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Title: ????????????? Ph.D. Program of Department of Chemistry ????????? 1st Semester of 2006 Academic Year


1
????????????? Ph.D. Program of Department of
Chemistry????????? 1st Semester of 2006 Academic
Year
????????(?)Special Topic on Advanced Physical
Chemistry Advanced Photochemistry
  • ????Lecture?????, Prof. Tai-Shan Fang,
  • e-mail
    chetsf_at_scc.ntnu.edu.tw
  • http//icho.chem.ntnu.edu.tw/fang/index.htm
  • ????Class LocationC304??
  • ???????,??200--500

2
(No Transcript)
3
(No Transcript)
4
95 1??2698(CMD0021 )?? ????????(?), ??
???(? 7-9 C304,), ? 7??? (Updated Oct. 12, 2006)
5
95 1??2698(CMD0021 )?? ????????(?), (?)??
???(? 7-9 C304,), ? 7??? (Updated Oct. 12, 2006)
6
????????? Lecture Contents and
References????????????,??????????????,???????????
?????????,??????????
  • (1) Modern Molecular Photochemistry of Organic
    Molecules
  • by Nicholas J. Turro, V. Ramamurthy,
    and Juan Scaiano,
  • Forthcoming in 2007! (University
    Science book)
  • Chapt. 13 and 14.(Contrained Medium
    Effect and Oxygen in
  • Photochemistry) , review basic organic
    photochemistry
  • (2) Chemical Kinetics and Reaction Dynamics by
    Paul L.
  • Houston, McGraw-Hill Higher Education ,
    Chapter 7.
  • Photochemistry (exercise)
  • (3) Modern Physical Organic Chemistry by Eric V.
    Anslyn and
  • Dennis A. Dougherty, 2005 (University
    Science book),
  • Chapter 17. Electronic Organic
    Materials, Solutions
  • (exercise)
  • (4) Recent Literatures and Journals

7
??????????
  • 1."???????????????????????????????2006???????????(
    ???   http//www.sinica.edu.tw/chem/TBIC/TBIC.htm)
    ,?????????????,???????????????????????????????????
    ??????????Green Bay Howard Hotel (???????)
    Speakers Program posterRegistration
    Transportation Origin  
  • 2. ??????????????-The 1st International
    Conference of Cutting-Edge Organic Chemistry in
    Asia (ICCEOCA-1)??10?16?10?20????????ICCEOCA-1????
    ?10?21??10?24????????????? Abstract Submission
    (Abstract Deadline September 15, 2006)
    Registration1"??????????????????
  • 3.??????95 ?11/25-26 ???????
  • 4.12?10 15? ???????????????????????
  • 5.Dec.14-16?????22??????????

8
95????????(?)by ???Advanced Photochemistry
??(??)(?)???, 1400-1700 C304
  • Syllabus
  • Modern Molecular Photochemistry of Organic
    Molecules
  • Nicholas J. TurroColumbia UniversityV.
    RamamurthyTulane UniversityJuan
    ScaianoUniversity of Ottawa
  • The course will involve a discussion of modern
    molecular organic photochemistry with emphasis on
    mechanisms. Useful texts and references

9
Forthcoming in 2007!Old Ed. 1992, OK!!
  • With two new co-authors, V. Ramamurthy and J.C.
    Scaiano, Nick Turro has completely revised and
    updated the 1992-edition of his benchmark text,
    Modern Molecular Photochemistry.  The text will
    present, at a level understandable by seniors and
    first year graduate students, the first totally
    integrated theory of organic photochemistry,
    including the first visualization of the role of
    electron spin at all levels.  In addition,
    chapters describing how experiment and theory can
    be applied to an understanding of the fundamental
    chromophors of organic chemistry will be
    presented.
  • If you would like to receive an e-mail
    announcement when this book is published, click
    here to send a . Please be sure to mention the
    title of the forthcoming book or books you would
    like to receive publication notification of.

10
Contents
  • 1. Introduction and Overview2. Electronic,
    nuclear and spin state of electronically excited
  • states3. Transitions between states4.
    Radiative transitions between states5.
    Radiationless transitions between states6.
    Theoretical organic photochemistry7. Energy and
    electron transfer processes8. Mechanistic
    organic photochemistry9. Photochemistry of
    carbonyl compounds10. Photochemistry of
    olefins11. Photochemistry of enones12.
    Photochemistry of aromatics13. Medium effects on
    photochemical processes organized
  • and constraining media14. Oxygen in
    photochemistryIndex

11
Chapter 7 Photochemistry
  • Paul L. Houston, Chemical Kinetics and
    Reaction Dynamics 1st Ed. (2001) , McGraw-Hill
    Higher Education
  • This textbook, designed for upper level
    undergraduates and beginning graduate students,
    was published by WCB/McGraw-Hill but is no longer
    available in printed form. A few copies are left
    at the publisher, which will run off a separate
    printing if there is demand, and a few copies are
    left at Amazon. A separate book containing the
    problems and solutions to this text is also
    available. As soon as the rights to the text are
    transferred back to the author from McGraw-Hill,
    the text will be made available by another
    publisher. I am pleased that Dover has agreed to
    publish it. With luck, we may have copies
    available for the Fall semester of 2006 at a
    price students may be better able to afford
  • To obtain a copy of this book for review please
    visit theAmazon.com
  • For a (favorable) review, see Krenos, John R. J.
    Chem. Educ. 2001 78 1466
  • Errata

12
Customer Reviews Average Customer Review by
Yummy, December 16, 2005
  • Chemical kinetics and reaction dynamics are not
    easy subjects, demanding quite a lot of physics
    in some complicated settings. Thus, it is all the
    more impressive that Paul Houston has managed to
    write this extraordinarily clear and concise text
    that is accessible to an advanced undergraduate.
    Do not get me wrong the prerequisites for this
    book are extensive. A good grasp of basic
    newtonian mechanics, quantum mechanics,
    spectroscopy, and statistical thermodynamics are
    musts. But nothing is needed beyond what can be
    expected from a good, stiff one-year course in
    physical chemistry. From the first chapter on
    the kinetic theory of gases, Houston's focus on
    the physics - on keeping derivations short and
    clear, on connecting formulae with sound physical
    intuition - is striking. It does not lag as the
    book goes on. Houston continues with a clean
    exposition of empirical chemical kinetics and how
    to integrate and/or simplify the resulting
    differential equations. The grungy business of
    theoretical kinetics - how to kludge your way to
    a theoretical gas-phase reaction rate constant -
    is well treated after that. In the third chapter,
    Houston delivers an elegant and unified
    flux-driven treatment of transport phenomena. He
    gets the basic equations correct up to a
    numerical factor with a minimum of effort. This
    is beautiful I wish chemical engineers would
    read this before beginning their own transport
    travails! There are then several chapters on the
    chemistry of more complicated systems, like
    solution-phase, solid surface-phase, and
    photochemical reactions. While I haven't read
    these, I am sure they are wonderful. The high
    point, in my opinion, is the final chapter on
    reaction dynamics. Its ongoing tacit motivation
    is the question, "How does a hydrogen fluoride
    laser work?" Read, and you will learn. In doing
    so, you will also become acquainted with the
    basic concepts in gas-phase reaction dynamics
    the details of the crossed-beam molecular
    scattering experiment, the concept of a potential
    energy surface, and what these can tell us about
    reaction mechanisms. Throughout Houston, the
    emphasis on looking up from the math and seeing
    the physical big picture prevents the blind and
    frustrating equation-crunching which is all too
    common in the quantitative sciences. This
    little book is really amazing. It takes you from
    a good undergraduate background to the forefront
    of modern chemical physics research with minimal
    pain and maximal excitement. Read it.

13
Modern Physical Organic Chemistry
  • Eric V. AnslynThe University of Texas, Austin
  • Dennis A. DoughertyCalifornia Institute of
    Technology

Chapter 17 Electronic Organic Materials,
Solutions
14
  • Dennis A. Dougherty, below, received a PhD from
    Princeton with Kurt Mislow, followed by a year of
    postdoctoral study with Jerome Berson at Yale. In
    1979 he joined the faculty at the California
    Institute of Te chnology, where he is now George
    Grant Hoag Professor of  Chemistry. Dougherty's
    extensive research interests have taken him to
    many fronts, but he is perhaps best known for
    development of the cation-p interaction, a novel
    but potent noncovalent binding interaction. More
    recently, he has addressed molecular
    neurobiology, developing the in vivo nonsense
    suppression method for unnatural amino acid
    incorporation into proteins expressed in living
    cells. This powerful new tool enables physical
    organic chemistry on the brain - chemical-scale
    studies of the molecules of memory, thought, and
    sensory perception and the targets of treatments
    for Alzheimer's disease, Parkinson's disease,
    schizophrenia, learning and attention deficits,
    and drug addiction.  His group is now working on
    extensive experimental and computational studies
    of the bacterial mechanosensitive channels MscL
    and MscS, building off the crystal structures of
    these channels recently reported by the Rees
    group at Caltech.

Eric V. Anslyn, right, received his PhD in
Chemistry from the California Institute of
Technology under the direction of Robert Grubbs.
After completing post-doctoral work with Ronald
Breslow at Columbia University, he joined the
faculty at the University of Texas at Austin,
where he became a Full Professor in 1999.  He
currently holds four patents and is the recipient
of numerous awards and honors, including the
Presidential Young Investigator, the Alfred P.
Sloan Research Fellow, the Searle Scholar, the
Dreyfus Teacher-Scholar Award, and the Jean
Holloway Award for Excellence in Teaching.  He is
also the Associate Editor for the Journal of the
American Chemical Society and serves on the
editorial boards of Supramolecular Chemistry and
the Journal of Supramolecular Chemistry.  His
primary research is in physical organic chemistry
and bioorganic chemistry, with specific interests
in catalysts for phosphoryl and glycosyl
transfers, receptors for carbohydrates and
enolates, single and multi-analyte sensors the
development of an electronic tongue, and
synthesis of polymeric molecules that exhibit
unique abiotic secondary structure. 
15
CONTENTS
  • Chapter 1 Introduction to Structure and Models
    of Bonding, Solutions
  • Chapter 2 Strain and Stability, Solutions
  • Chapter 3 The Thermodynamics of Solutions and
    Noncovalent Binding Forces, Solutions
  • Chapter 4 Molecular Recognition and
    Supramolecular Chemistry, Solutions
  • Chapter 5 Acid-Base Chemistry, Solutions
  • Chapter 6 Stereochemistry, Solutions
  • Chapter 7 Energy Surfaces and Kinetic Analyses,
    Solutions
  • Chapter 8 Experiments Related to Thermodynamics
    and Kinetics, Solutions
  • Chapter 9 Catalysis, Solutions
  • Chapter 10 Organic Reaction Mechanisms Part 1
    Reactions Involving Additions and/or
    Eliminations, Solutions
  • Chapter 11 Organic Reaction Mechanisms Part II
    Substitutions at Aliphatic Centers and Thermal
    Isomerizations/Rearrangements, Solutions
  • Chapter 12 Organotransition Metal Reaction
    Mechanisms and Catalysis, Solutions
  • Chapter 13. Organic Materials Chemistry,
    Solutions
  • Chapter 14. Advanced Concepts in Electronic
    Structure Theory, Solutions  Chapter 15
    Thermal Pericyclic Reactions, Solutions
  • Chapter 16 Photochemistry, Solutions
  • Chapter 17 Electronic Organic Materials,
    Solutions
  • Appendix

16
"A REMARKABLE ACHIEVEMENT"
  • "Spectacular! Congratulations! I plan to
    recommend it to all of my research group members
    and to those students in my class who are getting
    hooked on organic chemistry.  This is going to be
    a winner."--Peter Vollhardt, University of
    California at Berkeley"Anslyn and Dougherty
    have done an admirable and scholarly job to put
    the essence of this important subject between the
    covers of a single text.  I can enthusiastically
    recommend the text for anyone who is teaching a
    course dealing with the essentials of physical
    organic chemistry and more."--Nicholas J. Turro,
    Columbia University
  • The text will certainly inspire those coming to
    physical organic chemistry as a first love, as
    well as those coming from a bordering discipline
    who wish to acquire the insight that physical
    organic chemistry can provide.--Barry
    Carpenter, Cornell University
  • This much needed text places physical organic
    chemistry in its most modern context as the
    foundation of not only organic chemistry, but as
    the basis for understanding the most current
    research in supramolecular chemistry, organic
    materials science, catalysis, and
    organometallics.  This book is the new
    authoritative physical organic resource that will
    benefit researchers, students, and teachers
    alike.--Timothy M. Swager, Massachusetts
    Institute of Technology
  • "By building the text from the ground up, the
    authors have managed to incorporate modern
    applications of the theories of physical organic
    chemistry throughout, in a way that no revision
    of an existing text can hope to
    accomplish."Thomas Poon, Claremont Colleges
  • "This is a high quality book that fills a real
    need in our field, and that makes every other
    book in this area immediately obsolete.
    Congratulations to the authors on a remarkable
    achievement!"David I. Schuster, New York
    University This is the first modern textbook,
    written in the 21st century, to make explicit the
    many connections between physical organic
    chemistry and critical fields such as
    organometallic chemistry, materials chemistry,
    bioorganic chemistry, and biochemistry. In the
    latter part of the 20th century, the field of
    physical organic chemistry went through dramatic
    changes, with an increased emphasis on
    noncovalent interactions and their roles in
    molecular recognition, supramolecular chemistry,
    and biology the development of new materials
    with novel structural features and the use of
    computational methods. Contemporary chemists
    must be just as familiar with these newer fields
    as with the more established classical topics.
  • This completely new landmark text is intended to
    bridge that gap. In addition to covering
    thoroughly the core areas of physical organic
    chemistry structure and mechanism the book
    will escort the practitioner of organic chemistry
    into a field that has been thoroughly updated . 
    The foundations and applicabilities of modern
    computational methods are also developed.
  • Written by two distinguished researchers in this
    field, Modern Physical Organic Chemistry can
    serve as a text for a year-long course targeted
    to advanced undergraduates or first-year graduate
    students, as well as for a variety of shorter
    courses on selected aspects of the field. It
    will also serve as a landmark new reference text,
    and as an introduction to many of the more
    advanced topics of interest to modern
    researchers.  An accompanying Student Solutions
    Manual will become available.

17
Student Solutions Manualto accompany Modern
Physical Organic Chemistry
  • The Author sMichael B. Sponsler earned his PhD
    from the California Institute of Technology in
    1987, working as an NSF Graduate Fellow with
    Dennis A. Dougherty. He did research as an NIH
    Post-doctoral Fellow with Robert G. Bergman at
    the University of California, Berkeley and then
    accepted a faculty position at Syracuse
    University in 1989, where he is now Associate
    Professor. His research involves physical
    organic studies in the diverse areas of
    conjugated organometallic complexes and liquid
    crystalline holographic recording materials. The
    organometallic studies include synthesis and
    characterization of both mixed-valence complexes
    with polyenediyl bridges and related polymers.
    Applications in molecular electronics and
    nanotechnology are under investigation. The
    holographic studies are focused on new strategies
    for producing electrically switchable holograms.
  • Bios for Eric V. Anslyn and Dennis A. Dougherty
    can be found by linking to the page for their
    textbook,  Modern Physical Organic Chemistry

18
Photochemistry Invited Lecturers Yuan-Pern
Lee (chairperson), National Chiao-Tung
University Chi-Kung Ni, Institute of Atomic and
Molecular Sciences, Academia Sinica , Arthur G.
Suits, Wayne State University Mitchio Okumura
(chairperson), California Institute of
Technology, Robert E. Continetti, University of
California, San Diego Cheuk-Yiu Ng, University
of California, Davis
19
??????? Exams and Evaluation
  • (1)Advanced Photochem Exam  50 (closed book 2
    hours exam, Nov.15)
  • (2)Term Paper  25(Reviews on the subject in your
    research field)
  • (3)Seminar Presentation 25 (your research and
    proposal for future)
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