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Homo-halogen Bonding in 2-iodo-perfluoroalkane Darin J. Ulness Department of Chemistry Concordia College, Moorhead, MN.

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Presentation on theme: "Homo-halogen Bonding in 2-iodo-perfluoroalkane Darin J. Ulness Department of Chemistry Concordia College, Moorhead, MN."— Presentation transcript:

1 Homo-halogen Bonding in 2-iodo-perfluoroalkane Darin J. Ulness Department of Chemistry Concordia College, Moorhead, MN

2 Outline Hydrogen bonding History The  hole and  hole bonding Data Discussion

3 Hydrogen Bonding Hydrogen on a N, O, F Interact with a N, O, F Bond distance shorter than sum of Van der Waals Radii Angle approximately 180 o

4 Halogen Bonding I > Br > Cl, no F Interact with a N, O Bond distance shorter than sum of Van der Waals Radii Angle approximately 180 o

5 Halogen Bonding: History F. Guthrie, J. Chem. Soc. 16, 239 (1863) Complexation of I 2 and NH 3 I. Remsen, J.F. Norris, Am. Chem. J. 18, 90, (1896) Complexation of X 2 and methyl amines O. Hassel, Proc. Chem. Soc. 7, 250 (1957) [Nobel Prize 1969] Donor/acceptor complexes: Halogens and Lone Pair T. Di Paolo, C. Sandorfy, Can. J. Chem. 52, 3612 (1974) Spectroscopic studies aromatic amines and halo-alkanes

6 Halogen Bonding: Today Halogen Bonding Biochemistry Biomolecular engineering Drug Design Materials Science Crystal engineering Molecular recognition Computational Chemistry  hole bonding Voth A. R. et.al. PNAS 2007;104:6188-6193 Resnati et.al. J. Fluorine Chem. 2004;104: 271

7 The  hole I Test Charge Free Iodine Atom Test Charge “feels” an electroneutral field Test charge far from an iodine atom

8 The  hole I Test charge close to an iodine atom Test Charge “feels” an electropositive field An arbitrary spherical surface carries an eletropositive potential !

9 The  hole Test Charge In molecules the electron density is directed into the bond

10 The  hole Electropositve  -hole Test Charge Electroneutral “ring” Electronegative “belt”

11 The  hole Electropositve  -hole Test Charge Electroneutral “ring” Electronegative “belt” Perfluorinate: Stronger  hole

12  hole bonding with pyridine

13 Pyridine as a probe of Halogen bonding The ring stretches of pyridine act as a probe of its environment C N C CC C C N C CC C “ring-breathing” mode “triangle” mode

14 Pyridine as a probe of Halogen bonding Hydrogen bonding to a water modulates the stretching frequency C N C CC C free pyridine C N C CC C O H H H-bonded pyridine

15 I (2) CARS Experiment Monochromator Narrowband Source Broadband Source (noisy light) Lens Sample Interferometer  B B’ M I (2) CARS Computer CCD

16 Pyridine as a probe

17 free pyridine H-bonded pyridine ring-breathing

18 Pyridine as a probe of Halogen bonding C4F9IC4F9I C 6 F 13 I C3F7IC3F7I 2-iodo-perfluoropropane 1-iodo-perfluoroalkanes

19 C4F9IC4F9IC 6 F 13 I

20 2-iodo-perfluoropropane C3F7IC3F7IC 6 F 13 I

21 Temperature Studies C3F7IC3F7IC 6 F 13 I

22 I’m Special ! 2-iodo-perfluoropropane 1-iodo-perfluoroalkanes

23 Conjecture Stronger and more  F directed homo-halogen bonding leads to more local solvent structure order. Increased positive entropy contribution Increased positive enthalpy contribution

24 One is better than two ?

25

26 Strategies To test the homo-halogen bonding hypothesis utilized several techniques Analysis of physical properties 19 F-NMR IR (data not discussed) Noticed photochemical dissociation when left in room lights Suggested a kinetics study

27 Kinetics Let cuvettes sit in room light and observed their color change via the following reaction: Measured absorbance every 10 minutes to check iodine production

28 Time 20minTime 30minTime 45min Time 60minTime 90minTime 18hrs X=0.2NeatX=0.2NeatX=0.2Neat X=0.2NeatX=0.2Neat X=0.2Neat

29 Kinetics Different rate constants observed k obs = 0.0755min -1 in hexane (after correction for mole fraction) k obs = 0.0019min -1 when neat Iodine production nearly 40x faster in hexane Protection of iodine Dissociation and geminate pair recombination

30 Boiling and melting points Compare boiling point difference of non- fluorinated to fluorinated: –12°C difference compared to 1°C difference Compare melting point difference of non- fluorinated to fluorinated: –11°C difference compared to 37°C difference CompoundBoiling Point (°C) Melting Point C 3 H 7 I (1-iodo) 102-101 C 3 H 7 I (2-iodo) 90-90 C 3 F 7 I (1-iodo) 41-95 C 3 F 7 I (2-iodo) 40-58

31 Boiling and melting points Compare boiling point difference of non- fluorinated to fluorinated: –12°C difference compared to 1°C difference Compare melting point difference of non- fluorinated to fluorinated: –11°C difference compared to 37°C difference CompoundBoiling Point (°C) Melting Point C 3 H 7 I (1-iodo) 102-101 C 3 H 7 I (2-iodo) 90-90 C 3 F 7 I (1-iodo) 41-95 C 3 F 7 I (2-iodo) 40-58

32 Boiling and melting points Compare boiling point difference of non- fluorinated to fluorinated: –12°C difference compared to 1°C difference Compare melting point difference of non- fluorinated to fluorinated: –11°C difference compared to 37°C difference CompoundBoiling Point (°C) Melting Point C 3 H 7 I (1-iodo) 102-101 C 3 H 7 I (2-iodo) 90-90 C 3 F 7 I (1-iodo) 41-95 C 3 F 7 I (2-iodo) 40-58

33 Boiling and melting points Compare boiling point difference of non- fluorinated to fluorinated: –12°C difference compared to 1°C difference Compare melting point difference of non- fluorinated to fluorinated: –11°C difference compared to 37°C difference CompoundBoiling Point (°C) Melting Point C 3 H 7 I (1-iodo) 102-101 C 3 H 7 I (2-iodo) 90-90 C 3 F 7 I (1-iodo) 41-95 C 3 F 7 I (2-iodo) 40-58

34 Boiling and melting points Compare boiling point difference of non- fluorinated to fluorinated: –12°C difference compared to 1°C difference Compare melting point difference of non- fluorinated to fluorinated: –11°C difference compared to 37°C difference CompoundBoiling Point (°C) Melting Point C 3 H 7 I (1-iodo) 102-101 C 3 H 7 I (2-iodo) 90-90 C 3 F 7 I (1-iodo) 41-95 C 3 F 7 I (2-iodo) 40-58

35 NMR 19 F-NMR α-peak and β-peak behavior Measures amount of electron shielding

36 NMR More shielding Less shielding

37 NMR More shielding Less shielding

38 NMR More shielding Less shielding Halogen bonding

39 More shielding Less shielding Halogen bonding

40 More shielding Less shielding Halogen bonding

41 Conclusion Homo-halogen bonding  Boiling and melting points  Kinetics  Iodine production rates  Geminate pair recombination  NMR  Shift in α-peak  Shielding levels based on temperature

42 Acknowledgements Dr. Haiyan Fan Dr. Mark Gealy Jeff Eliason Scott Flancher Diane Moliva Danny Green NSF CAREER: CHE-0341087 Dreyfus Foundation Concordia Chemistry Research Fund

43

44 Importance of the  Fluorine

45 Infrared Spectroscopy

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