Tetrahalodiboranes

Tetrahalodiboranes are a class of diboron compounds with the formula B₂X₄ (X = F, Cl, Br, I). These compounds were first discovered in the 1920s,^[1] but, after some interest in the middle of the 20th century, were largely ignored in research. Compared to other diboron compounds, tetrahalodiboranes are fairly unstable and historically have been difficult to prepare; thus, their use in synthetic chemistry is largely unexplored, and research on tetrahalodiboranes has stemmed from fundamental interest in their reactivity.^[2] Recently, there has been a resurgence in interest in tetrahalodiboranes, particularly in diboron tetrafluoride as a reagent to promote doping of silicon with B⁺ for use in semiconductor devices.^[3]

Structures of Tetrahalodiboranes

Structure

 

Geometry for most stable tetrahalodiborane conformers

Because the perpendicular and planar geometries of tetrahalodiboranes are generally very close in energy, the energetic difference between these two structures has been the most investigated aspect of the geometry of these molecules. As it turns out, the difference is dependent on the identity of the halide in the compound. B₂F₄ adopts a planar geometry (D_2h symmetry) in both as a solid and in the gas phase. The barrier to rotation, however, is small (only 0.42 kcal/mo)l.^[4][5] B₂Cl₄, however, adopts a planar geometry when crystalized but favors the perpendicular geometry (D_2d symmetry) in the gas phase.^[4][5] Computations of the relative stability of the two conformers indicate that the D_2d geometry is ~2 kcal/mol lower in energy; the planar geometry in the solid phase is thought to be due to packing effects.^[5] Continuing this trend, computational modeling and experimental results agree that B₂Br₄ and B₂I₄ favor the perpendicular D_2d geometry.^[4][6]

Synthesis

The first synthesis of a tetrahalodiborane was reported by Stock et al. in 1925 where the authors reduced BCl₃ to form B₂Cl₄ by running a current between zinc electrodes immersed in liquid BCl₃.^[1] Later work explored gas phase syntheses of B₂Cl₄ using gaseous BCl₃ and mercury electrodes.^[7] Early characterization of B₂Cl₄ reported the to be a colorless, pyrophoric liquid that decomposes at temperatures above 0 °C.^[8] B₂F₄ was not synthesized until 1958 when Finch and Schlesinger reported the successful synthesis of B₂Cl₄ with antimony trifluoride to form B₂F₄.^[9] Unlike B₂Cl₄, B₂F₄ is stable at room temperature.^[9] The heavier tetrahalodiboranes, B₂Br₄ and B₂I₄, were first published in 1949 by Schlesinger et al. and Schumb respectively.^[10] B₂Br₄ was first accessed by reacting B₂Cl₄ and BBr₃.^[10] B₂I₄ was first synthesized using electrodeless radiofrequency discharge to reduce BI₃.^[10] B₂Br₄ is stable at temperatures below -40 °C, while B₂I₄ is stable below 0 °C. B₂I₄ also degrades when exposed to light.^[11] Decomposition of B₂I₄ at elevated temperatures yields a BI₃ and a black solid found to be a mixture of B₉I₉ and B₈I₈.^[12]

The initial interest in tetrahaloiboranes was largely fundamental, and more applied consideration of tetrahalodiboranes was largely limited by the difficulty of synthesis and the low stability of isolated compounds. Recent improvements in the synthesis of tetrahalodiboranes has yielded more convenient solution phase syntheses of B₂F₄, B₂Cl₄, B₂Br₄, and B₂I₄.^[3] The solution phase synthesis of B₂Br₄ first reported by Noth et al in 1981 has not been improved upon. To form B₂Br₄ in solution, B₂(OMe)₄ is treated with BBr₃.^[3] Other tetrahalodiboranes can be accessed from B₂Br₄ in the solution phase by reacting with SbF₃, GaCl₃, or BI₃ to form B₂F₄, B₂Cl₄, or B₂I₄ respectively.^[3] These improvements in synthetic methods have opened the door for exploring potential applications of tetrahalodiboranes; while this interest has been fairly limited thus far, researchers have begun to explore the use of tetrahalodiboranes as synthetic building blocks and for use in industrial applications.^[3] Notably, recent publications discussing tetrahalodiboranes have been largely in patent literature discussing the use of B₂F₄to replace BF₃ as a feed chemical to dope semiconductors with boron ions.^[3]

Reactivity

Lewis base adduct formation

 

Adduct formed by tetrahalodiborane and two lewis bases

The boron atoms in tetrahalodiboranes are highly lewis acidic and readily form adducts with neutral lewis bases.^[11] Though the formation of these complexes is usually energetically favorable, early attempts to form these lewis acid base complexes were hindered by the lability of the halogen substituents;^[11] prior to the 1992 publication of three additional phosphane-tetrahalodiborane(4) adducts, only three lewis acid-lewis base adducts had been reported.^[13] Other work has described many more lewis acid-lewis base adducts that form readily, but also outline how stability challenges with tetrahalodiboranes persist even in stabilized complexes.^[11] Examples of these unstable tetrahalodiborane-lewis base adducts include the bis-diethyl ether adduct formed with B₂Cl₄ or B₂F₄, the bis-adduct of B₂Cl₄ and either SH₂ or PH₃, and adducts formed by B₂Cl₄ or B₂F₄ and weak phosphine donors such as PCl₃ or PBr₃.^[11]

There are, however, some adducts that are stable beyond room temperature. B₂Cl₄ and B₂F₄ both form stable mono- and bis-adducts with aprotic nitrogen donors.^[11] The first of these stable lewis base-tetrahalodiborane adducts was published in 2012 by Braunshcweig et al. showing that B₂Br₄(IDip)₂ (where IDip = 1,3-bis(2,6-diisopropylphenyl)-imidazole-2-ylidene) is stable at ambient temperature. B₂Br₄(IDip)₂could then be reduced to form B₂Br₂(IDip)₂, a stable diborene, and could ultimately be reduced further to form >B₂(IDip)₂ the first isolable diboryne.^[11][14] Since this discovery, the Braunschweig group has published a number of other stable tetrahalodiborane adducts including some monoadducts and some asymetrical bis adducts. These adducts are typically characterized using ¹¹B NMR.^[11]

Reaction with transition metals

There has been some investigation of the reactivity of tetrahalodiboranes with transition metals. Norman et al. reported reactivity of B₂F₄ with PtL₂ to form cis-[Pt(BF₂)₂L₂] where L₂=₂PPh₃, Ph₂P(CH₂)₄PPh₂.^[3] Because the boron-halide bonds in B₂F₄ are substantially less reactive than in heavier tetrahalodiboranes, it is unsurprising that reactivity with Pt occurs at the B-B bond.^[2]

 

Because it was expected that heavier tetrahalodiboranes might have more reactive boron-halide bonds, the reactivity of B₂I₄ with electron rich Pt(PCy₃)₂ was explored.^[2] The greater lability of the B-I bond relative to the B-F bond in B₂F₄ allowed for the formation of a diplatnum complex with borryl ligands and a bridging [B₂I₄].^[2]

 

Reaction of diboron tetrachloride with a platinum complex to form a diplatinum complex

Reaction with boriranylideneboranes

In 2001, Seibert et al. showed that three boriranylideneboranes first synthesized by Berndt et al. in the 1980s could be reacted with tetrahalodiboranes to yield interesting boron containing compounds shown in the scheme below.^[15] In the first reaction, both the chlorine and fluorine containing compounds were synthesized in good yields, but the fluorine compound was noticeably less stable. The all compounds shown below were characterized by ¹¹B,¹H and ¹³C NMR.

 

Reported reactions between tetrahalodiboranes and boriranylideneboranes

Addition to unsaturated hydrocarbons

 

Some representative reactions showing 1,2-addition of diboron tetrachloride to hydrocarbons. Some of these reactions can also be carried out under more forcing conditions with diboron tetrafluoride

Tetrahalodiboranes can add to unsaturated hydrocarbons. Schlesinger et al. published 1,2-additions of B₂Cl₄ to ethylene and acetylene.^[16] Later work explored the reactivity of B₂Cl₄ with other alkenes, alkynes and dienes and showed that B₂F₄ can react similarly.^[5] B₂Br₄ can also add to alkenes.^[5] In 2015, Brown et al. used electronic structure calculation to provide mechanistic information on some of these (uncatalyzed) boron additions. Most interestingly, the authors were able to provide mechanistic information explaining the stereospecificity of the reaction of B₂Cl₄ with 1,2-disubstituted alkenes.^[5]

References

1. Stock, Alfred; Brandt, Arnold; Fischer, Hans (15 April 1925). "Der Zink‐Lichtbogen als Reduktionsmittel". Berichte der Deutschen Chemischen Gesellschaft (A and B Series). 58 (4): 643–657. doi:10.1002/cber.19250580402.
2. Braunschweig, Holger; Dewhurst, Rian D.; Jiménez-Halla, J. Oscar C.; Matito, Eduard; Muessig, Jonas H. (8 January 2018). "Transition-Metal π-Ligation of a Tetrahalodiborane". Angewandte Chemie International Edition. 57 (2): 412–416. doi:10.1002/anie.201709515. PMID 29134749.
3. Arrowsmith, Merle; Böhnke, Julian; Braunschweig, Holger; Deißenberger, Andrea; Dewhurst, Rian D.; Ewing, William C.; Hörl, Christian; Mies, Jan; Muessig, Jonas H. (20 July 2017). "Simple solution-phase syntheses of tetrahalodiboranes(4) and their labile dimethylsulfide adducts". Chemical Communications. 53 (59): 8265–8267. doi:10.1039/c7cc03148c. PMID 28656182. S2CID 206063034.
4. Clark, Timothy; von Ragué Schleyer, Paul (1981). "Conformational preferences of 34 valence electron A₂X₄ molecules: Anab initio Study of B₂F₄, B₂Cl₄, N₂O₄, and C₂O₄²⁻". Journal of Computational Chemistry. 2: 20–29. doi:10.1002/jcc.540020106. S2CID 98744097.
5. Pubill-Ulldemolins, Cristina; Fernánez, Elena; Bo, Carles; Brown, John M. (16 September 2015). "Origins of observed reactivity and specificity in the addition of B2Cl4 and analogues to unsaturated compounds". Organic & Biomolecular Chemistry. 13 (37): 9619–9628. doi:10.1039/C5OB01280E. PMID 26260922.
6. Mackie, Iain D.; Hinchley, Sarah L.; Robertson, Heather E.; Rankin, David W. H.; Pardoe, Jennifer A. J.; Timms, Peter L. (12 November 2002). "The structures of borane carbonyl compounds B4X6CO (X = F, Cl, Br and I) by gas-phase electron diffraction and ab initio calculations". Journal of the Chemical Society, Dalton Transactions (22): 4162–4167. doi:10.1039/B207192D.
7. Wartik, Thomas.; Moore, R.; Schlesinger, H. I. (September 1949). "Derivatives of Diborine". Journal of the American Chemical Society. 71 (9): 3265–3266. doi:10.1021/ja01177a538.
8. Urry, Grant; Wartik, Thomas; Moore, R. E.; Schlesinger, H. I. (1954). "The Preparation and Some of the Properties of Diboron Tetrachloride, B2Cl41". Journal of the American Chemical Society. 76 (21): 5293–5298. doi:10.1021/ja01650a010.
9. Finch, Arthur; Schlesinger, H. I. (July 1958). "Diboron Tetrafluoride". Journal of the American Chemical Society. 80 (14): 3573–3574. doi:10.1021/ja01547a020.
10. Neeve, Emily C.; Geier, Stephen J.; Mkhalid, Ibraheem A. I.; Westcott, Stephen A.; Marder, Todd B. (2016). "Diboron(4) Compounds: From Structural Curiosity to Synthetic Workhorse". Chemical Reviews. 116 (16): 9091–9161. doi:10.1021/acs.chemrev.6b00193. hdl:1807/78811. PMID 27434758.
11. Englert, Lukas; Stoy, Andreas; Arrowsmith, Merle; Muessig, Jonas H.; Thaler, Melanie; Deißenberger, Andrea; Häfner, Alena; Böhnke, Julian; Hupp, Florian; Seufert, Jens; Mies, Jan; Damme, Alexander; Dellermann, Theresa; Hammond, Kai; Kupfer, Thomas; Radacki, Krzysztof; Thiess, Torsten; Braunschweig, Holger (26 June 2019). "Stable Lewis Base Adducts of Tetrahalodiboranes: Synthetic Methods and Structural Diversity". Chemistry – A European Journal. 25 (36): 8612–8622. doi:10.1002/chem.201901437. PMID 30974025. S2CID 109939253.
12. Massey, A.G.; Portal, P.J. (January 1982). "Diboron tetraiodide and its decomposition". Polyhedron. 1 (3): 319. doi:10.1016/S0277-5387(00)87173-9.
13. Keller, Willi; Sneddon, Larry G.; Einholz, Wolfgang; Gemmler, Armin (November 1992). "Phosphane – Tetrahalodiborane(4) Adducts: Formation of closo ‐3,4,5,6‐Tetrabromo‐1,2‐diphosphahexaborane(4)". Chemische Berichte. 125 (11): 2343–2346. doi:10.1002/cber.19921251102.
14. Braunschweig, Holger; Dewhurst, Rian D.; Hammond, Kai; Mies, Jan; Radacki, Krzysztof; Vargas, Alfredo (15 June 2012). "Ambient-Temperature Isolation of a Compound with a Boron-Boron Triple Bond". Science. 336 (6087): 1420–1422. doi:10.1126/science.1221138. PMID 22700924. S2CID 206540959.
15. Ziegler, Andreas; Pritzkow, Hans; Siebert, Walter (2001). "Reactions of Diboratetrahalides(4) with Boriranylideneboranes − Formation, Reactivity, and Structures of Cyclic Tetraborylmethanes and Isomeric Diborylmethyleneborane Derivatives". European Journal of Inorganic Chemistry. 2001 (2): 387–391. doi:10.1002/1099-0682(200102)2001:2<387::AID-EJIC387>3.0.CO;2-N.
16. Urry, Grant; Kerrigan, James; Parsons, Theran D.; Schlesinger, H. I. (November 1954). "Diboron Tetrachloride, B 2 Cl 4 , as a Reagent for the Synthesis of Organo-boron Compounds. I. The Reaction of Diboron Tetrachloride with Ethylene 1". Journal of the American Chemical Society. 76 (21): 5299–5301. doi:10.1021/ja01650a011.