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Organoberyllium chemistry

April 15, 2024

Organoberyllium chemistry involves the synthesis and properties of organometallic compounds featuring the group 2 alkaline earth metal beryllium (Be). The area remains understudied, relative to the chemistry of other main-group elements, because although metallic beryllium is relatively unreactive, its dust causes berylliosis and compounds are toxic.[1] Organoberyllium compounds are typically prepared by transmetallation or alkylation of beryllium chloride.[2]

Crystal structure of a BePh2 compound.

The beryllium functional group in organoberyllium compounds usually serves to coordinate other elements and ligands. Beryllium, one of the smallest atoms on the periodic table, almost always exhibits a +2 oxidation state.[3] The Be2+ cation is characterized by the highest known charge density (Z/r = 6.45), making it one of the hardest cations and a very strong Lewis acid.[4]

Coordination in beryllium can range from a coordination number of two to four.[5] Most common ligands attached to beryllium are halides, hydride (like beryllium borohydride in a three-center two-electron bond), methyl, aryl, and alkyl. Beryllium can form complexes with known organic compounds such as phosphines, N-hetereocyclic carbenes (NHC), cyclic alkyl amino carbenes (CAAC), and β-diketiminates (NacNac).

General characteristics edit

Organoberyllium chemistry is limited to academic research due to the cost and toxicity of beryllium.

Organoberyllium compounds consist of a beryllium atom with an organic group attached. There are very few reported case of Be(I) and Be(0) oxidation states.[6][7][8] Instead, Be has a +2 oxidation state, and higher charge density than any other group 2 element. Organometallic beryllium compounds are highly reactive strong acids. Beryllium has a high electronegativity compare to other group 2 elements; thus the resulting C-Be bonds are less highly polarized than other C-MII bonds,[9] although the attached carbon still bears a negative dipole moment.

Lighter organoberyllium compounds are often considered covalent, but with some ionic bond characteristics. From this perspective, the C-Be bonds are much more ionic and highly polarized than other C-R bonds. This higher ionic character and bond polarization tends to produce high coordination numbers. Many compounds, particularly dialklys, are polymeric in solid or liquid states with highly complex structures in solution; in the gaseous state, they often revert to monomers. A good example is beryllium borohydride, which dimerizes to form three-center two-electron bonds.

 
Beryllium borohydride compound that creates a three center two electron bond.

Compounds such as these hydrides can coordinate with carbenes such as N-heterocyclic carbene to form crystals. The propensity for co-crystallization suggests applications in organocatalysis.

Compounds edit

Beryllium can form a variety of organoberyllium compounds, including ring structures, alkyls, alkynyls,[10] hydrides,[11][12] methyls, halides, phosphines, carbenes, and nitrogen-based coordination such as NacNac.

Dimethylberyllium has the same crystal structure as dimethylmagnesium[13] and can be used to synthesize beryllium azide and beryllium hydride.

Ring structure edit

Organoberyllium structures can consist of an aryl,[14] dineopentylberyllium,[14] beryllocene,[15][16][17] phenyl,[18] or terphenyl.[19]

Halides edit

Beryllium halides are formed by a combination of halogen with a beryllium atom. Beryllium halides are mostly covalent in nature except for the fluoride which is more ionic. They can be used as Lewis acid catalysts. Preparation for these compounds varies by the halogen. Beryllium halides are among the most common starting points to form complexes with other types of ligand.[20][2] Halides can donate 2 electrons into the beryllium center with a charge of −1.

Phosphines edit

Organoberyllium phosphines are another class of compounds that is used in synthesis.[21] Phosphine donates two electrons into the beryllium center. Phosphines are L-type ligands. Unlike most metal ammine complexes, metal phosphine complexes tend to be lipophilic, displaying good solubility in organic solvents. Phosphine ligands are also π-acceptors. Their π-acidity arises from overlap of P-C σ* anti-bonding orbitals with filled metal orbitals. Beryllium can coordinate with a phosphine due to its good π-acceptor ability, which is used extensively in beryllium chemistry literature. An organoberyllium phosphine can be prepared through coordination with a beryllium halide to form a four-coordinate tetrahedral compound.

 
Phosphine type coordination with a Be Halide Complex

Carbenes edit

An organoberyllium carbene consists of a carbene attached to beryllium. The types of carbene includes a N-heterocyclic carbenes (NHC) and cyclic alkyl amino carbenes (CAAC).

N-Hetereocyclic carbenes edit

Beryllium can coordinate with an N-hetereocyclic carbene (NHC).[22][23][24] NHCs are defined as heterocyclic species containing a carbene carbon and at least one nitrogen atom within the ring structure.[21] NHCs have found numerous applications in some of the most important catalytic transformations in chemical industry, but their reactivity in coordinating with main group elements especially with beryllium’s potential as a reactive organocatalyst has opened new areas of research.[25]

 
Coordination with a NHC ligand to a Be complex with R not limited to halogen, hydride, phosphine, aryl, alkyl etc.

Cyclic alkyl amino carbenes (CAAC) edit

Beryllium can coordinate with cyclic alkyl amino carbene (CAAC) ligands and can form beryllium radicals which can be present with beryllium complexes (BeR2). A CAAC ligand coordinates a 2 electron -1 charge into the beryllium center.[26] CAAC has an "amino" substituent and an "alkyl" sp3 carbon atom. CAACs are very good σ donors (higher HOMO) and π acceptors (lower LUMO) compared to NHCs. In addition, the lower heteroatom stability of the carbene center in CAAC compared to NHC results in a lower ΔE.

 
Coordination of a CAAC ligand to a Be complex with R not limited for coordination with Be

β-Diketiminates (NacNac) edit

β-Diketiminates (BDI, also known as NacNac), are a commonly used class of supporting ligands that have been successfully adopted to stabilize an extensive range of metal ions from the s, p, d, and f-blocks in multiple oxidation states.[27] The popularity of these monoanionic N-donor ligands can be explained by their convenient access and high stereoelectronic coordination. This enables the separation of highly reactive coordinatively unsaturated complexes. Moreover, studies have demonstrated the utility of this class of ligands for designing active catalysts for various transformations. So, because of that, beryllium can properly coordinate with β-diketiminate compounds due to the high reactivity and stereo electronic coordination with the beryllium thus a Be NacNac compound is also common in organoberyllium chemistry.

 
Example of a NacNac ligand coordination to a beryllium compound with L varies towards the reaction and number of equivalents.

Synthesis edit

Synthesis of organoberyllium compounds is limited but literature have shown that beryllium can react with halides, alkyls, alloxides and other organic compounds. Alkylation of beryllium halide is one of the most widely-used method in beryllium chemistry.[28]

Transmetallation edit

A transmetallation involves a ligand transfer to one another such as this:

MR2 + Be → BeR2 + M

M is not limited to any main group and/or transition metal. R can be limited to almost any phosphine, aryl, alkyl, halogen, hydrogen and/or carbene.

In this case organoberyllium can form reactions such as:

 
A synthesis of a BePh2, which forms a crystal structure from this reaction.

Alkylation edit

 
This structure shows a Cp2Be. The solid-state structure suggests that the two rings are bound to the beryllium differently such that one is designated η5 and the other η1

Alkylation of beryllium halide is another common method to react to make an organoberyllium compound such as this:

2 MR1 + BeR22 → BeR12 + 2 MR22

M is not limited to any main group and/or transition metal. R1 is not limited to phenyl, methyl, methyl oxide, carbene etc. R2 can be any halide such as fluoride, bromide, iodide, or chloride.

An example of such reaction is the synthesis of bis(cyclopentadienyl)beryllium (Cp2Be) or beryllocene from BeCl2 and potassium cyclopentadienide:

2 K[Cp] + BeCl2 → [Cp]2Be + 2 KCl

Low oxidation beryllium chemistry edit

While Be(II) is one of the more common oxidation states, there is also further research on a Be(I) and Be(0) complex. Low-valent main group compounds have recently become desirable synthetic targets due to their interesting reactivity comparable to transition metal complexes. In one work, stabilized cyclic (alkyl)(amino)carbene ligands were used to isolate and characterize the first neutral compounds containing beryllium, with the Be(0) compound stabilized by a strongly σ-donating and π-accepting cyclic CAAC ligand.[29]

 
This reaction is shown when a CAAC ligand is coordinated with a BeCl2 and using KC8 to form a zero oxidation beryllium complex. This work was done by Prof Braunschweig to create the first neutral Be complex the R group includes Me and (CH2)5 and Dipp is otherwise known as 2,6-diisopropylphenyl.

Be(I) is another example of a rare phenomenon and few publications were reported, but one example of a Be(I) was a CAAC ligand already coordinated with Be. Gilliard and his group created a more stable beryllium radical cation.[6] Because of well-established challenges concerning the reduction of Be(II) to Be(I), they pursued the radical via an oxidation strategy using TEMPO ((2,2,6,6-Tetramethylpiperidin-1-yl) oxyl). This reaction resulted in a Be(I) compound just by stabilizing the Be radical.

 
Reaction shown is radical cation reaction from a Be(II) CAAC compound to a Be(I) CAAC compound.

See also edit

References edit

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  19. ^ Paparo, Albert; Jones, Cameron (2019-02-01). "Beryllium Halide Complexes Incorporating Neutral or Anionic Ligands: Potential Precursors for Beryllium Chemistry". Chemistry: An Asian Journal. 14 (3): 486–490. doi:10.1002/asia.201801800. ISSN 1861-4728. PMID 30604490. S2CID 58632466.
  20. ^ Gilman, Henry; Schulze, F. (1927-11-01). "Organoberyllium halides". Journal of the American Chemical Society. 49 (11): 2904–2908. doi:10.1021/ja01410a043. ISSN 0002-7863.
  21. ^ a b Buchner, Magnus R.; Müller, Matthias; Rudel, Stefan S. (2017-01-19). "Beryllium Phosphine Complexes: Synthesis, Properties, and Reactivity of (PMe 3 ) 2 BeCl 2 and (Ph 2 PC 3 H 6 PPh 2 )BeCl 2". Angewandte Chemie International Edition. 56 (4): 1130–1134. doi:10.1002/anie.201610956. PMID 28004465.
  22. ^ Paparo, Albert; Best, Stephen P.; Yuvaraj, K.; Jones, Cameron (2020-12-14). "Neutral, Anionic, and Paramagnetic 1,3,2-Diazaberyllacyles Derived from Reduced 1,4-Diazabutadienes". Organometallics. 39 (23): 4208–4213. doi:10.1021/acs.organomet.0c00017. ISSN 0276-7333. S2CID 213828903.
  23. ^ Gilliard, Robert J.; Abraham, Mariham Y.; Wang, Yuzhong; Wei, Pingrong; Xie, Yaoming; Quillian, Brandon; Schaefer, Henry F.; Schleyer, Paul v. R.; Robinson, Gregory H. (2012-06-20). "Carbene-Stabilized Beryllium Borohydride". Journal of the American Chemical Society. 134 (24): 9953–9955. doi:10.1021/ja304514f. ISSN 0002-7863. PMID 22670857.
  24. ^ Paparo, Albert; Jones, Cameron (2019-01-03). "Beryllium Halide Complexes Incorporating Neutral or Anionic Ligands: Potential Precursors for Beryllium Chemistry". Chemistry: An Asian Journal. 14 (3): 486–490. doi:10.1002/asia.201801800. ISSN 1861-4728. PMID 30604490. S2CID 58632466.
  25. ^ Hopkinson, Matthew N.; Richter, Christian; Schedler, Michael; Glorius, Frank (2014-06-25). "An overview of N-heterocyclic carbenes". Nature. 510 (7506): 485–496. Bibcode:2014Natur.510..485H. doi:10.1038/nature13384. ISSN 1476-4687. PMID 24965649. S2CID 672379.
  26. ^ Schuster, Julia K.; Roy, Dipak Kumar; Lenczyk, Carsten; Mies, Jan; Braunschweig, Holger (2019-02-18). "New Outcomes of Beryllium Chemistry: Lewis Base Adducts for Salt Elimination Reactions". Inorganic Chemistry. 58 (4): 2652–2658. doi:10.1021/acs.inorgchem.8b03263. ISSN 0020-1669. PMID 30707568. S2CID 73424673.
  27. ^ Camp, Clément; Arnold, John (2016-09-20). "On the non-innocence of "Nacnacs": ligand-based reactivity in β-diketiminate supported coordination compounds". Dalton Transactions. 45 (37): 14462–14498. doi:10.1039/C6DT02013E. ISSN 1477-9234. PMID 27353604.
  28. ^ Coates, G. E.; Morgan, G. L. (1971-01-01), Stone, F. G. A.; West, Robert (eds.), Organoberyllium Compounds, Advances in Organometallic Chemistry, vol. 9, Academic Press, pp. 195–257, doi:10.1016/S0065-3055(08)60052-0, ISBN 9780120311095, retrieved 2022-11-08
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April 15, 2024
organoberyllium, chemistry, involves, synthesis, properties, organometallic, compounds, featuring, group, alkaline, earth, metal, beryllium, area, remains, understudied, relative, chemistry, other, main, group, elements, because, although, metallic, beryllium,. Organoberyllium chemistry involves the synthesis and properties of organometallic compounds featuring the group 2 alkaline earth metal beryllium Be The area remains understudied relative to the chemistry of other main group elements because although metallic beryllium is relatively unreactive its dust causes berylliosis and compounds are toxic 1 Organoberyllium compounds are typically prepared by transmetallation or alkylation of beryllium chloride 2 Crystal structure of a BePh2 compound The beryllium functional group in organoberyllium compounds usually serves to coordinate other elements and ligands Beryllium one of the smallest atoms on the periodic table almost always exhibits a 2 oxidation state 3 The Be2 cation is characterized by the highest known charge density Z r 6 45 making it one of the hardest cations and a very strong Lewis acid 4 Coordination in beryllium can range from a coordination number of two to four 5 Most common ligands attached to beryllium are halides hydride like beryllium borohydride in a three center two electron bond methyl aryl and alkyl Beryllium can form complexes with known organic compounds such as phosphines N hetereocyclic carbenes NHC cyclic alkyl amino carbenes CAAC and b diketiminates NacNac Contents 1 General characteristics 2 Compounds 2 1 Ring structure 2 2 Halides 2 3 Phosphines 2 4 Carbenes 2 4 1 N Hetereocyclic carbenes 2 4 2 Cyclic alkyl amino carbenes CAAC 2 5 b Diketiminates NacNac 3 Synthesis 3 1 Transmetallation 3 2 Alkylation 4 Low oxidation beryllium chemistry 5 See also 6 ReferencesGeneral characteristics editOrganoberyllium chemistry is limited to academic research due to the cost and toxicity of beryllium Organoberyllium compounds consist of a beryllium atom with an organic group attached There are very few reported case of Be I and Be 0 oxidation states 6 7 8 Instead Be has a 2 oxidation state and higher charge density than any other group 2 element Organometallic beryllium compounds are highly reactive strong acids Beryllium has a high electronegativity compare to other group 2 elements thus the resulting C Be bonds are less highly polarized than other C MII bonds 9 although the attached carbon still bears a negative dipole moment Lighter organoberyllium compounds are often considered covalent but with some ionic bond characteristics From this perspective the C Be bonds are much more ionic and highly polarized than other C R bonds This higher ionic character and bond polarization tends to produce high coordination numbers Many compounds particularly dialklys are polymeric in solid or liquid states with highly complex structures in solution in the gaseous state they often revert to monomers A good example is beryllium borohydride which dimerizes to form three center two electron bonds nbsp Beryllium borohydride compound that creates a three center two electron bond Compounds such as these hydrides can coordinate with carbenes such as N heterocyclic carbene to form crystals The propensity for co crystallization suggests applications in organocatalysis Compounds editBeryllium can form a variety of organoberyllium compounds including ring structures alkyls alkynyls 10 hydrides 11 12 methyls halides phosphines carbenes and nitrogen based coordination such as NacNac Dimethylberyllium has the same crystal structure as dimethylmagnesium 13 and can be used to synthesize beryllium azide and beryllium hydride Ring structure edit Organoberyllium structures can consist of an aryl 14 dineopentylberyllium 14 beryllocene 15 16 17 phenyl 18 or terphenyl 19 Halides edit Beryllium halides are formed by a combination of halogen with a beryllium atom Beryllium halides are mostly covalent in nature except for the fluoride which is more ionic They can be used as Lewis acid catalysts Preparation for these compounds varies by the halogen Beryllium halides are among the most common starting points to form complexes with other types of ligand 20 2 Halides can donate 2 electrons into the beryllium center with a charge of 1 Phosphines edit Organoberyllium phosphines are another class of compounds that is used in synthesis 21 Phosphine donates two electrons into the beryllium center Phosphines are L type ligands Unlike most metal ammine complexes metal phosphine complexes tend to be lipophilic displaying good solubility in organic solvents Phosphine ligands are also p acceptors Their p acidity arises from overlap of P C s anti bonding orbitals with filled metal orbitals Beryllium can coordinate with a phosphine due to its good p acceptor ability which is used extensively in beryllium chemistry literature An organoberyllium phosphine can be prepared through coordination with a beryllium halide to form a four coordinate tetrahedral compound nbsp Phosphine type coordination with a Be Halide ComplexCarbenes edit An organoberyllium carbene consists of a carbene attached to beryllium The types of carbene includes a N heterocyclic carbenes NHC and cyclic alkyl amino carbenes CAAC N Hetereocyclic carbenes edit Beryllium can coordinate with an N hetereocyclic carbene NHC 22 23 24 NHCs are defined as heterocyclic species containing a carbene carbon and at least one nitrogen atom within the ring structure 21 NHCs have found numerous applications in some of the most important catalytic transformations in chemical industry but their reactivity in coordinating with main group elements especially with beryllium s potential as a reactive organocatalyst has opened new areas of research 25 nbsp Coordination with a NHC ligand to a Be complex with R not limited to halogen hydride phosphine aryl alkyl etc Cyclic alkyl amino carbenes CAAC edit Beryllium can coordinate with cyclic alkyl amino carbene CAAC ligands and can form beryllium radicals which can be present with beryllium complexes BeR2 A CAAC ligand coordinates a 2 electron 1 charge into the beryllium center 26 CAAC has an amino substituent and an alkyl sp3 carbon atom CAACs are very good s donors higher HOMO and p acceptors lower LUMO compared to NHCs In addition the lower heteroatom stability of the carbene center in CAAC compared to NHC results in a lower DE nbsp Coordination of a CAAC ligand to a Be complex with R not limited for coordination with Beb Diketiminates NacNac edit b Diketiminates BDI also known as NacNac are a commonly used class of supporting ligands that have been successfully adopted to stabilize an extensive range of metal ions from the s p d and f blocks in multiple oxidation states 27 The popularity of these monoanionic N donor ligands can be explained by their convenient access and high stereoelectronic coordination This enables the separation of highly reactive coordinatively unsaturated complexes Moreover studies have demonstrated the utility of this class of ligands for designing active catalysts for various transformations So because of that beryllium can properly coordinate with b diketiminate compounds due to the high reactivity and stereo electronic coordination with the beryllium thus a Be NacNac compound is also common in organoberyllium chemistry nbsp Example of a NacNac ligand coordination to a beryllium compound with L varies towards the reaction and number of equivalents Synthesis editSynthesis of organoberyllium compounds is limited but literature have shown that beryllium can react with halides alkyls alloxides and other organic compounds Alkylation of beryllium halide is one of the most widely used method in beryllium chemistry 28 Transmetallation edit A transmetallation involves a ligand transfer to one another such as this MR2 Be BeR2 MM is not limited to any main group and or transition metal R can be limited to almost any phosphine aryl alkyl halogen hydrogen and or carbene In this case organoberyllium can form reactions such as nbsp A synthesis of a BePh2 which forms a crystal structure from this reaction Alkylation edit nbsp This structure shows a Cp2Be The solid state structure suggests that the two rings are bound to the beryllium differently such that one is designated h5 and the other h1Alkylation of beryllium halide is another common method to react to make an organoberyllium compound such as this 2 MR1 BeR22 BeR12 2 MR22M is not limited to any main group and or transition metal R1 is not limited to phenyl methyl methyl oxide carbene etc R2 can be any halide such as fluoride bromide iodide or chloride An example of such reaction is the synthesis of bis cyclopentadienyl beryllium Cp2Be or beryllocene from BeCl2 and potassium cyclopentadienide 2 K Cp BeCl2 Cp 2Be 2 KClLow oxidation beryllium chemistry editWhile Be II is one of the more common oxidation states there is also further research on a Be I and Be 0 complex Low valent main group compounds have recently become desirable synthetic targets due to their interesting reactivity comparable to transition metal complexes In one work stabilized cyclic alkyl amino carbene ligands were used to isolate and characterize the first neutral compounds containing beryllium with the Be 0 compound stabilized by a strongly s donating and p accepting cyclic CAAC ligand 29 nbsp This reaction is shown when a CAAC ligand is coordinated with a BeCl2 and using KC8 to form a zero oxidation beryllium complex This work was done by Prof Braunschweig to create the first neutral Be complex the R group includes Me and CH2 5 and Dipp is otherwise known as 2 6 diisopropylphenyl Be I is another example of a rare phenomenon and few publications were reported but one example of a Be I was a CAAC ligand already coordinated with Be Gilliard and his group created a more stable beryllium radical cation 6 Because of well established challenges concerning the reduction of Be II to Be I they pursued the radical via an oxidation strategy using TEMPO 2 2 6 6 Tetramethylpiperidin 1 yl oxyl This reaction resulted in a Be I compound just by stabilizing the Be radical nbsp Reaction shown is radical cation reaction from a Be II CAAC compound to a Be I CAAC compound See also editGroup 2 organometallic chemistry BerylliumReferences edit Gad S C 2014 01 01 Beryllium in Wexler Philip ed Encyclopedia of Toxicology Third Edition Oxford Academic Press pp 435 437 ISBN 978 0 12 386455 0 retrieved 2022 10 27 a b Naglav Dominik Buchner Magnus R Bendt Georg Kraus Florian Schulz Stephan 2016 08 26 Off the Beaten Track A Hitchhiker s Guide to Beryllium Chemistry Angewandte Chemie International Edition 55 36 10562 10576 doi 10 1002 anie 201601809 PMID 27364901 Montero Campillo M Merced Mo Otilia Yanez Manuel Alkorta Ibon Elguero Jose 2019 01 01 van Eldik Rudi Puchta Ralph eds Chapter Three The beryllium bond Advances in Inorganic Chemistry Computational Chemistry vol 73 Academic Press pp 73 121 doi 10 1016 bs adioch 2018 10 003 S2CID 140062833 retrieved 2022 10 27 Buchner M R 2017 01 01 Beryllium Chemistry Reference Module in Chemistry Molecular Sciences and Chemical Engineering Elsevier ISBN 978 0 12 409547 2 retrieved 2022 10 27 Nembenna Sharanappa Sarkar Nabin Sahoo Rajata Kumar Mukhopadhyay Sayantan 2022 01 01 Parkin Gerard Meyer Karsten O hare Dermot eds 2 03 Organometallic Complexes of the Alkaline Earth Metals Comprehensive Organometallic Chemistry IV Oxford Elsevier pp 71 241 ISBN 978 0 323 91350 8 retrieved 2022 10 27 a b Wang Guocang Walley Jacob E Dickie Diane A Pan Sudip Frenking Gernot Gilliard Robert J 2020 03 11 A Stable Crystalline Beryllium Radical Cation Journal of the American Chemical Society 142 10 4560 4564 doi 10 1021 jacs 9b13777 ISSN 0002 7863 PMID 32088963 S2CID 211262005 Czernetzki Corinna Arrowsmith Merle Fantuzzi Felipe Gartner Annalena Troster Tobias Krummenacher Ivo Schorr Fabian Braunschweig Holger 2021 09 13 A Neutral Beryllium I Radical Angewandte Chemie International Edition 60 38 20776 20780 doi 10 1002 anie 202108405 ISSN 1433 7851 PMC 8518760 PMID 34263524 Wang Guocang Freeman Lucas A Dickie Diane A Mokrai Reka Benko Zoltan Gilliard Robert J 2019 03 21 Isolation of Cyclic Alkyl Amino Carbene Bismuthinidene Mediated by a Beryllium 0 Complex Chemistry A European Journal 25 17 4335 4339 doi 10 1002 chem 201900458 ISSN 0947 6539 PMC 6593863 PMID 30706565 Montero Campillo M Merced Mo Otilia Yanez Manuel Alkorta Ibon Elguero Jose 2019 01 01 van Eldik Rudi Puchta Ralph eds Chapter Three The beryllium bond Advances in Inorganic Chemistry Computational Chemistry vol 73 Academic Press pp 73 121 doi 10 1016 bs adioch 2018 10 003 S2CID 140062833 retrieved 2022 10 26 Morosin B Howatson J 1971 05 16 The crystal structure of dimeric methyl 1 propynyl beryllium trimethylamine Journal of Organometallic Chemistry 29 1 7 14 doi 10 1016 S0022 328X 00 87485 9 ISSN 0022 328X Beryllium Hydride an overview ScienceDirect Topics www sciencedirect com Retrieved 2022 11 08 Arrowsmith Merle Hill Michael S Kociok Kohn Gabriele 2015 02 09 Activation of N Heterocyclic Carbenes by BeH 2 and Be H Me Fragments Organometallics 34 3 653 662 doi 10 1021 om501314g ISSN 0276 7333 S2CID 96288623 Snow A I Rundle R E 1951 07 02 The structure of dimethylberyllium Acta Crystallographica 4 4 348 352 doi 10 1107 S0365110X51001100 hdl 2027 mdp 39015095081207 ISSN 0365 110X a b Ruhlandt Senge Karin Bartlett Ruth A Olmstead Marilyn M Power Philip P 1993 04 01 Synthesis and structural characterization of the beryllium compounds Be 2 4 6 Me3C6H2 2 OEt2 Be O 2 4 6 tert Bu3C6H2 2 OEt2 and Be S 2 4 6 tert Bu3C6H2 2 THF cntdot PhMe and determination of the structure of BeCl2 OEt2 2 Inorganic Chemistry 32 9 1724 1728 doi 10 1021 ic00061a031 ISSN 0020 1669 Fischer Ernst Otto Hofmann Hermann P 1959 02 01 Uber Aromatenkomplexe von Metallen XXV Di cyclopentadienyl beryllium Chemische Berichte 92 2 482 486 doi 10 1002 cber 19590920233 ISSN 0009 2940 Almenningen Arne Haaland Arne Lusztyk Janusz 1979 05 08 The molecular structure of beryllocene C5H5 2Be A reinvestigation by gas phase electron diffraction Journal of Organometallic Chemistry 170 3 271 284 doi 10 1016 S0022 328X 00 92065 5 ISSN 0022 328X Wong C H Lee T Y Chao K J Lee S 1972 06 15 Crystal structure of bis cyclopentadienyl beryllium at 120 C Acta Crystallographica Section B Structural Crystallography and Crystal Chemistry 28 6 1662 1665 doi 10 1107 S0567740872004820 ISSN 0567 7408 Muller Matthias Buchner Magnus R 2020 08 06 Diphenylberyllium Reinvestigated Structure Properties and Reactivity of BePh2 12 crown 4 BePh and BePh3 Chemistry A European Journal 26 44 9915 9922 doi 10 1002 chem 202000259 ISSN 0947 6539 PMC 7496417 PMID 31957173 Paparo Albert Jones Cameron 2019 02 01 Beryllium Halide Complexes Incorporating Neutral or Anionic Ligands Potential Precursors for Beryllium Chemistry Chemistry An Asian Journal 14 3 486 490 doi 10 1002 asia 201801800 ISSN 1861 4728 PMID 30604490 S2CID 58632466 Gilman Henry Schulze F 1927 11 01 Organoberyllium halides Journal of the American Chemical Society 49 11 2904 2908 doi 10 1021 ja01410a043 ISSN 0002 7863 a b Buchner Magnus R Muller Matthias Rudel Stefan S 2017 01 19 Beryllium Phosphine Complexes Synthesis Properties and Reactivity of PMe 3 2 BeCl 2 and Ph 2 PC 3 H 6 PPh 2 BeCl 2 Angewandte Chemie International Edition 56 4 1130 1134 doi 10 1002 anie 201610956 PMID 28004465 Paparo Albert Best Stephen P Yuvaraj K Jones Cameron 2020 12 14 Neutral Anionic and Paramagnetic 1 3 2 Diazaberyllacyles Derived from Reduced 1 4 Diazabutadienes Organometallics 39 23 4208 4213 doi 10 1021 acs organomet 0c00017 ISSN 0276 7333 S2CID 213828903 Gilliard Robert J Abraham Mariham Y Wang Yuzhong Wei Pingrong Xie Yaoming Quillian Brandon Schaefer Henry F Schleyer Paul v R Robinson Gregory H 2012 06 20 Carbene Stabilized Beryllium Borohydride Journal of the American Chemical Society 134 24 9953 9955 doi 10 1021 ja304514f ISSN 0002 7863 PMID 22670857 Paparo Albert Jones Cameron 2019 01 03 Beryllium Halide Complexes Incorporating Neutral or Anionic Ligands Potential Precursors for Beryllium Chemistry Chemistry An Asian Journal 14 3 486 490 doi 10 1002 asia 201801800 ISSN 1861 4728 PMID 30604490 S2CID 58632466 Hopkinson Matthew N Richter Christian Schedler Michael Glorius Frank 2014 06 25 An overview of N heterocyclic carbenes Nature 510 7506 485 496 Bibcode 2014Natur 510 485H doi 10 1038 nature13384 ISSN 1476 4687 PMID 24965649 S2CID 672379 Schuster Julia K Roy Dipak Kumar Lenczyk Carsten Mies Jan Braunschweig Holger 2019 02 18 New Outcomes of Beryllium Chemistry Lewis Base Adducts for Salt Elimination Reactions Inorganic Chemistry 58 4 2652 2658 doi 10 1021 acs inorgchem 8b03263 ISSN 0020 1669 PMID 30707568 S2CID 73424673 Camp Clement Arnold John 2016 09 20 On the non innocence of Nacnacs ligand based reactivity in b diketiminate supported coordination compounds Dalton Transactions 45 37 14462 14498 doi 10 1039 C6DT02013E ISSN 1477 9234 PMID 27353604 Coates G E Morgan G L 1971 01 01 Stone F G A West Robert eds Organoberyllium Compounds Advances in Organometallic Chemistry vol 9 Academic Press pp 195 257 doi 10 1016 S0065 3055 08 60052 0 ISBN 9780120311095 retrieved 2022 11 08 Arrowsmith Merle Braunschweig Holger Celik Mehmet Ali Dellermann Theresa Dewhurst Rian D Ewing William C Hammond Kai Kramer Thomas Krummenacher Ivo Mies Jan Radacki Krzysztof Schuster Julia K 2016 06 06 Neutral zero valent s block complexes with strong multiple bonding Nature Chemistry 8 9 890 894 Bibcode 2016NatCh 8 890A doi 10 1038 nchem 2542 ISSN 1755 4349 PMID 27334631 Retrieved from https en wikipedia org w index php title Organoberyllium chemistry amp oldid 1194598935, wikipedia, wiki, book, books, library,

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