Recoupled Pair Bonding states? C has similar Recoupled Pair Bonding as S, CH and CF 4 Σ - states are recoupled states

13 CX and SX (X=H,F): Potential Energy Curves Two questions: 1.Are the 4 Σ - states in CH and CF Recoupled Pair Bonding states? C has similar Recoupled Pair Bonding as S, CH and CF 4 Σ - states are recoupled states 2. What causes the differences between the curves? What are the differences between C and S Recoupled Pair Bonding?

14 4Σ-4Σ- 2Π2Π CX and SX (X=H,F): Potential Energy Curves Difference (1) SH has repulsive 4 Σ - state CH and SF have stable 2 Π and 4 Σ - states repulsive Potential energy curves of the low lying 2 Π and 4 Σ - states of SH, SF, CH and CF at MRCI+Q/AV5Z level (energies in E h, bond lengths in Å)

15 C vs. S: GVB Overlap  Smaller GVB overlap means weaker coupling Therefore, it is easier to recouple the 2s 2 pair of C than the 3p 2 pair of S  Greater electronegativity means better ability to recouple Therefore, F is better at recoupling than H C GVB overlap: 0.737 GVB overlap: 0.862 S

16 4Σ-4Σ- 2Π2Π CX and SX (X=H,F): Potential Energy Curves Difference (2) Different ∆r e ( 4 Σ - - 2 Π ) CH & CF: r e ( 2 Π ) and r e ( 4 Σ - ) are nearly the same SF: r e ( 4 Σ - ) is much longer than r e ( 2 Π ) Potential energy curves of the low lying 2 Π and 4 Σ - states of SH, SF, CH and CF at MRCI+Q/AV5Z level (energies in E h, bond lengths in Å)

17 C vs. S: Non-Bonding vs. Anti-Bonding 4 Σ - Left-over singly occupied orbital S: strong anti-bonding character, weakens the bond C: non-bonding orbital, localized outside of bond region r e ( 2 Π ):1.274 Å FC r e ( 4 Σ - ):1.325 Å occ 1.98occ 1.00 C F C F r e ( 4 Σ - ):1.901 Å r e ( 2 Π ):1.605 Å S F occ 2.00 occ 1.00 SFSF Two types of Recoupled Pair Bonding: C-type and S-type MRCI/AV5Z

18 4Σ-4Σ- 2Π2Π CX and SX (X=H,F): Potential Energy Curves Difference (3) ∆E( 4 Σ - - 2 Π ) CH < CF Potential energy curves of the low lying 2 Π and 4 Σ - states of SH, SF, CH and CF at MRCI+Q/AV5Z level (energies in E h, bond lengths in Å)

19 C vs. S & H vs. F ∆E( 4 Σ - - 2 Π ):CH < CF C-F: unfavorable  interaction in 4 Σ - C-H: no  interaction 2Π2Π occ: 3.98 occ: 1.06 4Σ-4Σ- occ: 4.00 occ: 2.00 Puzzle: H has less decoupling ability than F CF<CH

20 Summary of Recoupled Pair Bonding in CX (X=H,F)  CX has similar RPB 4 Σ - states as in SF  CX and SX have two different types of RPB: one has singly occupied non-bonding orbital, the other has singly occupied anti-bonding orbtial  Different  interactions influence the energy separations of recoupled states and ground states of CX What about CX 2 ? Still similar as SF 2 ?

21 CX 2 (X=H,F): Predictions of Low-Lying States 4Σ-4Σ- 1A11A1 CX 2 CX 2Π2Π X (X=H,F) 3B13B1 3A23A2 C

22 CX 2 (X=H,F): 3 B 1 and 1 A 1 3B13B1 1A11A1 X (X=H,F) r e =1.078 Å A= 133.6 o BE=122.5 Kcal/mol r e =1.109 Å A= 102.0 o BE=96.4 Kcal/mol r e =1.300 Å A= 104.8 o BE= 125.2Kcal/mol r e =1.314 Å A= 119.0 o BE=149.5 Kcal/mol CH 2 CF 2 SF 2 r e = 1.592 Å A= 97.9 o BE= 91.0 Kcal/mol r e = 1.666 Å A= 162.7 o BE= 106.6 Kcal/mol RCCSD(T)/AVQZ BE:Bond Energy recoupled state Ground States covalent state

23 CX+X and SF+F ( 3 Σ - ): GVB Orbitals Animations SF( 4 Σ - )+F( 2 P): The singly occupied anti-bonding orbital delocalizes onto the incoming F; the anti-bonding character is largely reduced CH( 4 Σ - )+H( 2 S), CF( 4 Σ - )+F( 2 P): Due to the non-bonding nature of the singly occupied orbital on C, the orbitals don’t delocalize and change much SF F CH H C F F X=H,F

24 CH 2 1A11A1 recoupled state 3B13B1 3A23A2 CH 4Σ-4Σ- 2Π2Π recoupling/hypervalent colvalent w/left-over e- colvalent CH 2, CH 3 and CH 4 are hypervalent in RPB sense! ∆E=9.3 ∆E=64.5 RCCSD(T)/AVQZ; ∆E in Kcal/mol ∆E=16.8 CH 3, CH 4 C

25 Conclusion  Carbon has Recoupled Pair Bonding, similar as Sulfur  CX(X=H,F) and SF recoupled 4 Σ - are different in the nature of singly occupied orbital  CH 2, CH 3 and CH 4 ground states are recoupled states, so C is hypervalent in RPB sense

26 Acknowledgement  Dunning group: Prof. Thom Dunning, Dr. David Woon, Dr. Lina Chen, Jeff Leiding, Beth Lindquist, Tyler Takeshita  Funding: The Distinguished Chair for Research Excellence in Chemistry at the University of Illinois at Urbana- Champaign

Download ppt "A Comparison of Recoupled Pair Bonding in Carbon and Sulfur: States of CX and CX 2 (X=H,F) Lu Xu Lu Xu, D. E. Woon, T. H. Dunning, Jr. TI13."

Similar presentations

Chapter 9 Molecular Geometries and Bonding Theories

Chapter 9 Molecular Geometries and Bonding Theories
Chapter 6: covalent compounds

Chapter 6: covalent compounds
Theoretical Studies of Observable Transitions to Recoupled Pair Bonded States of Sulfur Halide Compounds Jeff Leiding, D. E. Woon, T. H. Dunning, Jr. University.

Theoretical Studies of Observable Transitions to Recoupled Pair Bonded States of Sulfur Halide Compounds Jeff Leiding, D. E. Woon, T. H. Dunning, Jr. University.
Bonding in ClF n (n=1-7): Further Insights into Hypervalent Molecules and Recoupled Pair Bonds Lina Chen, David E. Woon and Thom H. Dunning Department.

Bonding in ClF n (n=1-7): Further Insights into Hypervalent Molecules and Recoupled Pair Bonds Lina Chen, David E. Woon and Thom H. Dunning Department.
New Perspective on PF n (n=1-5) from the Recoupled Pair Bonding Model: A Quantum Chemical Study David E. Woon & Thom H. Dunning, Jr. TI12.

New Perspective on PF n (n=1-5) from the Recoupled Pair Bonding Model: A Quantum Chemical Study David E. Woon & Thom H. Dunning, Jr. TI12.
Chapter 9 Molecular Geometry and Bonding Theories CHEMISTRY The Central Science 9th Edition David P. White.

Chapter 9 Molecular Geometry and Bonding Theories CHEMISTRY The Central Science 9th Edition David P. White.
1 Covalent Bonding: Molecular Geometry Hybridization of Atomic Orbitals Molecular Orbitals.

1 Covalent Bonding: Molecular Geometry Hybridization of Atomic Orbitals Molecular Orbitals.
Theoretical Predictions of the Structures and Energetics of ClF n +/- (n =1-6) Ions: Extended Studies of Hypervalent Species Using the Recoupled Pair Bonding.

Theoretical Predictions of the Structures and Energetics of ClF n +/- (n =1-6) Ions: Extended Studies of Hypervalent Species Using the Recoupled Pair Bonding.
Chem 125 Lecture 13 10/3/08 This material is for the exclusive use of Chem 125 students at Yale and may not be copied or distributed further. It is not.

Chem 125 Lecture 13 10/3/08 This material is for the exclusive use of Chem 125 students at Yale and may not be copied or distributed further. It is not.
Homework DUE Friday, 5 Sept Problems in McMurry 1.24; 1.28; 1.31; 1.45; 1.46; 1.47 => (1.48—1.52 BONUS Problems) Organic Chemistry - 246A.

Homework DUE Friday, 5 Sept Problems in McMurry 1.24; 1.28; 1.31; 1.45; 1.46; 1.47 => (1.48—1.52 BONUS Problems) Organic Chemistry - 246A.
Molecular Orbital Theory Edward A. Mottel Department of Chemistry Rose-Hulman Institute of Technology.

Molecular Orbital Theory Edward A. Mottel Department of Chemistry Rose-Hulman Institute of Technology.
Molecular Orbital Theory

Molecular Orbital Theory
Valence Bond Theory and Molecular Orbital Theory

Valence Bond Theory and Molecular Orbital Theory
John E. McMurry www.cengage.com/chemistry/mcmurry Paul D. Adams University of Arkansas Atomic and Molecular Orbitals.

John E. McMurry Paul D. Adams University of Arkansas Atomic and Molecular Orbitals.
VSEPR Theory 1 1 1 1.

VSEPR Theory
Covalent Bonding: Orbitals.  Some atoms will form hybridized orbitals when bonding with other atoms. There are three that are included on the AP exam.

Covalent Bonding: Orbitals.  Some atoms will form hybridized orbitals when bonding with other atoms. There are three that are included on the AP exam.
Base Pairing in DNA. Red = O Grey = C White = H Purple = K Ionic Radii Li + = 0.68 Å Na + = 0.97 Å K + = 1.33 Å Rb + = 1.47 Å Cavity Size (O-O Dist.)

Base Pairing in DNA. Red = O Grey = C White = H Purple = K Ionic Radii Li + = 0.68 Å Na + = 0.97 Å K + = 1.33 Å Rb + = 1.47 Å Cavity Size (O-O Dist.)
Lewis Structures –Bond Pairs and Lone Pairs In Lewis structures with five or six pairs of electrons around the central atom we need to distinguish between.

Lewis Structures –Bond Pairs and Lone Pairs In Lewis structures with five or six pairs of electrons around the central atom we need to distinguish between.
AP Chapter 9 Molecular Geometry and Bonding Theories HW: 3 4 7 15 21 25 35 41 55 76 79 87.

AP Chapter 9 Molecular Geometry and Bonding Theories HW:
Chemistry 100 Chapter 9 Molecular Geometry and Bonding Theories.

Chemistry 100 Chapter 9 Molecular Geometry and Bonding Theories.

Similar presentations

Ads by Google