QUANTIFICATION OF VIRTUAL CHEMICAL PROPERTIES: STRAIN, HYPERCONJUGATION, CONJUGATION, AND AROMATICITY by JUDY I-CHIA WU (Under the Direction of Paul von Ragué Schleyer) ABSTRACT Highly important chemical concepts, like strain, hyperconjugation, conjugation, and aromaticity, are widely used to interpret the behavior of organic molecules, but are virtual (i.e., not directly measurable). This dissertation focuses on validating reliable quantum mechanical approaches for quantitative estimates of these virtual chemical properties and applying them to solve significant chemical problems. We are concerned with the simplest iconic organic molecules: cyclopropane, benzene, cyclobutadiene, cyclooctatetraene, and the polybenzenoid hydrocarbons. Cyclopropane’s unexpectedly low ring strain (almost the same as that of cyclobutane) is due to substantial CCC geminal delocalization. Cyclooctatetraene (COT) is not representative of an unconjugated cyclic polyene. Instead, double hyperconjugation stabilizes the tub-shaped COT (D ), as well as other non-planar conjugated systems, and compensates for their diminished π 2d conjugation. On the other hand, planar D COT is net stabilized by π conjugation and only 4h weakly anti-aromatic destabilized. Planar [4]annulenes in general are not very destabilized antiaromatically. Even cyclobutadiene is only modestly destabilized by antiaromaticity; its high heat of formation is mainly due to significant angle strain and Pauli repulsion between the pairs of C=C π bonds. Large 4n π electron polycyclic benzenoids and the higher dihydrodiazaacenes benefit from substantial π conjugation and can even display aromatic stabilization energies (ASE), of equal or greater magnitude, than their 4n+2 π electron analogs. Aromaticity is very robust towards electronic and geometric perturbtations. Hence, perfluorobenzene (C F ) is as 6 6 aromatic as benzene, while perfluorocyclobutadiene (C F ) has only reduced antiaromaticity 4 4 compared to cyclobutadiene, due to the twisting of its π system. This work further shows the effectiveness of the nucleus independent chemical shifts (NICS) as a “local” probe of aromaticity for substituted and fused-ring aromatic systems. Our computational findings provide valuable insight to the development of fundamental organic concepts. INDEX WORDS: computational chemistry, hyperconjugation, electron delocalization, resonance energy, aromatic stabilization energy (ASE), substituent effects, nucleus independent chemical shifts (NICS), block-localized wave function (BLW) QUANTIFICATION OF VIRTUAL CHEMICAL PROPERTIES: STRAIN, CONJUGATION, HYPERCONJUGATION, AND AROMATICITY by JUDY I-CHIA WU B.S., Tung-Hai University, Taichung, Taiwan, 2004 A Dissertation Submitted to the Graduate Faculty of The University of Georgia in Partial Fulfillment of the Requirements for the Degree DOCTOR OF PHILISOPHY ATHENS, GEORGIA 2011 © 2011 Judy I-Chia Wu All Rights Reserved QUANTIFICATION OF VIRTUAL CHEMICAL PROPERTIES: STRAIN, CONJUGATION, HYPERCONJUGATION, AND AROMATICITY by JUDY I-CHIA WU Major Professor: Paul von Ragué Schleyer Committee: Henry F. Schaefer III Robert J. Woods Electronic Version Approved: Maureen Grasso Dean of the Graduate School The University of Georgia May 2011 DEDICATION To Keigo, Paul, my Parents, and in memory of Gnocchi “It has often been said there’s so much to be read, you never can cram all those words in your head. So the writer who breeds more words than he needs is making a chore for the reader who reads. That's why my belief is the briefer the brief is, the greater the sigh of the reader's relief is. And that's why your books have such power and strength. You publish with shorth! (Shorth is better than length.)” -Theodor Seuss Giesel a.k.a. “Dr. Seuss” iv “All Hyperconjugation, All the Time.” v ACKNOWLEDGEMENTS My deepest appreciation goes to many people who have helped me greatly in personal and scientific growth during the past six years. Most of all, I am in debt to Prof. Schleyer for the fine education he has given me. I thank him especially for changing my mind about chemistry. His nurturing of a good appetite for chemical discoveries as well as for elegant scientific writing has made a world of difference for me. I thank my parents for the love, time, “goodie boxes,” and resources they have devoted to supporting my ups and downs all the time. Special thanks go to my Dad, whose guidance and 3M tips has been an essential part to my accomplishment. I also thank Keigo and Chad for wonderful friendship and many cheerful scientific and philosophical conversations. I’ve enjoyed so much learning and exploring chemistry (and Germany) together with them. I thank Keigo especially for being a great companion through many difficult times, for sharing my excitement for every new discovery, and for being a great mentor in helping me improve many presentations. I am grateful to Prof. Schaefer for his cheerful encouragements and for the valuable opportunities of meeting and observing many distinguished scientists at the CCQC. Clémence has been a wonderful role model. I would like to thank her for the time she has spent guiding me in many ways when I first joined the Schleyer group. I also thank Prof. Mo for many friendly and insightful discussions. Finally, I want to acknowledge Nattoh, Gnocchi, and Dexter for being my Athens family. They do a (almost) perfect job of distracting me from work when stubborn problems and a stubborn mind prevent me from going to bed on time. vi TABLE OF CONTENTS Page ACKNOWLEDGEMENTS...........................................................................................................vi LIST OF TABLES.........................................................................................................................xi LIST OF FIGURES.....................................................................................................................xiii CHAPTER 1 INTRODUCTION.........................................................................................................1 2 WHY CYCLOOCTATETRAENE IS HIGHLY STABILIZED: THE IMPORTANCE OF “TWO-FOLD” (DOUBLE) HYPERCONJUGATION...........................................5 2.1 ABSTRACT.......................................................................................................6 2.2 INTRODUCTION.............................................................................................7 2.3 METHODS......................................................................................................17 2.4 ELECTRON DELOCALIZATION IN D AND D 2D 4H CYCLOOCTATETRAENE..................................................................................20 2.5 THE INVERSION BARRIER OF CYCLOOCTATETRAENE.....................22 2.6 ANTIAROMATICITY IN D CYCLOOCTATETRAENE.........................24 4H 2.7 1,3-BUTADIENE ROTATION.......................................................................26 2.8 OTHER MOLECULES WITH “TWO-FOLD” (DOUBLE) HYPERCONJUGATION......................................................................................32 2.9 CONCLUSIONS..............................................................................................36 2.10 REFERENCES..............................................................................................39 vii 3 IS CYCLOBUTADIENE REALLY DESTABILIZED BY ANTIAROMAITICITY? AN ALTERNATIVE EXPLANATION BASED ON SIMPLE STRAIN CONSIDERATIONS...................................................................................................47 3.1 ABSTRACT.....................................................................................................48 3.2 INTRODUCTION...........................................................................................48 3.3 EVIDENCE FOR HIGH RING STRAIN IN THE SIGMA-FRAMEWORK OF CBD.................................................................................................................52 3.4 BLOCK-LOCALIZED WAVEFUNCTION ANALYSES.............................55 3.5 DISCUSSIONS................................................................................................56 3.6 CONCLUSIONS..............................................................................................58 3.7 REFERENCES................................................................................................59 4 WHY IS THE STRAIN ENERGY OF CYCLOPROPANE SO LOW?.....................61 4.1 ABSTRACT.....................................................................................................62 4.2 INTRODUCTION...........................................................................................62 4.3 METHODS......................................................................................................70 4.4 THE MISSING STRAIN IN CYCLOPROPANE...........................................71 4.5 GEMINAL DELOCALIZATION AND SUBSTITUENT EFFECTS............75 4.6 NUCLEUS INDEPENDENT CHEMICAL SHIFTS......................................79 4.7 CONCLUSIONS..............................................................................................82 4.8 REFERENCES................................................................................................83 5 THE EFFECT OF PERFLUORINATION ON THE AROMATICITY OF BENZENE AND HETEROCYCLIC SIX MEMBERED RINGS.................................................86 5.1 ABSTRACT.....................................................................................................87 viii