Stahl oxidation

Last updated
Stahl oxidation
Named after Shannon S. Stahl
Reaction type Organic redox reaction

The Stahl oxidation is a copper-catalyzed aerobic oxidation of primary and secondary alcohols to aldehydes and ketones. Known for its high selectivity and mild reaction conditions, the Stahl oxidation offers several advantages over classical alcohol oxidations.

Contents

Key features of the Stahl oxidation are the use of a 2,2'-bipyridyl-ligated copper(I) species in the presence of a nitroxyl radical and N-methyl imidazole in polar aprotic solvent, most commonly acetonitrile or acetone. [1] [2] [3] Copper(I) sources can vary, though sources with non-coordinating anions like triflate, tetrafluoroborate, and hexafluorophosphate are preferred, [1] with copper(I) bromide [2] and copper(I) iodide [4] salts demonstrating utility in select applications. Frequently, tetrakis(acetonitrile)copper(I) salts are used. [1] [5] [6] [7] For most applications, reactions can be run at room temperature and ambient air contains sufficiently high enough oxygen concentrations to be used as the terminal oxidant. Compared to chromium-, DMSO-, or periodinane-mediated oxidations, this proves safe, environmentally-friendly, practical, and highly economical. [8]

Model substrate used in Hoover & Stahl's seminal work. Under these conditions, >98% yields were observed by gas chromatography. StahlOxidationScheme.jpg
Model substrate used in Hoover & Stahl's seminal work. Under these conditions, >98% yields were observed by gas chromatography.

In general, the Stahl oxidation is selective for oxidizing primary alcohols over secondary alcohols (both aliphatic and benzylic), and favors the oxidation of primary benzylic alcohols over primary aliphatic alcohols when TEMPO is used as the nitroxyl radical. [1] This is in contrast to the Oppenauer oxidation, which favors the oxidation of secondary alcohols over primary and several other specialty oxidations. [10] [11] Over-oxidation of primary alcohols to carboxylic acids is rare, though lactones can form in certain diol-containing substrates. [1] [3] [7] The use of less hindered nitroxyl radicals like ABNO [12] or AZADO [13] allow for the oxidation of both primary and secondary alcohols. [14] [15]

History

In 2011, Jessica Hoover and Shannon Stahl disclosed improved conditions for selective oxidation of primary alcohols to aldehydes using a (bpy)copper(I)/TEMPO system. [1] While several catalytic aerobic oxidation systems were known at the time, many utilized palladium, which can be prohibitive through its expense [16] and its cross-reactivity with alkene-bearing substrates. [17] [18] Aerobic oxidative catalysis of alcohols by copper, though known since at least 1984, [19] was generally lower performing, requiring some combination of elevated reaction temperatures, higher catalyst loading, handling of pure oxygen, and biphasic or otherwise non-common solvent systems. [20] [21] [22]

Following the success of this initial disclosure, Hoover and Stahl went on to publish a further simplified protocol for rapid benzylic alcohol oxidation with Nicolas Hill, director of undergraduate organic chemistry laboratories at the University of Wisconsin - Madison. [2] [23] Utilizing a less expensive solvent and copper source, Hill, Hoover, and Stahl demonstrated that higher catalyst loadings could be economically achieved. In doing so, the oxidation of alcohols could be accelerated for use as a practical educational tool in undergraduate labs. Furthermore, reaction completion is typically indicated by a change in solution color for red/brown to green resulting from a change in the copper species' resting state. [2] This is unique for benzylic and other activated alcohols, as the rate-limiting-step for these substrates is catalyst re-oxidation, which differs from aliphatic alcohols where the rate limiting step is C-H cleavage. [24] The Stahl oxidation is a component of the undergraduate organic chemistry laboratory curriculum at UW-Madison and the University of Utah. [25]

In 2013, the mechanism for the copper(I)/TEMPO oxidation of alcohols was elucidated, [24] and it was found the use of less hindered nitroxyl radical sources allowed for the oxidation of secondary alcohols. [14]

Modifications

Hoover-Stahl Oxidation of a primary benzylic alcohol on gram scale. Conditions - 3 mol% CuBr, 2,2'-bipyridyl, TEMPO; 6 mol% NMI; 0.2M in acetone. Left image: Time = 0 hr; Right image: Time = 12 hr. Note the change in brown to green color indicating a change in the resting state for the copper species. StahlOxidation.jpg
Hoover–Stahl Oxidation of a primary benzylic alcohol on gram scale. Conditions - 3 mol% CuBr, 2,2'-bipyridyl, TEMPO; 6 mol% NMI; 0.2M in acetone. Left image: Time = 0 hr; Right image: Time = 12 hr. Note the change in brown to green color indicating a change in the resting state for the copper species.

Hoover–Stahl oxidation

The Hoover–Stahl oxidation explicitly indicates the earliest of the Stahl oxidation conditions allowing for the selective oxidation of primary alcohols. The system utilizes 2,2'-bipyridine (bpy), a copper(I) source (typically tetrakis(acetonitrile) copper(I) triflate, tetrafluoroborate, or hexafluorophosphate), TEMPO, and N-methylimidazole. The reaction is conducted in acetonitrile at room temperature under an atmosphere or air. Catalyst loadings are typically around 5 mol %, with N-methylimidazole being used at 10 mol %. The reaction is selective for oxidation of primary alcohols to aldehydes and generally does not oxidize secondary alcohols. [1] Solutions for the Hoover–Stahl oxidation are commercially available from Millipore-Sigma, though the catalyst can be easily prepared in situ from common laboratory reagents. [1] [26]

Steves–Stahl oxidation

The Steves–Stahl oxidation indicates the use of a less hindered nitroxyl radical in the Stahl oxidation, allowing for the oxidation of secondary alcohols in addition to primary alcohols. [14] The reaction is conducted in acetonitrile at room temperature under an atmosphere of air, or less commonly, under an atmosphere of oxygen. Typically, the nitroxyl radical used in the Steves–Stahl is 9-Azabicyclo[3.3.1]nonane N-Oxyl (ABNO) [12] and is used in conjunction with a more strongly electron-donating 2,2'-bipyridyl ligand compared to bpy, like 4,4'-dimethoxy-2,2'-bipyridine, as this is shown to accelerate alcohol oxidation. [14] Due to the comparatively high price and reactivity of ABNO, common practice is to use it sparingly, oftentimes at catalytic loading of 1 mol % or less. [27] Solutions for the Steves–Stahl oxidation are commercially available through Millipore-Sigma, though the mixture can be easily prepared in situ. [28] Due to the high reagent cost associated with the Steves–Stahl oxidation, it is generally only employed for oxidation of secondary alcohols or after the Hoover–Stahl oxidation has proved fruitless. Several improved methods for the scalable preparation of ABNO have been recently published. [29] [30]

Xie–Stahl oxidative lactonization

The Xie–Stahl oxidative lactonization is a lactonization reaction which generally employs Steves–Stahl conditions for the oxidative cyclization of diols. [3] The Xie–Stahl reaction lends itself toward selective formation of γ-, δ-, and ε-lactones, forming the carbonyl at the less-hindered primary alcohol. In some instances, higher selectivity can be afforded through the use of 1 mol % TEMPO in place of ABNO. [3]

Zultanski–Zhao–Stahl oxidative amide coupling

The Zultanski–Zhao–Stahl oxidative amide coupling is a reaction between a primary alcohol and an amine to form an amide. [31] In the Zultanski–Zhao–Stahl reaction, a primary alcohol is oxidized to an aldehyde which, in the presence of an amine, reversibly forms a hemiaminal which is then irreversibly oxidized to the amide by the catalyst. The reaction is performed under an atmosphere of oxygen in the presence of 3Å molecular sieves using relatively high ABNO loading of 3 mol %. Optimal reaction conditions are substrate dependent, requiring specific copper(I) sources, ligands, and solvents depending on the structure of the starting alcohol and amines. [31]

Related Research Articles

<span class="mw-page-title-main">Wacker process</span> Chemical reaction

The Wacker process or the Hoechst-Wacker process refers to the oxidation of ethylene to acetaldehyde in the presence of palladium(II) chloride and copper(II) chloride as the catalyst. This chemical reaction was one of the first homogeneous catalysis with organopalladium chemistry applied on an industrial scale.

<span class="mw-page-title-main">Pauson–Khand reaction</span> Chemical reaction

The Pauson–Khand (PK) reaction is a chemical reaction, described as a [2+2+1] cycloaddition. In it, an alkyne, an alkene, and carbon monoxide combine into a α,β-cyclopentenone in the presence of a metal-carbonyl catalyst Ihsan Ullah Khand (1935–1980) discovered the reaction around 1970, while working as a postdoctoral associate with Peter Ludwig Pauson (1925–2013) at the University of Strathclyde in Glasgow. Pauson and Khand's initial findings were intermolecular in nature, but the reaction has poor selectivity. Some modern applications instead apply the reaction for intramolecular ends.

The Ullmann reaction or Ullmann coupling, named after Fritz Ullmann, couples two aryl or alkyl groups with the help of copper. The reaction was first reported by Ullmann and his student Bielecki in 1901. It has been later shown that palladium and nickel can also be effectively used.

The Baeyer–Villiger oxidation is an organic reaction that forms an ester from a ketone or a lactone from a cyclic ketone, using peroxyacids or peroxides as the oxidant. The reaction is named after Adolf von Baeyer and Victor Villiger who first reported the reaction in 1899.

The Negishi coupling is a widely employed transition metal catalyzed cross-coupling reaction. The reaction couples organic halides or triflates with organozinc compounds, forming carbon-carbon bonds (C-C) in the process. A palladium (0) species is generally utilized as the catalyst, though nickel is sometimes used. A variety of nickel catalysts in either Ni0 or NiII oxidation state can be employed in Negishi cross couplings such as Ni(PPh3)4, Ni(acac)2, Ni(COD)2 etc.

Oppenauer oxidation, named after Rupert Viktor Oppenauer, is a gentle method for selectively oxidizing secondary alcohols to ketones.

Chiral Lewis acids (CLAs) are a type of Lewis acid catalyst. These acids affect the chirality of the substrate as they react with it. In such reactions, synthesis favors the formation of a specific enantiomer or diastereomer. The method is an enantioselective asymmetric synthesis reaction. Since they affect chirality, they produce optically active products from optically inactive or mixed starting materials. This type of preferential formation of one enantiomer or diastereomer over the other is formally known as asymmetric induction. In this kind of Lewis acid, the electron-accepting atom is typically a metal, such as indium, zinc, lithium, aluminium, titanium, or boron. The chiral-altering ligands employed for synthesizing these acids often have multiple Lewis basic sites that allow the formation of a ring structure involving the metal atom.

<span class="mw-page-title-main">Liebeskind–Srogl coupling</span>

The Liebeskind–Srogl coupling reaction is an organic reaction forming a new carbon–carbon bond from a thioester and a boronic acid using a metal catalyst. It is a cross-coupling reaction. This reaction was invented by and named after Jiri Srogl from the Academy of Sciences, Czech Republic, and Lanny S. Liebeskind from Emory University, Atlanta, Georgia, USA. There are three generations of this reaction, with the first generation shown below. The original transformation used catalytic Pd(0), TFP = tris(2-furyl)phosphine as an additional ligand and stoichiometric CuTC = copper(I) thiophene-2-carboxylate as a co-metal catalyst. The overall reaction scheme is shown below.

<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">Vinyl iodide functional group</span>

In organic chemistry, a vinyl iodide functional group is an alkene with one or more iodide substituents. Vinyl iodides are versatile molecules that serve as important building blocks and precursors in organic synthesis. They are commonly used in carbon-carbon forming reactions in transition-metal catalyzed cross-coupling reactions, such as Stille reaction, Heck reaction, Sonogashira coupling, and Suzuki coupling. Synthesis of well-defined geometry or complexity vinyl iodide is important in stereoselective synthesis of natural products and drugs.

In organic chemistry, carbonyl allylation describes methods for adding an allyl anion to an aldehyde or ketone to produce a homoallylic alcohol. The carbonyl allylation was first reported in 1876 by Alexander Zaitsev and employed an allylzinc reagent.

<span class="mw-page-title-main">Krische allylation</span>

The Krische allylation involves the enantioselective iridium-catalyzed addition of an allyl group to an aldehyde or an alcohol, resulting in the formation of a secondary homoallylic alcohol. The mechanism of the Krische allylation involves primary alcohol dehydrogenation or, when using aldehyde reactants, hydrogen transfer from 2-propanol. Unlike other allylation methods, the Krische allylation avoids the use of preformed allyl metal reagents and enables the direct conversion of primary alcohols to secondary homoallylic alcohols.

Dialkylbiaryl phosphine ligands are phosphine ligands that are used in homogeneous catalysis. They have proved useful in Buchwald-Hartwig amination and etherification reactions as well as Negishi cross-coupling, Suzuki-Miyaura cross-coupling, and related reactions. In addition to these Pd-based processes, their use has also been extended to transformations catalyzed by nickel, gold, silver, copper, rhodium, and ruthenium, among other transition metals.

The Mukaiyama hydration is an organic reaction involving formal addition of an equivalent of water across an olefin by the action of catalytic bis(acetylacetonato)cobalt(II) complex, phenylsilane and atmospheric oxygen to produce an alcohol with Markovnikov selectivity.

The Riley oxidation is a selenium dioxide-mediated oxidation of methylene groups adjacent to carbonyls. It was first reported by Harry Lister Riley and co-workers in 1932. In the decade that ensued, selenium-mediated oxidation rapidly expanded in use, and in 1939, Andre Guillemonat and co-workers disclosed the selenium dioxide-mediated oxidation of olefins at the allylic position. Today, selenium-dioxide-mediated oxidation of methylene groups to alpha ketones and at the allylic position of olefins is known as the Riley Oxidation.

Organoniobium chemistry is the chemistry of compounds containing niobium-carbon (Nb-C) bonds. Compared to the other group 5 transition metal organometallics, the chemistry of organoniobium compounds most closely resembles that of organotantalum compounds. Organoniobium compounds of oxidation states +5, +4, +3, +2, +1, 0, -1, and -3 have been prepared, with the +5 oxidation state being the most common.

<span class="mw-page-title-main">Sukbok Chang</span> South Korean chemist (born 1962)

Sukbok Chang is a South Korean organic chemist. He is a distinguished professor in the Department of Chemistry at Korea Advanced Institute of Science and Technology (KAIST). He is also the director of the Institute for Basic Science (IBS) Center for Catalytic Hydrocarbon Functionalizations (CCHF). He was an associate editor on ACS Catalysis and has served on the editorial advisory boards of The Journal of Organic Chemistry, Journal of the American Chemical Society, and Accounts of Chemical Research. His major research interest is transition metal catalyzed C-H bond functionalization for the carbon-carbon bond and carbon-heteroatom bond formation.

Shuttle catalysis is used to describe catalytic reactions where a chemical entity of a donor molecule is transferred to an acceptor molecule. In these reactions, while the number of chemical bonds of each reactant changes, the types and total number of chemical bonds remain constant over the course of the reaction. In contrast to many organic reactions which exothermicity practically renders them irreversible, reactions operated under shuttle catalysis are often reversible. However, the position of the equilibrium can be driven to the product side through Le Chatelier’s principle. The driving forces for this equilibrium shift are typically the formation of a gas/precipitation, the use of high ground-state energy reactants or the formation of stabilized products or the excess equivalents of a reactant.

<span class="mw-page-title-main">Nitro-Mannich reaction</span>

The nitro-Mannich reaction is the nucleophilic addition of a nitroalkane to an imine, resulting in the formation of a beta-nitroamine. With the reaction involving the addition of an acidic carbon nucleophile to a carbon-heteroatom double bond, the nitro-Mannich reaction is related to some of the most fundamental carbon-carbon bond forming reactions in organic chemistry, including the aldol reaction, Henry reaction and Mannich reaction.

Alison Wendlandt is an American chemist who is an assistant professor at the Massachusetts Institute of Technology. Her research considers the development of catalysts for organic synthesis.

References

  1. 1 2 3 4 5 6 7 8 Hoover, Jessica M.; Stahl, Shannon S. (2011-10-26). "Highly Practical Copper(I)/TEMPO Catalyst System for Chemoselective Aerobic Oxidation of Primary Alcohols". Journal of the American Chemical Society. 133 (42): 16901–16910. doi: 10.1021/ja206230h . ISSN   0002-7863. PMC   3197761 . PMID   21861488.
  2. 1 2 3 4 Hill, Nicholas J.; Hoover, Jessica M.; Stahl, Shannon S. (2013-01-08). "Aerobic Alcohol Oxidation Using a Copper(I)/TEMPO Catalyst System: A Green, Catalytic Oxidation Reaction for the Undergraduate Organic Chemistry Laboratory". Journal of Chemical Education. 90 (1): 102–105. Bibcode:2013JChEd..90..102H. doi: 10.1021/ed300368q . ISSN   0021-9584.
  3. 1 2 3 4 Xie, Xiaomin; Stahl, Shannon S. (2015-03-25). "Efficient and Selective Cu/Nitroxyl-Catalyzed Methods for Aerobic Oxidative Lactonization of Diols". Journal of the American Chemical Society. 137 (11): 3767–3770. doi:10.1021/jacs.5b01036. ISSN   0002-7863. PMID   25751494.
  4. Ochen, Augustine; Whitten, Robert; Aylott, Helen E.; Ruffell, Katie; Williams, Glynn D.; Slater, Fiona; Roberts, Andrew; Evans, Paul; Steves, Janelle E.; Sanganee, Mahesh J. (2019-01-14). "Development of a Large-Scale Copper(I)/TEMPO-Catalyzed Aerobic Alcohol Oxidation for the Synthesis of LSD1 Inhibitor GSK2879552". Organometallics. 38 (1): 176–184. doi:10.1021/acs.organomet.8b00546. ISSN   0276-7333. S2CID   106029012.
  5. Forster, Michael; Chaikuad, Apirat; Dimitrov, Teodor; Döring, Eva; Holstein, Julia; Berger, Benedict-Tilman; Gehringer, Matthias; Ghoreschi, Kamran; Müller, Susanne; Knapp, Stefan; Laufer, Stefan A. (2018-05-31). "Development, Optimization, and Structure–Activity Relationships of Covalent-Reversible JAK3 Inhibitors Based on a Tricyclic Imidazo[5,4-d]pyrrolo[2,3-b]pyridine Scaffold". Journal of Medicinal Chemistry. 61 (12): 5350–5366. doi:10.1021/acs.jmedchem.8b00571. ISSN   0022-2623. PMID   29852068. S2CID   46919031.
  6. Lowell, Andrew N.; DeMars, Matthew D.; Slocum, Samuel T.; Yu, Fengan; Anand, Krithika; Chemler, Joseph A.; Korakavi, Nisha; Priessnitz, Jennifer K.; Park, Sung Ryeol; Koch, Aaron A.; Schultz, Pamela J. (2017-06-14). "Chemoenzymatic Total Synthesis and Structural Diversification of Tylactone-Based Macrolide Antibiotics through Late-Stage Polyketide Assembly, Tailoring, and C—H Functionalization". Journal of the American Chemical Society. 139 (23): 7913–7920. doi:10.1021/jacs.7b02875. ISSN   0002-7863. PMC   5532807 . PMID   28525276.
  7. 1 2 Alfonzo, Edwin; Beeler, Aaron B. (2019). "A sterically encumbered photoredox catalyst enables the unified synthesis of the classical lignan family of natural products". Chemical Science. 10 (33): 7746–7754. doi:10.1039/C9SC02682G. ISSN   2041-6520. PMC   6761868 . PMID   31588322.
  8. US EPA, OCSPP (2014-09-30). "Presidential Green Chemistry Challenge: 2014 Academic Award". US EPA. Retrieved 2020-02-02.
  9. Hoover, Jessica M.; Stahl, Shannon S. (2011-10-26). "Highly Practical Copper(I)/TEMPO Catalyst System for Chemoselective Aerobic Oxidation of Primary Alcohols". Journal of the American Chemical Society. 133 (42): 16901–16910. doi:10.1021/ja206230h. ISSN   0002-7863. PMC   3197761 . PMID   21861488.
  10. Mello, Rossella; Martínez-Ferrer, Jaime; Asensio, Gregorio; González-Núñez, María Elena (November 2007). "Oppenauer Oxidation of Secondary Alcohols with 1,1,1-Trifluoroacetone as Hydride Acceptor". The Journal of Organic Chemistry. 72 (24): 9376–9378. doi:10.1021/jo7016422. ISSN   0022-3263. PMID   17975928.
  11. Tojo, Gabriel. (2006). Oxidation of alcohols to aldehydes and ketones : a guide to current common practice. Fernández, Marcos (Marcos I.). New York, NY: Springer. ISBN   978-0-387-23607-0. OCLC   190867041.
  12. 1 2 "9-Azabicyclo[3.3.1]nonane N-Oxyl, ABNO". The Organic Chemistry Portal.
  13. "2-Azaadamantane N-Oxyl, AZADO". The Organic Chemistry Portal.
  14. 1 2 3 4 Steves, Janelle E.; Stahl, Shannon S. (2013-10-23). "Copper(I)/ABNO-Catalyzed Aerobic Alcohol Oxidation: Alleviating Steric and Electronic Constraints of Cu/TEMPO Catalyst Systems". Journal of the American Chemical Society. 135 (42): 15742–15745. doi:10.1021/ja409241h. ISSN   0002-7863. PMC   6346749 . PMID   24128057.
  15. Ryland, Bradford L.; Stahl, Shannon S. (2014-08-18). "Practical Aerobic Oxidations of Alcohols and Amines with Homogeneous Copper/TEMPO and Related Catalyst Systems". Angewandte Chemie International Edition. 53 (34): 8824–8838. doi:10.1002/anie.201403110. PMC   4165639 . PMID   25044821.
  16. "Live USD Palladium Price Charts & Historical Data". APMEX. Retrieved 2020-02-02.
  17. Nishimura, Takahiro; Kakiuchi, Nobuyuki; Onoue, Tomoaki; Ohe, Kouichi; Uemura, Sakae (2000). "Palladium(II)-catalyzed oxidation of terminal alkenes to methyl ketones using molecular oxygen". Journal of the Chemical Society, Perkin Transactions 1 (12): 1915–1918. doi:10.1039/b001854f.
  18. Mifsud, Maria; Parkhomenko, Ksenia V.; Arends, Isabel W.C.E.; Sheldon, Roger A. (January 2010). "Pd nanoparticles as catalysts for green and sustainable oxidation of functionalized alcohols in aqueous media". Tetrahedron. 66 (5): 1040–1044. doi:10.1016/j.tet.2009.11.007.
  19. Semmelhack, M. F.; Schmid, Christopher R.; Cortes, David A.; Chou, Chuen S. (May 1984). "Oxidation of alcohols to aldehydes with oxygen and cupric ion, mediated by nitrosonium ion". Journal of the American Chemical Society. 106 (11): 3374–3376. doi:10.1021/ja00323a064. ISSN   0002-7863.
  20. Gamez, Patrick; Arends, Isabel W. C. E.; Reedijk, Jan; Sheldon, Roger A. (2003). "Copper(ii)-catalysed aerobic oxidation of primary alcohols to aldehydes". Chemical Communications (19): 2414–5. doi:10.1039/b308668b. ISSN   1359-7345. PMID   14587708.
  21. Ragagnin, Gianna; Betzemeier, Bodo; Quici, Silvio; Knochel, Paul (May 2002). "Copper-catalysed aerobic oxidation of alcohols using fluorous biphasic catalysis". Tetrahedron. 58 (20): 3985–3991. doi:10.1016/S0040-4020(02)00250-8.
  22. Marko, I. E.; Giles, P. R.; Tsukazaki, M.; Brown, S. M.; Urch, C. J. (1996-12-20). "Copper-Catalyzed Oxidation of Alcohols to Aldehydes and Ketones: An Efficient, Aerobic Alternative". Science. 274 (5295): 2044–2046. Bibcode:1996Sci...274.2044M. doi:10.1126/science.274.5295.2044. ISSN   0036-8075. PMID   8953027.
  23. "hill | UW-Madison Department of Chemistry". www.chem.wisc.edu. Retrieved 2020-02-02.
  24. 1 2 Hoover, Jessica M.; Ryland, Bradford L.; Stahl, Shannon S. (2013-02-13). "Mechanism of Copper(I)/TEMPO-Catalyzed Aerobic Alcohol Oxidation". Journal of the American Chemical Society. 135 (6): 2357–2367. doi:10.1021/ja3117203. ISSN   0002-7863. PMC   3834274 . PMID   23317450.
  25. "Experiment 15: Aerobic Oxidation of an Alcohol Using a Cu/TEMPO Catalyst System | UW-Madison Department of Chemistry". www.chem.wisc.edu. Retrieved 2020-02-02.
  26. "Stahl Aerobic Oxidation TEMPO solution 796549". Sigma-Aldrich. Retrieved 2020-02-02.
  27. Steves, Janelle E.; Preger, Yuliya; Martinelli, Joseph R.; Welch, Christopher J.; Root, Thatcher W.; Hawkins, Joel M.; Stahl, Shannon S. (2015-07-15). "Process Development of CuI/ABNO/NMI-Catalyzed Aerobic Alcohol Oxidation". Organic Process Research & Development. 19 (11): 1548–1553. doi:10.1021/acs.oprd.5b00179. ISSN   1083-6160.
  28. "Stahl Aerobic Oxidation ABNO solution 796557". Sigma-Aldrich. Retrieved 2020-02-02.
  29. Shibuya, Masatoshi; Tomizawa, Masaki; Sasano, Yusuke; Iwabuchi, Yoshiharu (2009-06-19). "An Expeditious Entry to 9-Azabicyclo[3.3.1]nonane N -Oxyl (ABNO): Another Highly Active Organocatalyst for Oxidation of Alcohols". The Journal of Organic Chemistry. 74 (12): 4619–4622. doi:10.1021/jo900486w. ISSN   0022-3263. PMID   19476345.
  30. Song, Zhiguo J.; Zhou, Guoyue; Cohen, Ryan; Tan, Lushi (2018-09-21). "Preparation of ABNO on Scale and Analysis by Quantitative Paramagnetic NMR". Organic Process Research & Development. 22 (9): 1257–1261. doi:10.1021/acs.oprd.8b00191. ISSN   1083-6160. S2CID   105020689.
  31. 1 2 Zultanski, Susan L.; Zhao, Jingyi; Stahl, Shannon S. (2016-05-25). "Practical Synthesis of Amides via Copper/ABNO-Catalyzed Aerobic Oxidative Coupling of Alcohols and Amines". Journal of the American Chemical Society. 138 (20): 6416–6419. doi:10.1021/jacs.6b03931. ISSN   0002-7863. PMC   5273591 . PMID   27171973.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.