M-Terphenyl

Last updated
m-Terphenyl
Meta-terphenyl.png
Names
IUPAC name
1,3-diphenylbenzene
Other names
m-Terphenyl; 1,1'-Biphenyl, 3-phenyl-; 1,1':3',1''-Terphenyl; 1,3-Diphenylbenzene; 1,3-Terphenyl; AI3-00860; CCRIS 1656; EINECS 202-122-1; HSDB 2537; Isodiphenylbenzene; m-Diphenylbenzene; m-Triphenyl; NSC 6808; Santowax M; UNII-WOI2PSS0KX
Identifiers
3D model (JSmol)
ChEMBL
ChemSpider
ECHA InfoCard 100.001.930 OOjs UI icon edit-ltr-progressive.svg
EC Number
  • 202-122-1
PubChem CID
  • InChI=1S/C18H14/c1-3-8-15(9-4-1)17-12-7-13-18(14-17)16-10-5-2-6-11-16/h1-14H
    Key: YJTKZCDBKVTVBY-UHFFFAOYSA-N
  • C1=CC=C(C=C1)C2=CC(=CC=C2)C3=CC=CC=C3
Properties
C18H14
Molar mass 230.310 g·mol−1
Appearanceyellow needles
Density 1.23
Melting point 86–87 °C (187–189 °F; 359–360 K)
Boiling point 365
1.51 mg/l
Hazards
GHS labelling: [1]
GHS-pictogram-pollu.svg
Warning
H410
P273, P391, P501
Flash point 191 °C (376 °F; 464 K)
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).

m-Terphenyls (also known as meta-terphenyls, meta-diphenylbenzenes, or meta-triphenyls) are organic molecules composed of two phenyl groups bonded to a benzene ring in the one and three positions. [2] The simplest formula is C18H14, but many different substituents can be added to create a diverse class of molecules. [3] Due to the extensive pi-conjugated system, the molecule it has a range of optical properties and because of its size, it is used to control the sterics in reactions with metals and main group elements. [4] This is because of the disubstituted phenyl rings, which create a pocket for molecules and elements to bond without being connected to anything else. [5] It is a popular choice in ligand, and the most chosen amongst the terphenyls because of its benefits in regards to sterics. [6] Although many commercial methods exist to create m-terphenyl compounds, they can also be found naturally in plants such as mulberry trees. [7]

Contents

The basic structure of m-terphenyl with R representing the most common bonding site M-terphenyl.svg
The basic structure of m-terphenyl with R representing the most common bonding site

History

Discovery

The earliest known synthesis of meta-terphenyl was completed in 1866 by Pierre Eugène Marcellin Berthelot by heating benzene to high temperatures leading to a mixture of hydrocarbons including a mixture of meta-terphenyl and para-terphenyl. [2] Meta-terphenyl was isolated in 1874 by Guslav Schultz by taking the mixture of the compounds, mixing them in a solvent and allowing meta-terphenyl to melt off as it has a lower melting and boiling point than para-terphenyl. [5] Meta-terphenyl, and other aromatic compounds, remained of much interest to scientists in throughout the end of the 20th century, with many of the physical properties being measured and compared during this time. This also led to the first alternate form of meta-terphenyl synthesis, which involved passing gaseous benzene and toluene through a hot glass tube. [8]

Reactivity

By the 1930s, focus had shifted to experimenting with the reactivity of meta-terphenyl and its potential use as a ligand. The first verified modified version of meta-terphenyl was created in 1932 by Arthur Wardner and Alexander Lowy and led to the creation of nitro-substituted meta-terphenyls as well as amino-meta-terphenyls from the oxidation of the nitro-substituted compounds. [9] Walter and Kathryn Cook halogenated meta-terphenyl with chlorine and bromine with further applications such as use in as Grignard reaction, the first such suggestion for meta-terphenyl as a ligand for a main group element. [10] They later confirmed their results using the Stepanow Method. [11] This trend continued with C.K. Breadsher and I. Swerlick publishing a review of all known reactions that meta-terphenyl could undergo. [12] G. R. Ames also wrote an article detailing not only reactions of meta-terphenyls, but also covering all the different experimental methods to obtain meta-terphenyl known at the time. [13]

Early synthetic methods

During this time, the method of producing meta-terphenyl had remained the same. While people did experiment with other ways to obtain the compound, for the most part the method of heating benzene in a glass tube remained the primary method. In 1948, however, G. Woods and Irwin Tucker put forth an alternative method. Instead of heating benzene, they found that a combination of dihydroresocinol and two equivalents of phenyllithium would create unsymmetrical meta-terphenyl molecules. [14] This was significant as the previous method required the separation of meta-terphenyl from other compounds and this novel synthesis allowed meta-terphenyls to be the major product and much more easily isolatable. This method would remain the most popular form of making meta-terphenyls until the end of the 20th century.

Woods and Tucker mechanism for the creation of m-terphenyl. Woods-Tucker Method.svg
Woods and Tucker mechanism for the creation of m-terphenyl.

It was during this time that it was discovered that meta-terphenyls occurred in nature. In 1975, Karl-Werner Glombitza, Hans-Willi Rauwald, and Gert Eckhardt isolated two meta-terphenyls from the algae Fugus vesiculosus. [15] More naturally occurring meta-terphenyls have been isolated since then and have shown promising applications in the field of biochemistry. [7]

Synthesis

Hart Method

As the demand for meta-terphenyl and its derivatives grew through the latter half of the 20th century, it became necessary to increase the yield of reactions producing meta-terphenyls as well as have the ability to uniquely create symmetric and unsymmetric meta-terphenyls to investigate their reactivity as well utilize their increased steric control. Such a method was discovered by Akbar Saednya and Harold Hart in 1986. Using an excess of Grignard reagent that had a phenyl group attached, meta-terphenyl was able to be made quickly, in one step, with a relatively high yield. [3] This method also allowed for a variety of meta-terphenyl compounds to be made as so long as it could successfully be made into a Grignard reagent.

Saedyna and Hart's initial proposed mechanism for making m-terphenyl Saedyna-Hart Method.svg
Saedyna and Hart’s initial proposed mechanism for making m-terphenyl

This method continues to remain very popular in terms of the creation of symmetrical meta-terphenyl compounds, but that has not stopped attempts to quicken synthesis, increase yield, and create more sterically bulky m-terphenyls. The method developed by Saednya and Hart has provided the basis for improved synthesis of meta-terphenyls and has often been used as a comparison when it comes to resulting structures and methods. [16] Saednya and Hart continued their work and provided two alternate paths to create meta-terphenyls in 1996. [17] One involved using a halogenated benzene and three equivalents of the phenyl group attached to the benzene. The second involved a dichloro-substituted benzene and butyl lithium followed by two equivalents of the Grignard reagents mentioned above. This led to increased yields of larger terphenyl compounds, however as the size of the substituents has been hypothesized to have a limit due to the increased steric hinderance of the molecule.

Sadenya and Hart's second proposed process of making m-terphenyl. SH Second Method.svg
Sadenya and Hart’s second proposed process of making m-terphenyl.

New approaches

Novel synthesis methods have continued to be developed to this day. One such method involves using an ultrasound bath to make m-terphenyl compounds. By reacting anionic diphenyl molecules with functional ketones in a solution of potassium hydroxide and DMF in an ultrasound bath, a bulky meta-terphenyl molecule can be obtained. While this method does not have the highest yield, it is much quicker being able to be completed within an hour. [18] Additionally, meta-terphenyl synthesis has begun to become more focused. As opposed to general routes to produce common meta-terphenyl compounds, the shift has been to improve certain derivatives to accomplish particular goals. Examples of this include a method to produce a very sterically hindered meta-terphenyl with the purpose of forming phosphorus-phosphorus double bonds and a heavily fluorinated meta-terphenyl being produced to help stabilize silylium compounds. Additionally, reaction to add other bulky substituents to the center phenyl group has been shown to discourage rotation of the outer phenyl groups in hopes of stabilizing boron and silicon radicals and bonded complexes. [16] [19] [20]

Applications

Main group chemistry

Meta-terphenyls have a variety of uses in fields of chemistry. Their large size can help to sterically force a certain reaction to take place, however they are mainly used to stabilize compounds that would be unstable otherwise. [4] One such area of study is in main group chemistry. An example of this can be seen in the formation of heavier carbene analogues, where bulky meta-terphenyl ligands were able to provide enough steric protection to stabilize newly created bismuthenium and stibenium ions, the first reported carbene analogs that were not in Group 14. [21] Additionally, meta-terphenyl ligands were used to stabilize phosphorus-phosphorus double bonds. [22] This was proven multiple times with a variety of different meta-terphenyl compounds being used to confirm the result and led to the confirmation of the appropriate length of a phosphorus-phosphorus double bond.

m-Terphenyl ligands being used to stabilize a bismuth analogue of a carbene. Bismuthium ion.svg
m-Terphenyl ligands being used to stabilize a bismuth analogue of a carbene.

Organometallics

Another relevant field of study where meta-terphenyls have shown significant use is organometallics. One such application has been in the creation of paramagnetic organometallic compounds. Due to the steric hinderance provided by m-terphenyls, the creation of certain main group-metal aryl complexes has been made possible, which provide the opportunity to create species with a broad range of reactivity, including with small molecules such as ammonia, carbon dioxide, and oxygen. It has additionally helped in methyl-bridging bonds between transition metal centers. [23]

M-terphenyls have also been quite helpful in getting preliminary structures of divalent lithium and sodium, although both molecules had substantial stabilization from the electron-rich meta-terphenyl group. [24] M-terphenyls have also helped, along with the electronic support of sodium ions, to stabilize the first gallium-gallium triple bond, although this is contested due to the high coordination of the sodium atoms in the complex. [24] A similar approach meshing the methods to form a phosphorus-phosphorus double bonds and a gallium-gallium triple bond allowed researched to create and isolate the first germanium-germanium double bond. Meta-terphenyl continues to play an important part of organometallic chemistry, as well as main group chemistry, due to its kinetic stabilization of molecules and its thermodynamic influence on the energies between molecules. [24]

Example of m-terphenyl stabilizing an iron complex bonding though to methylene groups. Iron-Bridged Complex.svg
Example of m-terphenyl stabilizing an iron complex bonding though to methylene groups.

Biochemistry

Meta-terphenyl ligands can be used on their own in the field of biochemistry. Due to its composition and shape, meta-terphenyl can be used as the basis for the formation of synthetic proteins that can bind to carbohydrates, lectins. This is due to the large twisted shape of meta-terphenyl, when not hindered by bulkier substituents used in organometallics and main-group chemistry, which may opt to increase the rotational barrier of the molecule. In this way, synthetic receptors for sugars such as disaccharides can be bound temporarily before being used in further experiments. This process, while it continues to be developed, has many promising applications such as the prevention and treatment of bacterial infections. [25]

Transition metal chemistry

Another field that often uses meta- terphenyls is transition metal chemistry. They are most relevant in attaining low-coordinate metal centers. This is because their size makes it difficult for a lot of ligands to bond to a metal center. [26] This has shown to be quite useful in the area of reaction chemistry and they have shown to be quite helpful a number of catalysis reactions, such as those involving isocyanates. This has allowed for certain reactions to occur in a shorter amount of time and with generally mild conditions. [26]

Related Research Articles

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In organometallic chemistry, organolithium reagents are chemical compounds that contain carbon–lithium (C–Li) bonds. These reagents are important in organic synthesis, and are frequently used to transfer the organic group or the lithium atom to the substrates in synthetic steps, through nucleophilic addition or simple deprotonation. Organolithium reagents are used in industry as an initiator for anionic polymerization, which leads to the production of various elastomers. They have also been applied in asymmetric synthesis in the pharmaceutical industry. Due to the large difference in electronegativity between the carbon atom and the lithium atom, the C−Li bond is highly ionic. Owing to the polar nature of the C−Li bond, organolithium reagents are good nucleophiles and strong bases. For laboratory organic synthesis, many organolithium reagents are commercially available in solution form. These reagents are highly reactive, and are sometimes pyrophoric.

In chemistry, a hypervalent molecule is a molecule that contains one or more main group elements apparently bearing more than eight electrons in their valence shells. Phosphorus pentachloride, sulfur hexafluoride, chlorine trifluoride, the chlorite ion, and the triiodide ion are examples of hypervalent molecules.

<span class="mw-page-title-main">Steric effects</span> Geometric aspects of ions and molecules affecting their shape and reactivity

Steric effects arise from the spatial arrangement of atoms. When atoms come close together there is a rise in the energy of the molecule. Steric effects are nonbonding interactions that influence the shape (conformation) and reactivity of ions and molecules. Steric effects complement electronic effects, which dictate the shape and reactivity of molecules. Steric repulsive forces between overlapping electron clouds result in structured groupings of molecules stabilized by the way that opposites attract and like charges repel.

<span class="mw-page-title-main">Quintuple bond</span>

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<span class="mw-page-title-main">Bite angle</span>

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

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Bismuthinidenes are a class of organobismuth compounds, analogous to carbenes. These compounds have the general form R-Bi, with two lone pairs of electrons on the central bismuth(I) atom. Due to the unusually low valency and oxidation state of +1, most bismuthinidenes are reactive and unstable, though in recent decades, both transition metals and polydentate chelating Lewis base ligands have been employed to stabilize the low-valent bismuth(I) center through steric protection and π donation either in solution or in crystal structures. Lewis base-stabilized bismuthinidenes adopt a singlet ground state with an inert lone pair of electrons in the 6s orbital. A second lone pair in a 6p orbital and a single empty 6p orbital make Lewis base-stabilized bismuthinidenes ambiphilic.

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References

  1. "M-Terphenyl". pubchem.ncbi.nlm.nih.gov.
  2. 1 2 Chattaway, Frederick; Evans, R (1896). "LXII. The Diphenylbenzenes. I. Metaphenylbenzene". Journal of the Chemical Society, Transactions. 69: 980–985. doi:10.1039/CT8966900980.
  3. 1 2 Du, Chi Jen Frank; Hart, Harold; Ng, Kwok Keung Daniel (1986). "A one-pot synthesis of m-terphenyls, via a two-aryne sequence". The Journal of Organic Chemistry. 51 (16): 3162–3165. doi:10.1021/jo00366a016. ISSN   0022-3263.
  4. 1 2 Adrio, Luis A.; Míguez, José M. Antelo; Hii, King Kuok (Mimi) (2009-09-24). "Synthesis of Terphenyls". Organic Preparations and Procedures International. 41 (5): 331–358. doi:10.1080/00304940903163632. ISSN   0030-4948. S2CID   98582754.
  5. 1 2 Schultz, Guslav (1874). "Ueber Diphenyl". Justus Liebig's Annalen der Chemie (in German). 174 (2): 201–235. doi:10.1002/jlac.18741740206.
  6. Rivard, Eric; Power, Philip P. (2007-11-01). "Multiple Bonding in Heavier Element Compounds Stabilized by Bulky Terphenyl Ligands". Inorganic Chemistry. 46 (24): 10047–10064. doi:10.1021/ic700813h. ISSN   0020-1669. PMID   17975890.
  7. 1 2 Liu, Ji-Kai (2006-06-01). "Natural Terphenyls: Developments since 1877". Chemical Reviews. 106 (6): 2209–2223. doi:10.1021/cr050248c. ISSN   0009-2665. PMID   16771447.
  8. Carnelley, Thos (1880-01-01). "LXV.—Action of heat on the mixed vapours of benzene and toluene. Two new methylene-diphenylenes". Journal of the Chemical Society, Transactions. 37: 701–720. doi:10.1039/CT8803700701. ISSN   0368-1645.
  9. Wardner, C. Arthur; Lowy, Alexander (1932). "Nitration of Meta-Diphenylbenzene and Derivatives of Nitro-Meta-Diphenylbenzene1". Journal of the American Chemical Society. 54 (6): 2510–2515. doi:10.1021/ja01345a051. ISSN   0002-7863.
  10. Cook, Walter A.; Cook, Kathryn Hartkoff (1933). "The Halogenation of Meta-Diphenylbenzene. I. The Monochloro and Monobromo Derivatives". Journal of the American Chemical Society. 55 (3): 1212–1217. doi:10.1021/ja01330a059. ISSN   0002-7863.
  11. Cook, Walter A.; Cook, Kathryn Hartkoff (1933-05-01). "Determination of Nuclear Halogens in Organic Compounds". Industrial & Engineering Chemistry Analytical Edition. 5 (3): 186–188. doi:10.1021/ac50083a016. ISSN   0096-4484.
  12. Bradsher, C. K.; Swerlick, I. (1950). "Reactions in the m-Terphenyl Series1". Journal of the American Chemical Society. 72 (9): 4189–4192. doi:10.1021/ja01165a100. ISSN   0002-7863.
  13. Ames, G. R. (1958). "The Synthesis of Substituted Terphenyls". Chemical Reviews. 58 (5): 895–923. doi:10.1021/cr50023a004. ISSN   0009-2665.
  14. Woods, G. Forrest; Tucker, Irwin W. (1948). "Synthesis of m-Diarylbenzenes". Journal of the American Chemical Society. 70 (10): 3340–3342. doi:10.1021/ja01190a035. ISSN   0002-7863. PMID   18891854.
  15. Glombitza, Karl-Werner; Rauwald, Hans-Willi; Eckhardt, Gert (1975-06-01). "Fucole, polyhydroxyoligophenyle aus Fucus vesiculosus". Phytochemistry (in German). 14 (5): 1403–1405. doi:10.1016/S0031-9422(00)98637-0. ISSN   0031-9422.
  16. 1 2 Olaru, Marian; Beckmann, Jens; Raţ, Ciprian I. (2014-06-23). "Polyfluorinated Functionalized m -Terphenyls. New Substituents and Ligands in Organometallic Synthesis". Organometallics. 33 (12): 3012–3020. doi:10.1021/om500244y. ISSN   0276-7333.
  17. SAEDNYA, A.; HART, H. (2010-08-03). "ChemInform Abstract: Two Efficient Routes to m-Terphenyls from 1,3-Dichlorobenzenes". ChemInform. 28 (22): no. doi:10.1002/chin.199722096. ISSN   0931-7597.
  18. Shetgaonkar, Samata E.; Singh, Fateh V. (2019-04-18). "Ultrasound-assisted one pot synthesis of polysubstituted meta-terphenyls using ring transformation strategy". Synthetic Communications. 49 (8): 1092–1102. doi:10.1080/00397911.2019.1591454. ISSN   0039-7911. S2CID   109167395.
  19. Smith, Rhett; Ren, Tong; Protasiewicz, John; John, A. (2002). "A Robust, Reactive, and Remarkably Simple to Prepare Sterically Encumbered meta-Terphenyl Ligand". European Journal of Inorganic Chemistry. 2002 (11): 2779–2783. doi:10.1002/1099-0682(200211)2002:11<2779::AID-EJIC2779>3.0.CO;2-Q.
  20. Stanciu, Corneliu; Richards, Anne F.; Fettinger, James C.; Brynda, Marcin; Power, Philip P. (2006-05-15). "Synthesis and characterization of new, modified terphenyl ligands: Increasing the rotational barrier for flanking rings". Journal of Organometallic Chemistry. 691 (11): 2540–2545. doi:10.1016/j.jorganchem.2006.01.046. ISSN   0022-328X.
  21. Olaru, Marian; Duvinage, Daniel; Lork, Enno; Mebs, Stefan (2018). "Heavy Carbene Analogues: Donor-Free Bismuthenium and Stibenium Ions". Angewandte Chemie. 57 (32): 10080–10084. doi:10.1002/anie.201803160. PMID   29644767.
  22. Protasiewicz, John D.; Washington, Marlena P.; Gudimetla, Vittal B.; Payton, John L.; Cather Simpson, M. (2010-12-15). "A closer look at the phosphorus–phosphorus double bond lengths in meta-terphenyl substituted diphosphenes". Inorganica Chimica Acta. Special Volume: Dedication to Professor Rheingold. 364 (1): 39–45. doi:10.1016/j.ica.2010.07.018. ISSN   0020-1693.
  23. Ni, Chengbao; Power, Philip P. (2009-11-23). "Methyl-Bridged Transition Metal Complexes (M = Cr−Fe) Supported by Bulky Terphenyl Ligands". Organometallics. 28 (22): 6541–6545. doi:10.1021/om900724p. ISSN   0276-7333.
  24. 1 2 3 Clyburne, Jason A. C; McMullen, Nichole (2000-12-01). "Unusual structures of main group organometallic compounds containing m-terphenyl ligands". Coordination Chemistry Reviews. 210 (1): 73–99. doi:10.1016/S0010-8545(00)00317-9. ISSN   0010-8545.
  25. Mazik, Monika (2008-05-05). "Design of Lectin Mimetics". ChemBioChem. 9 (7): 1015–1017. doi:10.1002/cbic.200800038. ISSN   1439-4227. PMID   18366054. S2CID   11426160.
  26. 1 2 Sharpe, Helen R.; Geer, Ana M.; Williams, Huw E. L.; Blundell, Toby J.; Lewis, William; Blake, Alexander J.; Kays, Deborah L. (2017-01-10). "Cyclotrimerisation of isocyanates catalysed by low-coordinate Mn(II) and Fe(II) m-terphenyl complexes". Chemical Communications. 53 (5): 937–940. doi:10.1039/C6CC07243G. ISSN   1364-548X. PMID   28008435.
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