R. Tom Baker

Last updated
R. Tom Baker
Born
Tsawwassen, British Columbia, Canada
Alma mater University of British Columbia and University of California, Los Angeles
Scientific career
Fields Chemistry
Institutions University of Ottawa, Los Alamos National Laboratory, DuPont CR&D
Doctoral advisor M. Frederick Hawthorne

R. Tom Baker is an inorganic chemist known for the development and application of inorganic transition metal-based catalysis.

Contents

Education

R. Tom Baker was born in Tsawwassen, British Columbia, Canada. He attended University of British Columbia (UBC) as an undergraduate student and earned his B.Sc in Chemistry in 1975. He then conducted his graduate research work under M. Frederick Hawthorne at University of California, Los Angeles (UCLA). After he earned his Ph.D in Inorganic Chemistry in 1980, he spent a year as a postdoctoral fellow with Philip S. Skell at Pennsylvania State University.

Career

From 1981 to 1996, Baker worked as a research chemist at DuPont CR&D where he became a homogeneous catalysis scouting group leader in 1993. In 1996 he joined Inorganic Isotopes and Actinides Group at Los Alamos National Laboratory (LANL) to work as a research chemist. In 2008 he joined the faculty at University of Ottawa. He was a director of Centre for Catalysis Research and Innovation from 2008 to 2015. He currently is a Canada Research Chair in Catalysis Science for Energy Applications. In 2009, he was awarded fellowship from the American Association for the Advancement of Science (AAAS).

Research

Baker has made contributions to the development and application of inorganic transition metal-based catalysis in many areas of chemical industry and academia. During the years at DuPont, his research was focused on developing and applying inorganic homogeneous catalysis to industrial products such as fluorocarbons and nylon, as well as developing transition metal boryl compounds such as boryliridium complexes to facilitate the hydroboration of alkenes. [1] [2] After he joined LANL, he turned his interest towards developing sustainable synthetic chemistry with multiphasic, multifunctional catalysis at low temperatures to minimize energy consumption and chemical wastes, [3] [4] as well as B-N containing compounds for chemical hydrogen storage. [5]

Much of his recent research has been focused on sustainability and green chemistry, such as developing efficient transition metal-based catalysts for hydrogen storage compounds in order to utilize hydrogen as an alternate safe and clean energy resource. This includes a broad work of B-N containing compounds such as ammonia-borane (H3NBH3) as an ideal hydrogen fuel carrier, [6] as well as developing inexpensive earth-abundant transition metal-based catalysts such as iron complex to facilitate dehydrogenation process of ammonia-borane with less expenses. [7] His work provides insight into the second hydrogen release step of dehydrogenation by isolation and characterization of reaction intermediate. [8]

Baker also works on utilizing copper and vanadium homogeneous catalysts to facilitate aerobic oxidation of lignocellulose to obtain small monomeric organic molecules which can produce more valuable chemicals and renewable biofuels. This research includes investigating reactivity and oxidation selectivity of different metal catalysts towards a variety of lignin models, a study of C-O bond and C-C bond cleavage pathways towards simple and complex lignin models, and the function of base in the aerobic oxidation process. [9] [10] Baker’s recent research also includes the development of tandem catalytic system to convert ethanol to n-butanol with high selectivity. [11] N-butanol, owing to its high energy density and immiscibility with water, is known as a better renewable biofuel than ethanol.

His group has also made substantial contributions to organofluorine chemistry, especially on metal-based fluorocarbenes, including synthesis of a variety of fluorocarbene transition metal complexes by directly introducing difluorocarbene ligands to transition metal centres such as cobalt and nickel, [12] [13] as well as investigating [2+2] cycloaddition reactions between metal fluorocarbenes and tetrafuoroethylene (TFE), which sheds light on a greener route to produce fluorocarbons from waste polytetrafluoroethylene materials. [14]

Lignocellulose disassembly to break down common lignin linkage into monomeric molecules by transition metal-based catalysts. R.Tom Baker's research figure 1.jpg
Lignocellulose disassembly to break down common lignin linkage into monomeric molecules by transition metal-based catalysts.
Tandem catalytic system to convert ethanol to n-butanol with high selectivity. R. Tom Baker figure 2.jpg
Tandem catalytic system to convert ethanol to n-butanol with high selectivity.

Related Research Articles

<span class="mw-page-title-main">Catalysis</span> Process of increasing the rate of a chemical reaction

Catalysis is the process of increasing the rate of a chemical reaction by adding a substance known as a catalyst. Catalysts are not consumed by the reaction and remain unchanged after it. If the reaction is rapid and the catalyst recycles quickly, very small amounts of catalyst often suffice; mixing, surface area, and temperature are important factors in reaction rate. Catalysts generally react with one or more reactants to form intermediates that subsequently give the final reaction product, in the process of regenerating the catalyst.

<span class="mw-page-title-main">Organometallic chemistry</span> Study of organic compounds containing metal(s)

Organometallic chemistry is the study of organometallic compounds, chemical compounds containing at least one chemical bond between a carbon atom of an organic molecule and a metal, including alkali, alkaline earth, and transition metals, and sometimes broadened to include metalloids like boron, silicon, and selenium, as well. Aside from bonds to organyl fragments or molecules, bonds to 'inorganic' carbon, like carbon monoxide, cyanide, or carbide, are generally considered to be organometallic as well. Some related compounds such as transition metal hydrides and metal phosphine complexes are often included in discussions of organometallic compounds, though strictly speaking, they are not necessarily organometallic. The related but distinct term "metalorganic compound" refers to metal-containing compounds lacking direct metal-carbon bonds but which contain organic ligands. Metal β-diketonates, alkoxides, dialkylamides, and metal phosphine complexes are representative members of this class. The field of organometallic chemistry combines aspects of traditional inorganic and organic chemistry.

<span class="mw-page-title-main">Hydrogenation</span> Chemical reaction between molecular hydrogen and another compound or element

Hydrogenation is a chemical reaction between molecular hydrogen (H2) and another compound or element, usually in the presence of a catalyst such as nickel, palladium or platinum. The process is commonly employed to reduce or saturate organic compounds. Hydrogenation typically constitutes the addition of pairs of hydrogen atoms to a molecule, often an alkene. Catalysts are required for the reaction to be usable; non-catalytic hydrogenation takes place only at very high temperatures. Hydrogenation reduces double and triple bonds in hydrocarbons.

In chemistry, dehydrogenation is a chemical reaction that involves the removal of hydrogen, usually from an organic molecule. It is the reverse of hydrogenation. Dehydrogenation is important, both as a useful reaction and a serious problem. At its simplest, it is useful way of converting alkanes, which are relatively inert and thus low-valued, to olefins, which are reactive and thus more valuable. Alkenes are precursors to aldehydes, alcohols, polymers, and aromatics. As a problematic reaction, the fouling and inactivation of many catalysts arises via coking, which is the dehydrogenative polymerization of organic substrates.

<span class="mw-page-title-main">Heterogeneous catalysis</span> Type of catalysis involving reactants & catalysts in different phases of matter

In chemistry, heterogeneous catalysis is catalysis where the phase of catalysts differs from that of the reactants or products. The process contrasts with homogeneous catalysis where the reactants, products and catalyst exist in the same phase. Phase distinguishes between not only solid, liquid, and gas components, but also immiscible mixtures, or anywhere an interface is present.

In chemistry, homogeneous catalysis is catalysis by a soluble catalyst in a solution. Homogeneous catalysis refers to reactions where the catalyst is in the same phase as the reactants, principally in solution. In contrast, heterogeneous catalysis describes processes where the catalysts and substrate are in distinct phases, typically solid-gas, respectively. The term is used almost exclusively to describe solutions and implies catalysis by organometallic compounds. Homogeneous catalysis is an established technology that continues to evolve. An illustrative major application is the production of acetic acid. Enzymes are examples of homogeneous catalysts.

The water–gas shift reaction (WGSR) describes the reaction of carbon monoxide and water vapor to form carbon dioxide and hydrogen:

<span class="mw-page-title-main">Transition metal pincer complex</span>

In chemistry, a transition metal pincer complex is a type of coordination complex with a pincer ligand. Pincer ligands are chelating agents that binds tightly to three adjacent coplanar sites in a meridional configuration. The inflexibility of the pincer-metal interaction confers high thermal stability to the resulting complexes. This stability is in part ascribed to the constrained geometry of the pincer, which inhibits cyclometallation of the organic substituents on the donor sites at each end. In the absence of this effect, cyclometallation is often a significant deactivation process for complexes, in particular limiting their ability to effect C-H bond activation. The organic substituents also define a hydrophobic pocket around the reactive coordination site. Stoichiometric and catalytic applications of pincer complexes have been studied at an accelerating pace since the mid-1970s. Most pincer ligands contain phosphines. Reactions of metal-pincer complexes are localized at three sites perpendicular to the plane of the pincer ligand, although in some cases one arm is hemi-labile and an additional coordination site is generated transiently. Early examples of pincer ligands were anionic with a carbanion as the central donor site and flanking phosphine donors; these compounds are referred to as PCP pincers.

<span class="mw-page-title-main">Robert H. Crabtree</span> British-American chemist

Robert Howard Crabtree is a British-American chemist. He is serving as Conkey P. Whitehead Professor Emeritus of Chemistry at Yale University in the United States. He is a naturalized citizen of the United States. Crabtree is particularly known for his work on "Crabtree's catalyst" for hydrogenations, and his textbook on organometallic chemistry.

<span class="mw-page-title-main">Ammonia borane</span> Chemical compound

Ammonia borane (also systematically named amminetrihydridoboron), also called borazane, is the chemical compound with the formula H3NBH3. The colourless or white solid is the simplest molecular boron-nitrogen-hydride compound. It has attracted attention as a source of hydrogen fuel, but is otherwise primarily of academic interest.

<span class="mw-page-title-main">Hydrogen storage</span> Methods of storing hydrogen for later use

Several methods exist for storing hydrogen. These include mechanical approaches such as using high pressures and low temperatures, or employing chemical compounds that release H2 upon demand. While large amounts of hydrogen are produced by various industries, it is mostly consumed at the site of production, notably for the synthesis of ammonia. For many years hydrogen has been stored as compressed gas or cryogenic liquid, and transported as such in cylinders, tubes, and cryogenic tanks for use in industry or as propellant in space programs. Interest in using hydrogen for on-board storage of energy in zero-emissions vehicles is motivating the development of new methods of storage, more adapted to this new application. The overarching challenge is the very low boiling point of H2: it boils around 20.268 K (−252.882 °C or −423.188 °F). Achieving such low temperatures requires expending significant energy.

<span class="mw-page-title-main">Concurrent tandem catalysis</span>

Concurrent tandem catalysis (CTC) is a technique in chemistry where multiple catalysts produce a product otherwise not accessible by a single catalyst. It is usually practiced as homogeneous catalysis. Scheme 1 illustrates this process. Molecule A enters this catalytic system to produce the comonomer, B, which along with A enters the next catalytic process to produce the final product, P. This one-pot approach can decrease product loss from isolation or purification of intermediates. Reactions with relatively unstable products can be generated as intermediates because they are only transient species and are immediately used in a consecutive reaction.

<span class="mw-page-title-main">Shvo catalyst</span> Chemical compound

The Shvo catalyst is an organoruthenium compound that catalyzes the hydrogenation of polar functional groups including aldehydes, ketones and imines. The compound is of academic interest as an early example of a catalyst for transfer hydrogenation that operates by an "outer sphere mechanism". Related derivatives are known where p-tolyl replaces some of the phenyl groups. Shvo's catalyst represents a subset of homogeneous hydrogenation catalysts that involves both metal and ligand in its mechanism.

Gábor Laurenczy is a Hungarian-Swiss chemist and academic. He is a Professor Emeritus at the École Polytechnique Fédérale de Lausanne. He is academician, External Member of the Hungarian Academy of Sciences.

<span class="mw-page-title-main">Hydrogen auto-transfer</span>

Hydrogen auto-transfer, also known as borrowing hydrogen, is the activation of a chemical reaction by temporary transfer of two hydrogen atoms from the reactant to a catalyst and return of those hydrogen atoms back to a reaction intermediate to form the final product. Two major classes of borrowing hydrogen reactions exist: (a) those that result in hydroxyl substitution, and (b) those that result in carbonyl addition. In the former case, alcohol dehydrogenation generates a transient carbonyl compound that is subject to condensation followed by the return of hydrogen. In the latter case, alcohol dehydrogenation is followed by reductive generation of a nucleophile, which triggers carbonyl addition. As borrowing hydrogen processes avoid manipulations otherwise required for discrete alcohol oxidation and the use of stoichiometric organometallic reagents, they typically display high levels of atom-economy and, hence, are viewed as examples of Green chemistry.

<span class="mw-page-title-main">Boranylium ions</span>

In chemistry, a boranylium ion is an inorganic cation with the chemical formula BR+
2
, where R represents a non-specific substituent. Being electron-deficient, boranylium ions form adducts with Lewis bases. Boranylium ions have historical names that depend on the number of coordinated ligands:

Dehydrogenation of amine-boranes or dehydrocoupling of amine-boranes is a chemical process in main group and organometallic chemistry wherein dihydrogen is released by the coupling of two or more amine-borane adducts. This process is of due to the potential of using amine-boranes for hydrogen storage.

Karen Ila Goldberg is an American chemist, currently the Vagelos Professor of Energy Research at University of Pennsylvania. Goldberg is most known for her work in inorganic and organometallic chemistry. Her most recent research focuses on catalysis, particularly on developing catalysts for oxidation, as well as the synthesis and activation of molecular oxygen. In 2018, Goldberg was elected to the National Academy of Sciences.

Metal-ligand cooperativity (MLC) is a mode of reactivity in which a metal and ligand of a complex are both involved in the bond breaking or bond formation of a substrate during the course of a reaction. This ligand is an actor ligand rather than a spectator, and the reaction is generally only deemed to contain MLC if the actor ligand is doing more than leaving to provide an open coordination site. MLC is also referred to as "metal-ligand bifunctional catalysis." Note that MLC is not to be confused with cooperative binding.

Heterogeneous metal catalyzed cross-coupling is a subset of metal catalyzed cross-coupling in which a heterogeneous metal catalyst is employed. Generally heterogeneous cross-coupling catalysts consist of a metal dispersed on an inorganic surface or bound to a polymeric support with ligands. Heterogeneous catalysts provide potential benefits over homogeneous catalysts in chemical processes in which cross-coupling is commonly employed—particularly in the fine chemical industry—including recyclability and lower metal contamination of reaction products. However, for cross-coupling reactions, heterogeneous metal catalysts can suffer from pitfalls such as poor turnover and poor substrate scope, which have limited their utility in cross-coupling reactions to date relative to homogeneous catalysts. Heterogeneous metal catalyzed cross-couplings, as with homogeneous metal catalyzed ones, most commonly use Pd as the cross-coupling metal.

References

  1. Baker, R. Thomas; Ovenall, Derick W.; Calabrese, Joseph C.; Westcott, Stephen A.; Taylor, Nicholas J.; Williams, Ian D.; Marder, Todd B. (December 1990). "Boryliridium and boraethyliridium complexes fac-[IrH2(PMe3)3(BRR')] and fac-[IrH(PMe3)3(.eta.2-CH2BHRR')]". Journal of the American Chemical Society. 112 (25): 9399–9400. doi:10.1021/ja00181a055.
  2. Burgess, Kevin; Van der Donk, Wilfred A.; Westcott, Stephen A.; Marder, Todd B.; Baker, R. Thomas; Calabrese, Joseph C. (November 1992). "Reactions of catecholborane with Wilkinson's catalyst: implications for transition metal-catalyzed hydroborations of alkenes". Journal of the American Chemical Society. 114 (24): 9350–9359. doi:10.1021/ja00050a015.
  3. Baker, R. T. (28 May 1999). "HOMOGENEOUS CATALYSIS:Enhanced: Toward Greener Chemistry". Science. 284 (5419): 1477–1479. doi:10.1126/science.284.5419.1477. S2CID   93160815.
  4. Liu, Fuchen; Abrams, Michael B.; Baker, R. Tom; Tumas, William (2001). "Phase-separable catalysis using room temperature ionic liquids and supercritical carbon dioxide". Chemical Communications (5): 433–434. doi:10.1039/B009701M.
  5. Keaton, Richard J.; Blacquiere, Johanna M.; Baker, R. Tom (February 2007). "Base Metal Catalyzed Dehydrogenation of Ammonia−Borane for Chemical Hydrogen Storage". Journal of the American Chemical Society. 129 (7): 1844–1845. doi:10.1021/ja066860i. PMID   17253687.
  6. Stephens, Frances H.; Pons, Vincent; Tom Baker, R. (2007). "Ammonia–borane: the hydrogen source par excellence?". Dalton Trans. (25): 2613–2626. doi:10.1039/B703053C. PMID   17576485.
  7. Baker, R. Tom; Gordon, John C.; Hamilton, Charles W.; Henson, Neil J.; Lin, Po-Heng; Maguire, Steven; Murugesu, Muralee; Scott, Brian L.; Smythe, Nathan C. (28 March 2012). "Iron Complex-Catalyzed Ammonia–Borane Dehydrogenation. A Potential Route toward B–N-Containing Polymer Motifs Using Earth-Abundant Metal Catalysts". Journal of the American Chemical Society. 134 (12): 5598–5609. doi:10.1021/ja210542r. PMID   22428955.
  8. Kalviri, Hassan A.; Gärtner, Felix; Ye, Gang; Korobkov, Ilia; Baker, R. Tom (2015). "Probing the second dehydrogenation step in ammonia-borane dehydrocoupling: characterization and reactivity of the key intermediate, B-(cyclotriborazanyl)amine-borane". Chem. Sci. 6 (1): 618–624. doi:10.1039/C4SC02710H. PMC   5491959 . PMID   28706630.
  9. Hanson, Susan K.; Baker, R. Tom (21 July 2015). "Knocking on Wood: Base Metal Complexes as Catalysts for Selective Oxidation of Lignin Models and Extracts". Accounts of Chemical Research. 48 (7): 2037–2048. doi:10.1021/acs.accounts.5b00104. PMID   26151603.
  10. Díaz-Urrutia, Christian; Chen, Wei-Ching; Crites, Charles-Oneil; Daccache, Jennifer; Korobkov, Ilia; Baker, R. Tom (2015). "Towards lignin valorisation: comparing homogeneous catalysts for the aerobic oxidation and depolymerisation of organosolv lignin". RSC Adv. 5 (86): 70502–70511. doi:10.1039/C5RA15694G.
  11. Chakraborty, Sumit; Piszel, Paige E.; Hayes, Cassandra E.; Baker, R. Tom; Jones, William D. (18 November 2015). "Highly Selective Formation of n-Butanol from Ethanol through the Guerbet Process: A Tandem Catalytic Approach". Journal of the American Chemical Society. 137 (45): 14264–14267. doi:10.1021/jacs.5b10257. PMID   26526779.
  12. Lee, Graham M.; Harrison, Daniel J.; Korobkov, Ilia; Baker, R. Tom (2014). "Stepwise addition of difluorocarbene to a transition metal centre". Chem. Commun. 50 (9): 1128–1130. doi:10.1039/C3CC48468H. PMID   24322965.
  13. Harrison, Daniel J.; Daniels, Alex L.; Korobkov, Ilia; Baker, R. Tom (28 September 2015). "Tetracarbonyl(trifluoromethyl)cobalt(I) [Co(CO)4(CF3)] as a Precursor to New Cobalt Trifluoromethyl and Difluorocarbene Complexes". Organometallics. 34 (18): 4598–4604. doi:10.1021/acs.organomet.5b00674.
  14. Harrison, Daniel J.; Lee, Graham M.; Leclerc, Matthew C.; Korobkov, Ilia; Baker, R. Tom (11 December 2013). "Cobalt Fluorocarbenes: Cycloaddition Reactions with Tetrafluoroethylene and Reactivity of the Perfluorometallacyclic Products". Journal of the American Chemical Society. 135 (49): 18296–18299. doi:10.1021/ja411503c. PMID   24294941.