George S. Hammond

George Hammond
Born (1921-05-22)22 May 1921
Auburn, Maine, U.S.
Died 5 October 2005(2005-10-05) (aged 84)
Portland, Oregon, U.S.
Residence United States
Fields Chemistry
Institutions
Alma mater
Doctoral advisor Paul Doughty Bartlett
Known for
Notable awards

George Simms Hammond (May 22, 1921 – October 5, 2005[1]) was an American scientist, author, academic administrator, and chemical theorist. He is widely credited as the father of organic photochemistry,[2][3][4] and developed the general theory of the geometric structure of the transition state in an organic chemical reaction; the theory is widely known as "Hammond's postulate".[1] Hammond's research is also known for its influence on the philosophy of science.[5] His research garnered him the Norris Award in 1968, the Priestley Medal in 1976, the National Medal of Science in 1994,[6] and the Othmer Gold Medal in 2003.[7][8] He served as the executive chairman of the Allied Chemical Corporation from 1979 to 1989.[2]

He was a chemist at the California Institute of Technology, and subsequently headed both the Departments of Chemistry and Chemical Engineering at the university. He conducted research at the University of Oxford and University of Basel as a Guggenheim Fellow and National Science Foundation Fellow, respectively. He served as the foreign secretary of the National Academy of Sciences from 1974 to 1978.

A native of Maine, he was born and raised in Auburn; he attended nearby Bates College in Lewiston, Maine, where he graduated magna cum laude with a B.S. in Chemistry in 1943. He completed his doctorate at Harvard University in 1947, under the mentorship of Paul Doughty Bartlett, and a postdoctorate at University of California, Los Angeles with Saul Winstein in 1948.[1]

Early life and education

George Simmons Hammond was born on May 22, 1921 in Auburn, Maine.[2] Growing up in Auburn his family were charged with the operation of the neighborhood dairy farm on Hardscrapple Road. His father died when Hammond was thirteen. He was the oldest of seven children and was raised by a single mother. From an early age Hammond was charged with running the day-to-day operations of the dairy farm with his mother and older siblings.[2] Homeschooled until sixth grade, he was educated at various Auburn public schools before graduating in 1938. After graduating he took a gap year to continue operating his dairy farm. After his educational hiatus he applied to and was accepted into Bates College, in Lewiston, Maine. He graduated with a Bachelors of Science in Chemistry Magna Cum Laude and Phi Beta Kappa in January 1943.[2]

Early career

Upon graduating from college, Hammond took a position as a Chemist at Rohm and Haas in Philadelphia, Pennsylvania. After months on the job he quit to pursue graduate studies at Harvard University. He received a Masters of Science (M.S.) and Doctor of Philosophy (Ph.D).[2] His thesis, Inhibition of the Polymerization of Allylacetate, was reviewed by Paul Doughty Bartlett. Hammond moved to Los Angeles, California to study intermolecular compounds at UCLA.[2]

Career in academia

His academic career began in 1948 with a teaching position at Iowa State College; he served as Assistant Professor of Chemistry. In his capacity there he published Hammon's postulate which has widely known as the most important publication in the field of organic photochemistry.[2][3][4] He moved to the University of Oxford and University of Basel as a Guggenheim Fellow and National Science Foundation Fellow, respectively.[2] In 1958, he moved to the California Institute of Technology as a Professor of Organic Chemistry. Later he was appointed the Arthur Amos Noyes Professor of Chemistry and subsequently went on to lead the Departments of Chemistry and Chemical Engineering. After 14 years teaching and serving as an academic administrator at Caltech he moved in 1972 to the University of Santa Clara. At Santa Clara he served as both a professor and the Chancellor of the natural sciences.[2]

Later pursuits

He was appointed as the Foreign Secretary of the National Academy of Sciences in 1974 and served for one term retiring in 1978. He also gave notable speeches on political issues such as the invasion of Cambodia,[2] and various topics on Chemistry. The talks he gave sometimes had negative impacts on his life, exemplified by Nixon's withdrawal of his name for major National Academy of Sciences positions. In 1979 he retired from academia and joined the Allied Chemical Corporation as Executive Chairman, serving for ten years. He retired from the capacity and all others after hist tenure concluded.[2]

Scientific career

Hammond's postulate

Main article: Hammond's postulate

George Hammond published a hypothesis in physical organic chemistry which describes the geometric structure of the transition state in an organic chemical reaction in his publication, Hammond's principle.

His 1955 publication asserted:

"If two states, as, for example, a transition state and an unstable intermediate, occur consecutively during a reaction process and have nearly the same energy content, their interconversion will involve only a small reorganization of the molecular structures."[9]

Therefore, the geometric structure of a state can be predicted by comparing its energy to the species neighboring it along the reaction coordinate. For example, in an exothermic reaction the transition state is closer in energy to the reactants than to the products. Therefore, the transition state will be more geometrically similar to the reactants than to the products. In contrast, however, in an endothermic reaction the transition state is closer in energy to the products than to the reactants. So, according to Hammond’s postulate the structure of the transition state would resemble the products more than the reactants.[10] This type of comparison is especially useful because most transition states cannot be characterized experimentally.[11]

Hammond's postulate also helps to explain and rationalize the Bell–Evans–Polanyi principle. Namely, this principle describes the experimental observation that the rate of a reaction, and therefore its activation energy, is affected by the enthalpy of that reaction. Hammond's postulate explains this observation by describing how varying the enthalpy of a reaction would also change the structure of the transition state. In turn, this change in geometric structure would alter the energy of the transition state, and therefore the activation energy and reaction rate as well.[12]

The postulate has also been used to predict the shape of reaction coordinate diagrams. For example, electrophilic aromatic substitutions involves a distinct intermediate and two less well defined states. By measuring the effects of aromatic substituents and applying Hammond's postulate it was concluded that the rate-determining step involves formation of a transition state that should resemble the intermediate complex.[13]

During the 1940s and 1950s, chemists had trouble explaining why even slight changes in the reactants caused significant differences in the rate and product distributions of a reaction. In 1955 George S. Hammond, a young professor at Iowa State University, postulated that transition-state theory could be used to qualitatively explain the observed structure-reactivity relationships.[3] Notably, John E. Leffler of Florida State University proposed a similar idea in 1953.[4] However, Hammond's version has received more attention since its qualitative nature was easier to understand and employ than Leffler's complex mathematical equations. Hammond's postulate is sometimes called the Hammond-Leffler postulate to give credit to both scientists.[3]

Interpreting the postulate

Effectively, the postulate states that the structure of a transition state resembles that of the species nearest to it in free energy. This can be explained with reference to potential energy diagrams:

In case (a), which is an exothermic reaction, the energy of the transition state is closer in energy to that of the reactant than that of the intermediate or the product. Therefore, from the postulate, the structure of the transition state also more closely resembles that of the reactant. In case (b), the energy of the transition state is close to neither the reactant nor the product, making none of them a good structural model for the transition state. Further information would be needed in order to predict the structure or characteristics of the transition state. Case (c) depicts the potential diagram for an endothermic reaction, in which, according to the postulate, the transition state should more closely resemble that of the intermediate or the product.

Another significance of Hammond’s postulate is that it permits us to discuss the structure of the transition state in terms of the reactants, intermediates, or products. In the case where the transition state closely resembles the reactants, the transition state is called “early” while a “late” transition state is the one that closely resembles the intermediate or the product.[14]

An example of the “early” transition state is chlorination. Chlorination favors the products because it is an exothermic reaction, which means that the products are lower in energy than the reactants.[15] When looking at the adjacent diagram (representation of an "early" transition state), one must focus on the transition state, which is not able to be observed during an experiment. To understand what is meant by an “early” transition state, the Hammond postulate represents a curve that shows the kinetics of this reaction. Since the reactants are higher in energy, the transition state appears to be right after the reaction starts.

An example of the “late” transition state is bromination. Bromination favors the reactants because it is an endothermic reaction, which means that the reactants are lower in energy than the products.[16] Since the transition state is hard to observe, the postulate of bromination helps to picture the “late” transition state (see the representation of the "late" transition state). Since the products are higher in energy, the transition state appears to be right before the reaction is complete.

One other useful interpretation of the postulate often found in textbooks of organic chemistry is the following:

Assume that the transition states for reactions involving unstable intermediates can be closely approximated by the intermediates themselves.

This interpretation ignores extremely exothermic and endothermic reactions which are relatively unusual and relates the transition state to the intermediates which are usually the most unstable.

Structure of transition states

SN1 reactions

Energy diagrams of SN1 reactions

Hammond's postulate can be used to examine the structure of the transition states of a SN1 reaction. In particular, the dissociation of the leaving group is the first transition state in a SN1 reaction. The stabilities of the carbocations formed by this dissociation are known to follow the trend tertiary > secondary > primary > methyl.

Therefore, since the tertiary carbocation is relatively stable and therefore close in energy to the R-X reactant, then the tertiary transition state will have a structure that is fairly similar to the R-X reactant. In terms of the graph of reaction coordinate versus energy, this is shown by the fact that the tertiary transition state is further to the left than the other transition states. In contrast, the energy of a methyl carbocation is very high, and therefore the structure of the transition state is more similar to the intermediate carbocation than to the R-X reactant. Accordingly, the methyl transition state is very far to the right.

SN2 reactions

Substitution, nucleophilic bimolecular reactions are concerted reactions where both the nucleophile and substrate are involved in the rate limiting step. Since this reaction is concerted, the reaction occurs in one step, where the bonds are broken, while new bonds are formed.[17] Therefore, to interpret this reaction, it is important to look at the transition state, which resembles the concerted rate limiting step. In the "Depiction of SN2 Reaction" figure, the nucleophile forms a new bond to the carbon, while the halide (L) bond is broken.[18]

E1 reactions

Unimolecular Elimination Reaction Mechanism

An E1 reaction consists of an unimolecular elimination, where the rate determining step of the mechanism depends on the removal of a single molecular species. This is a two-step mechanism. The more stable the carbocation intermediate is, the faster the reaction will proceed, favoring the products. Stabilization of the carbocation intermediate lowers the activation energy. The reactivity order is (CH3)3C- > (CH3)2CH- > CH3CH2- > CH3-.[19]

Unimolecular Elimination Reaction Coordinate

Furthermore, studies describe a typical kinetic resolution process that starts out with two enantiomers that are energetically equivalent and, in the end, forms two energy-inequivalent intermediates, referred to as diastereomers. According to Hammond's postulate, the more stable diastereomer is formed faster.[20]

E2 reactions

Elimination, bimolecular reactions are one step, concerted reaction where both base and substrate participate in the rate limiting step. In an E2 mechanism, a base takes a proton near the leaving group, forcing the electrons down to make a double bond, and forcing off the leaving group-all in one concerted step. The rate law depends on the first order concentration of two reactants, making it a 2nd order (bimolecular) elimination reaction. Factors that affect the rate determining step are stereochemistry, leaving groups, and base strength.

A theory, for an E2 reaction, by Joseph Bunnett suggests the lowest pass through the energy barrier between reactants and products is gained by an adjustment between the degrees of Cβ-H and Cα-X rupture at the transition state. The adjustment involves much breaking of the bond more easily broken, and a small amount of breaking of the bond which requires more energy.[21] This conclusion by Bunnett is a contradiction from the Hammond postulate. The Hammond postulate is the opposite of what Bunnett theorized. In the transition state of a bond breaking step it involves little breaking when the bond is easily broken and much breaking when it is difficult to break.[21] Despite these differences, the two postulates are not in conflict since they are concerned with different sorts of processes. Hammond focuses on reaction steps where one bond is made or broken, or the breaking of two or more bonds occur simultaneously. The E2 theory transition state concerns a process when bond formation or breaking are not simultaneous.[21]

Kinetics and the Bell-Evans-Polanyi principle

Technically, Hammond's postulate only describes the geometric structure of a chemical reaction. However, Hammond's postulate indirectly gives information about the rate, kinetics, and activation energy of reactions. Hence, it gives a theoretical basis for the understanding the Bell-Evans-Polanyi principle, which describes the experimental observation that the enthalpy and rate of a similar reactions were usually correlated.

Energy diagrams of SN1 reactions

The relationship between Hammond's postulate and the BEP principle can be understood by considering a SN1 reaction. Although two transition states occur during a SN1 reaction (dissociation of the leaving group and then attack by the nucleophile), the dissociation of the leaving group is almost always the rate-determining step. Hence, the activation energy and therefore rate of the reaction will depend only upon the dissociation step.

First, consider the reaction at secondary and tertiary carbons. As the BEP principle notes, experimentally SN1 reactions at tertiary carbons are faster than at secondary carbons. Therefore, by definition, the transition state for tertiary reactions will be at a lower energy than for secondary reactions. However, the BEP principle cannot justify why the energy is lower.

Using Hammond's postulate, the lower energy of the tertiary transition state means that its structure is relatively closer to its reactants R(tertiary)-X than to the carbocation "product" when compared to the secondary case. Thus, the tertiary transition state will be more geometrically similar to the R(tertiary)-X reactants than the secondary transition state is to its R(secondary)-X reactants. Hence, if the tertiary transition state is close in structure to the (low energy) reactants, then it will also be lower in energy because structure determines energy. Likewise, if the secondary transition state is more similar to the (high energy) carbocation "product," then it will be higher in energy.

Applying the postulate

Hammond's postulate is useful for understanding the relationship between the rate of a reaction and the stability of the products. While the rate of a reaction depends just on the activation energy (often represented in organic chemistry as ΔG “delta G double dagger”), the final ratios of products in chemical equilibrium depends only on the standard free-energy change ΔG (“delta G”). The ratio of the final products at equilibrium corresponds directly with the stability of those products.

Hammond's postulate connects the rate of a reaction process with the structural features of those states that form part of it, by saying that the molecular reorganizations have to be small in those steps that involve two states that are very close in energy. This gave birth to the structural comparison between the starting materials, products, and the possible "stable intermediates" that led to the understanding that the most stable product is not always the one that is favored in a reaction process.

Critical acclaim and question

Hammond's postulate is especially important when looking at the rate-limiting step of a reaction. However, one must be cautious when examining a multistep reaction or one with the possibility of rearrangements during an intermediate stage. In some cases, the final products appear in skewed ratios in favor of a more unstable product (called the kinetic product) rather than the more stable product (the thermodynamic product). In this case one must examine the rate-limiting step and the intermediates. Often, the rate-limiting step is the initial formation of an unstable species such as a carbocation. Then, once the carbocation is formed, subsequent rearrangements can occur. In these kinds of reactions, especially when run at lower temperatures, the reactants simply react before the rearrangements necessary to form a more stable intermediate have time to occur. At higher temperatures when microscopic reversal is easier, the more stable thermodynamic product is favored because these intermediates have time to rearrange. Whether run at high or low temperatures, the mixture of the kinetic and thermodynamic products eventually reach the same ratio, one in favor of the more stable thermodynamic product, when given time to equilibrate due to microreversal.

Death and legacy

Hammond married Marian Reese in 1945, and had five children with her. The couple divorced in 1975, and he was remarried soon after to Eve Menger. He had two children with Eve.[2]

See also

References

  1. 1 2 3 Weiss, Richard G.; Wamser, Carl C. (2006). "Introduction to the Special Issue in honour of George Simms Hammond". Photochemical & Photobiological Sciences. The Royal Society of Chemistry and Owner Societies (10): 869–870. doi:10.1039/b612175f. Retrieved 28 May 2013.
  2. 1 2 3 4 5 6 7 8 9 10 11 12 13 Wamser, Carl C. (2003-05-01). "Biography of George S. Hammond". The Journal of Physical Chemistry A. 107 (18): 3149–3150. doi:10.1021/jp030184e. ISSN 1089-5639.
  3. 1 2 3 4 Yarnell, Amanda. Hammond Postulate: 1955 paper used transition-state theory to explain structure-reactivity relationships. Chemical & Engineering News May 19, 2003, 81(20), 42
  4. 1 2 3 Leffler, J. E. Parameters for the Description of Transition States. Science 1953, 117, 340–341.
  5. Fox and Whiteshell, Marye Anne and James K. (2004). Organic Chemistry. Sudbury, Massachusetts: Jones and Bartlett Publishers. pp. 355–357. ISBN 0-7637-2197-2.
  6. "Obituaries", C&EN, 83(48), 46 (November 28, 2005).
  7. "Chemical Heritage Foundation names John Baldeschwieler and George Hammond 2003 Othmer Gold Medalists". Eureka Alert. 1 April 2003. Retrieved 12 June 2014.
  8. "Othmer Gold Medal". Chemical Heritage Foundation. Retrieved 1 December 2016.
  9. Hammond, G. S. (1955). "A Correlation of Reaction Rates". J. Am. Chem. Soc. 77: 334–338. doi:10.1021/ja01607a027. Solomons, T.W. Graham & Fryhle, Craig B. (2004). Organic Chemistry (8th ed.). John Wiley & Sons, Inc. ISBN 0-471-41799-8.
    Loudon, G. Marc. "Organic Chemistry" 4th ed. 2005.
  10. Carey, Francis A.; Sundberg, Richard (2007). Advanced Organic Chemistry Part A:Structure and Mechanisms. Norwell: Springer.
  11. Anslyn, Eric V.; Dougherty, Dennis A. (2006). Modern Physical Organic Chemistry. Sausalito, CA: University Science.
  12. McMurry, John (1992). Organic Chemistry. Pacific Grove, CA: Brooks/Cole. pp. 246–248.
  13. Carey, F.A.; Sundberg, R.J. (1990). Advanced Organic Chemistry.-Part A: Structure and Mechanism. New York, NY: Plenum.
  14. Meany, J.E. (1 February 2001). "Application of Hammond's postulate". Journal of the chemical education. 01. 2 (78): 204.
  15. Fox, Marye Anne; Whitesell, James K. (2004). Organic Chemistry Third Edition. Sudbury, MA: Jones and Barlett Publishers. p. 356.
  16. Sorrell, Thomas N. (2005). Organic Chemistry Third Edition. Sausalito, CA: University Science Books. pp. 370–371.
  17. Anslyn, Eric V.; Brown, William H.; Foote, Christopher S.; Iverson, Brent L. (2009). Organic Chemistry Fifth Edition. Belmont, CA: Brooks/Cole Cengage Learning. p. 333.
  18. Curtis, Rachael (October 2, 2013). "Kinetics of Nucleophilic Substitution Reactions". Chemwiki. UCDavis. Retrieved November 21, 2015.
  19. Justik, Michael W. "Review of SN1, SN2, E1, and E2" (PDF).
  20. Rajendran, Kamalraj V.; Nikitin, Kirill V.; Gilheany, Declan G. (2015-07-17). "Hammond Postulate Mirroring Enables Enantiomeric Enrichment of Phosphorus Compounds via Two Thermodynamically Interconnected Sequential Stereoselective Processes". Journal of the American Chemical Society. 137 (29): 9375–9381. doi:10.1021/jacs.5b04415.
  21. 1 2 3 Bunnett, Joseph (1962). Survey of Progress in Chemistry. New York: Academic. pp. 70–72.

Further reading

External links

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