Hypervalent Bromine(III) Compounds: Synthesis, Applications, Prospects

Hypervalent compounds play a prominent role in homogeneous oxidation catalysis. Despite the higher reactivity of hypervalent bromine compounds when compared to their isoelectronic iodine analogues, the corresponding  3 -bromanes are much less explored. This can be attributed to the discernible lack of convenient strategies for their synthesis. This short review highlights the available methods for the synthesis of various organo- 3 -bromanes, with a major focus on the recent developments and reactivities in the last few years. Additionally, limitations and future prospects of hypervalent bromine chemistry are discussed.


Introduction
In marked contrast to the substantial growth in the field of iodine(III) reagents, their isoelectronic hypervalent bromine counterparts have seen notably slower progress.During the last century, only a reserved selection of scientists have partaken in their development, resulting in their limited precedence in the literature.While the first ever synthesis of a hypervalent iodine compound, (dichloro-iodo)benzene, was reported in 1886 by Willgerodt, 1 the first hypervalent bromonium compound arrived notably later, in 1952, when Sandin and Hay reported the preparation of a bromonium salt through the intramolecular nucleophilic bromine attack on an aryldiazonium salt. 2 Still, the remarkably slower growth of hypervalent bromine chemistry cannot be justified by its later arrival 'on the market'.In line with this, we will highlight both the predominant struggles in terms of the synthetic approaches that have heavily hindered progression in this field, as well as the attractive properties of bromine(III) compounds, in an effort to incentivize scientific interest. 3

Short Review Synthesis
Hypervalency refers to a main group element, such as hypervalent bromine, that breaks the octet rule and has more than 8 electrons in its valence shell. 4According to IUPAC rules, compounds with non-standard bonding numbers are given a  notation.For example, H 3 Br is called  3bromane and has a dectet structure, while H 5 Br is called  5bromane with a dodectet structure.

Figure 1 Commonplace hypervalent iodine/bromine compounds
Hypervalent-halogen-containing compounds have attracted unprecedented attention in organic chemistry, which has been attributed to their unique characteristic properties. 5Undoubtedly, the vast majority of this attention has been paid to the field of iodine chemistry, with reagents such as Dess-Martin periodinane, 6 [bis(trifluoroacetoxy)iodo]benzene, (diacetoxyiodo)benzene and diaryliodonium-type compounds 7 becoming mainstream reagents in contemporary organic synthesis and even commercially available (Figure 1).The attractiveness of iodine(III) reagents can be accredited to their versatile characteristics; they are a mild, non-toxic (green oxidation), easy to handle and environmentally benign class of reagents.The reactivity pattern of hypervalent iodine is somewhat discretely similar to the heavy transition metals and, as such, they are typically preferred as a less toxic alternative.The diverse nature of these reactions includes oxidative couplings, 8 halogenations, 9 arylations, 10 oxidative rearrangements, 11 trifluoromethylations 12 and C-H functionalizations. 13Their hypervalent bromine analogues can feature superior reactivity owing to their higher nucleofugality, ionization potential and stronger electrophilicity. 14nsurprisingly, these superior qualities have facilitated the development of other useful synthetic transformations including the Bayer-Villiger-like oxidations of open-chain aliphatic aldehydes, 14 metal-free C-O and C-N couplings, 15 the oxidative coupling of alkynes and 1° alcohols, 16 metalfree aminations of unactivated alkanes 17 and thermal solvolysis, 18 amongst others.Even so, despite their often superior reactivity and unique structures, a limited number of hypervalent bromine reagents have been reported and utilized, especially in comparison to hypervalent iodine reagents.
Perhaps the most substantial impediment to progression in this field can be attributed to the discernible lack of expedient methods for the synthesis of these compounds.The main challenge arises due to the innate thermodynamic barrier for the oxidation of bromine(I) to hypervalent bromine.For instance, the oxidation potentials of aryl bromides [o-(CO 2 Et)C 6 H 4 Br = 2.3 V vs Ag/0.01 M AgCl in MeCN] are remarkably high in comparison to iodides [o-(CO 2 Et)C 6 H 4 I = 1.9 V vs Ag/0.01 M AgCl in MeCN], arising from their greater electronegativity and ionization potential. 19Hereby, the oxidation of the corresponding haloarenes with oxidants, which is standard for the preparation of iodine(III) reagents, is generally not effective for the synthesis of hypervalent bromanes.Until recently, the most competent synthesis of hypervalent bromine compounds involved the ligand exchange of bromine trifluoride (BrF 3 ), which circumvents the unfavorable oxidation process.These approaches, however, are far from ideal in terms of safety and convenience.Bromine trifluoride is a highly reactive compound that etches glass and quartz, sets fire to paper and wood, and reacts violently with the majority of organic compounds. 20iterature protocols for its access can be low yielding and require harsh reaction conditions.The choice of solvent is also pivotal in terms of solubility and stability, but is often not typical in terms of organic chemistry.For instance, BF 3 reacts violently with CH 2 Cl 2 at temperatures above -20 °C. 21t is moderately soluble in trichlorofluoromethane, but above 5-10 °C it reacts with CCl 3 F to produce CCl 2 F 2 , mainly.Moreover, the strict exclusion of air and moisture, immoderate reactivity and extreme toxicity of this reagent means specialist knowledge is required for such reactions.The poor stability of the subsequently prepared bromine(III) reagents regularly complicates matters further.For example, Frohn's reagent, a key building block for various  3 -bromanes, decomposes immediately in the presence of moisture via H 2 O oxidation. 22Evidently, the development of user-friendly synthetic approaches, in terms of experimental safety, ease and proficiency, could provide significant incentive for the influx of new researchers into this field, which is key to rapid progression.High yielding and milder reaction conditions to access bromine(III), with a particular focus on precluding the need for fluorinating reagents, has been the focus of research in the past 5 years.Pleasingly, electrochemical oxidation, single-step oxidation with commercially available organic oxidants, and bench-stable reagents have all emerged recently.Herein, we will discuss the synthetic approaches towards bromine(III) reagents, with an emphasis on the advances in synthetic strategies that have arisen in the past 5 years.In this respect, we will highlight synthetic methods from the early 19th century and modern progressive techniques, to allow comparison between modern-day literature and the early endeavors.

Short Review Synthesis 2 Diaryl- 3 -bromanes
In pioneering work by Sandin and Hay, the first synthesis of an organo- 3 -bromane was reported through the thermal decomposition of the aryldiazonium salt, readily prepared from 2-amino-2′-bromobiphenyl (Scheme 1). 2 Interestingly, the first organo- 3 -chlorane was also synthesized using a similar strategy.In this work, the close proximity of the adjacent halogen atom was crucial to capture the generated aryl cation in an intramolecular fashion.In this respect, adoption of an almost identical strategy for the intermolecular diaryl- 3 -bromane synthesis was largely unsuccessful, only resulting in low yields of the desired products (Scheme 2). 23,24Encouragingly, the efficiency of trapping the aryl cation has recently been improved significantly by employing a weakly coordinating ligand/counter anion along with the mesityl diazonium salt. 25heme 1 Synthesis of the first hypervalent organo- 3 -bromane Scheme 2 Initial and modified attempts for the synthesis of acyclic diaryl- 3 -bromanes Later, in 1980, in a significant breakthrough, Nesmeyanov and co-workers developed a more general pathway for the synthesis of acyclic diaryl- 3 -bromanes.In this approach, the highly reactive bromine trifluoride (BrF 3 ) underwent double ligand exchange on the bromine(III) center with aryl groups, deriving from tetraarylstannane or diarylmercury compounds in the presence of BF 3 •OEt 2 (Scheme 3).26 Such ligand exchange with a nucleophile is believed to follow an addition-elimination sequence similar to iodine(III) analogues. Te role of acetonitrile in this reaction is proposed to solubilize and stabilize the highly reactive BrF 3 and decrease the oxidizing ability of the bromine(III) through BrF 3 •(MeCN) 2 complex formation.The Lewis acid BF 3 •OEt 2 was used to facilitate the second F/Ar exchange.Later, this approach was successfully extended for the use of aryl silanes, 27 and even arenes, 28 in place of tetraarylstannanes in acyclic diaryl- 3 -bromane synthesis.The use of BF 3 •OEt 2 as an exogenous Lewis acid could be avoided when the Lewis acidic aryl-transfer reagent (C 6 F 5 ) 2 BF was used.However, this strategy is limited by the generality in aryl-transfer reagent (Scheme 4).29 From the crystal structure, an infinite -Br-F-B-F-zigzag chain structure was observed for bis(perfluorophenyl)bromane tetrafluoroborate and the bromine(III) center exhibited a distorted square-planar coordination.

Scheme 4 External Lewis acid free intermolecular diaryl- 3 -bromane synthesis
Acyclic diaryl- 3 -iodanes can be synthesized by simple oxidation of an iodoarene by an oxidant in the presence of another arene.However, such an approach is not suitable for isoelectronic diaryl- 3 -bromanes owing to the lower polarizability of the bromine atom. 30However, a few reports can be found where 2-bromobiphenyl derivatives afford the desired  3 -bromane through oxidation by either hydrogen peroxide in H 2 SO 4 (Scheme 5) 31 or by H 2 S 2 O 8 generated in situ from a K 2 S 2 O 8 /H 2 SO 4 combination. 32heme 5 Arene-oxidation-induced diaryl- 3 -bromane synthesis Despite all these efforts, the synthesis of diaryl- 3 -bromanes is still challenging since BF 3 is necessary in most cases.BrF 3 -free methods are low yielding and are typically limited to intramolecular versions only.
Recently, in a seminal report by Yoshida and co-workers, a modified procedure for the BrF 3 -free synthesis of cyclic diaryl- 3 -bromanes was disclosed.In this case, a series of functionalized 2-amino-2′-bromobiphenyl derivatives was easily synthesized through palladium-catalyzed Suzuki coupling reactions.Next, these biphenyl derivatives were successfully cyclized via their corresponding diazonium salts to produce the diarylbromonium salts (Scheme 6).From the crystallographic analysis of the chloride salt, the existence of an ion pair was unambiguously established in place of the covalent bond as initially predicted in Scheme 1.The ionic nature was further confirmed by successful counter anion exchange with triflate and the bulky BAr

Short Review Synthesis
Yoshida utilized these stable bromonium salts as halogenbonding organocatalysts in the Michael addition of indoles to ,-unsaturated ketones.18b So far, this is the first and only catalytic application of a  3 -bromane in synthesis.

Scheme 6 Synthesis and catalytic application of stable diaryl- 3 -bromanes
Furthermore, in an important breakthrough in recent years, Wencel-Delord and co-workers developed a general and safe strategy for the synthesis of cyclic diaryl- 3 -bromanes with significantly improved yields.The use of tertbutyl nitrite ( t BuONO) as a mild oxidant in the presence of a Brønsted acid was key to generate these bromonium salts in high yields (Scheme 7). 15Subsequently, these bromonium salts were found to form arynes in the presence of a weak base.Such arynes could be trapped by a carboxylic acid or amine to deliver the formal meta-selective transitionmetal-free C-O and C-N coupling products.Typically,  3 -iodanes can display such reactivity only in the presence of a transition metal, emphasizing the superior qualities of hypervalent bromine reagents. 33However, a recent report disclosed that  3 -iodanes can show similar reactivity in the presence of strong bases. 34part from such newly discovered unique reactivity profiles, in general, diaryl- 3 -bromanes serve as more efficient arylating reagents than their  3 -iodane analogues.They present as excellent arylating reagents towards various heteroatom nucleophiles (O, N, S, halide, etc.) under mild reaction conditions.In general, the reactivity towards harder nucleophiles follows the order: Ph 2 I + < Ph 2 Br + < Ph 2 Cl + owing to the enhanced nucleofugality along the sequence. 35n general, for 4-substituted unsymmetrical diaryl- 3 -bromanes, nucleophiles prefer to attack a phenyl ring carrying electron-withdrawing groups.However, for 2-substituted unsymmetrical diaryl- 3 -bromanes, an ortho effect plays a crucial role and the 2-substituted phenyl ring is attacked by the incoming nucleophile. 24,36Dialkyl- 3 -bromanes Dialkyl- 3 -bromanes are powerful alkylating reagents in organic chemistry.However, given the lack of reports in recent years, this short section proves to merely introduce the reader to their existence, benefits and synthetic problems. Akyl- 3 -bromanes are generally considered as unstable transient intermediates.As a result, only a limited number of methods are known for their synthesis and characterization.Open-chain dialkyl and alkyl(aryl)- 3 -bromanes were largely unknown until the late 20th century.In 1969, the first symmetrical dialkyl and alkyl(aryl)- 3 -bromanes were reported by Olah and DeMember through the self-condensation of alkyl halides with a strong Lewis acid, such as SbF 5 •SO 2 , under inert atmospheres at low temperatures (Scheme 8).37 The formation of dimethyl, diethyl and diisopropyl(hexafluoroantimonato)- 3 -bromanes was confirmed by low-temperature NMR, IR, and laser Raman spectroscopy.38 Symmetrical dialkylhalonium ions could be obtained by the reaction of alkyl halides with an excess of SbF•SO 2 , anhydrous fluoroantimonic acid (HF•SbF 5 ) or anhydrous silver hexafluoroantimonate in SO 2 solution.Both symmetrical and unsymmetrical dialkylhalonium ions could be obtained by the alkylation of alkyl halides with methyl or ethyl fluoroantimonate in SO 2 solution.Dialkylhalonium salts prepared this way were generally clean and not contaminated with any by-products.While the reactions of alkyl fluoroantimonates with methyl-, ethyl-or diisopropyl bromide gave the corresponding dialkylhalonium ions, the reactions of tertiary alkyl halides gave an alkylcarbenium ion and a symmetrical dialkylhalonium ion.Both unsymmetrical and symmetrical dialkylhalonium compounds undergo immediate hydrolysis in atmospheric moisture, which hampers their practicality. Mreover, the

Short Review Synthesis
non-symmetrical  3 -bromanes were kinetically labile and susceptible to disproportionation and self-condensation, even at low temperature (-30 °C).In general, the relative stability of the prepared dialkylhalonium ions follows the order RI + R > RBr + R > RCl + R, indicating that the larger halogen atom was more capable of accommodating the charge.Despite the instability, compound 2 could be isolated as a storable solid at room temperature under argon.The chemical reactivity as well as synthetic application of the prepared dialkylhalonium ions was demonstrated by the alkylation of -donor aromatics, olefins and a wide variety of n-donor bases.For example, compounds 2 and 3 facilitated the Friedel-Crafts alkylation of benzene or toluene at -50 °C in SO 2 ClF within 5 minutes, and the isomer distributions showed no significant differences from typical Friedel-Crafts reactions.Notably, dimethyl- 3 -iodane could not facilitate the same reaction, even at 20 °C, emphasizing the increased reactivity of the dialkyl- 3 -bromanes compared to the corresponding iodanes.Nevertheless, further investigation of these types of compounds is mainly restricted by their facile decomposition.

Scheme 8 Synthesis of dialkyl- 3 -bromanes
In 1937, Roberts and Kimball first proposed that a cyclic three-membered bromonium ion was formed as an intermediate during the electrophilic addition of Br 2 to a double bond. 39Subsequently, similar reactions have been invoked for the preparation of cyclic dialkyl- 3 -bromanes.Olah and Bollinger presented the synthesis of a cyclic dialkyl- 3 -bromane 6 by treating 2-fluoro-3-bromo-2-methylbutane (5) with SbF 5 in a sulfur dioxide solution at -60 °C (Scheme 9). 40heme 9 Synthesis of a cyclic dialkyl- 3 -bromane by Olah and coworkers When 2-fluoro-3-bromo-2-methylbutane was ionized in a SbF 5 •SO 2 solution at -78 °C, a stable solution of the (trimethyl)ethylenebromonium ion was obtained.Although NMR evidence for the existence of such species was reported, solid-state structures for the  3 -bromane were not since subsequent nucleophilic attack to yield the product was rapid.In terms of modern synthetic developments, these procedures have diminished appeal, particularly in terms of safety.Antimony pentafluoride and its derivatives are high-ly corrosive chemicals that require specialist equipment for handling, which limits the user-friendliness of such techniques.Later, Brown and co-workers reported the solidstate structure of a three-membered cyclic  3 -bromane, notably in the absence of SbF 5 (Scheme 10). 41The bromination of adamantylidene adamantane in chlorinated hydrocarbons yielded a bright yellow solid, which could be easily handled without special precautions.This compound was unstable in polar protic solvents and tended to lose Br 2 , converting back into the starting alkene, but it had both stability and modest solubility in MeCN, MeNO 2 , and dichloroethane.In this case, the incorporation of the adamantyl group was to sterically shut down subsequent nucleophilic substitution reactions.
Scheme 10 Structure of a three-membered cyclic  3 -bromane synthesized by Brown and co-workers Overall, in recent years, there has been no significant progression in the synthesis of dialkyl- 3 -bromanes, despite their synthetic prowess.Given their emergence as powerful alkylating reagents, certainly a safer, more stable, and versatile bromine(III)-type alternative to these reagents would be of huge progress to this area.

Dihetero- 3 -bromanes
As outlined in the previous two sections, the stability of organo- 3 -bromanes is dependent on the presence of aryl groups with a bromine(III) center.To complement this, several attempts were made to investigate the synthesis and reactivity of dihetero- 3 -bromanes containing one aryl group.The first report on dihetero- 3 -bromane synthesis came from the Martin group in 1980.In this case, highly reactive liquid BrF 3 was employed to oxidize the bromoarene 7 in (CFCl 2 ) 2 at a low temperature for the generation of airand moisture-stable solid 8 (Scheme 11). 42The crystal structure revealed two inequivalent O-Br bonds with lengths slightly longer than the equivalent covalent bond lengths (1.81 Å).The two appended 'Martin' alkoxy ligands bind in the apical site of the bromine(III) center to form linear O-Br-O hypervalent bonding.An intermolecular oxygen binding to the Lewis acidic bromine(III) center from another molecule forms an overall dimeric structure and provides higher stability. 43Compound 8 can tolerate mild acidic or basic conditions.Also, it can oxidize heteroatomic nucleophiles such as PhSH, PhNH 2 , NaI, HBr, etc.

Short Review Synthesis
Scheme 11 Synthesis of a stable dialkoxyaryl- 3 -bromane Despite its high stability, an important limitation of Martin's  3 -bromane is the use of BrF 3 .In 2021, this issue was addressed by Francke, Suna and co-workers.In this ground-breaking example, the simple electrochemical oxidation of aryl bromides possessing two coordinating hexafluoro-2-hydroxypropanyl substituents delivered stable  3bromane derivatives in high yields (Scheme 12). 44heme 12 A simplified synthesis and an application of Martin's  3bromane With just the use of an undivided cell under constant current conditions, and with glassy carbon (GC) as the working electrode, platinum as the counter electrode, TBABF 4 as the supporting electrolyte and HFIP (hexafluoroisopropanol) as the solvent, the easy scale up for the synthesis of a bench-stable  3 -bromane on multi-gram scale was possible.Moreover, the reactivity of such  3 -bromanes was investigated for oxidative C-C, C-N, and C-O bond forming reactions to complement this simplified synthetic route.The reactivity of Martin's  3 -bromane is sufficient for oxidative amidation and benzoxazole formation and could be further enhanced by Lewis or Brønsted acid additives, as demonstrated by its successful application in biaryl coupling.
Excluding Martin's  3 -bromane, the chemistry of difluoro- 3 -bromanes is quite well established in the literature.In 1984, Frohn and co-workers revolutionized the field of hypervalent bromine chemistry by introducing difluoro- 3bromanes.These were prepared from aryl silanes and BrF 3 through ligand exchange (Scheme 13). 22,27In the absence of any other convenient procedure, Frohn's reagent serves as a pivotal platform for the synthesis of various  3 -bromanes without using highly reactive BrF 3 in subsequent steps.Generally, Frohn's reagents are stable at room temperature, but require an inert atmosphere to prevent instantaneous decomposition into O 2 , HF and the corresponding bromoarenes in the presence of atmospheric moisture.The fluorine ligands can be easily displaced by any other nucleophiles which are stable against oxidation.Easily oxidized substrates such as aromatic alcohols and aldehydes are often converted into fluoromethyl aryl ethers 45 and difluoromethyl aryl ethers, 46 respectively, after oxidation followed by 1,2-aryl migration.

Scheme 13 Synthetic route towards difluoro- 3 -bromanes and their decomposition pathway
In a sharp contrast to the high stability and applicability of diacyloxy- 3 -iodanes, the use of diacyloxy- 3 -bromanes is mainly limited by their high moisture sensitivity.[Bis(trifluoroacetoxy)]- 3 -bromane was first synthesized by Frohn and Giesen from Frohn's reagent through ligand exchange with trifluoroacetic anhydride (Scheme 14). 22However, its reactivity was not explored.

Scheme 14 Synthesis of bis(trifluoroacetoxy)bromoarene
Later, Ochiai and co-workers followed a similar procedure to synthesize the corresponding acetoxy derivative.Such compounds are discretely similar to the very stable, heavily utilized and commercially available (diacetoxyiodo)benzenes.They explored the reactivity of this diacetoxybromoarene in alkene aziridination reactions (Scheme 15). 47The aziridination reaction proceeds with TfNH 2 or sulfamate esters in a highly stereospecific fashion with retention of the stereochemistry in olefins at room temperature by using the olefins as the limiting reagents.Interestingly, (diacetoxybromo)arenes were also used in C-H amination reactions of alkanes in the presence of a suitable sulfonamide source. 48

Scheme 15 Synthesis and reactivity of a (diacetoxybromo)arene
In a seminal report in 2021, Miyamoto, Ochiai and coworkers reported the synthesis of air/moisture-stable  3bromanes (Scheme 16). 19The methodology represents the first versatile synthetic procedure towards the synthesis of

Short Review Synthesis
bench-stable  3 -bromanes.Analogous to Martin's approach, the bromine(III) center is effectively stabilized by intramolecular R-Br-O bonding, both electronically and sterically, but in this case via a 1,2-benzbromoxol-3-(1H)-one (BBX) ligand.The clever use of a N-triflylimino group as an exocyclic changeable ligand allowed the introduction of diverse functionalities through electrophilic substitution reactions on the bromine(III) center.Using this strategy, a variety of Br-hydroxy, -acetoxy, -alkynyl, -aryl, and bis[(trifluoromethyl)sulfonyl]methylide  3 -bromane derivatives were prepared.Intriguingly, all of these  3 -bromanes were found to be air-, moisture-, and bench-stable.The extra stabilization of the bromine(III) center by intramolecular R-Br-O hypervalent bonding was further confirmed by X-ray crystallography and NMR and IR spectroscopy of N-triflylimino- 3 -bromane.The hydroxy-BBX- 3 -bromane could be stored in a refrigerator (4 °C) indefinitely, though it slowly decomposes with a half-life (t 1/2 ) of 7.5 days in CD 3 CN/D 2 O (1:1) solution with evolution of O 2 gas.

Scheme 16 Synthesis of air-and moisture-stable  3 -bromanes
The initial reactivity of these compounds was also investigated for the oxidation of various nucleophiles.The hydroxy-BBX- 3 -bromane served as a potent oxidizing reagent through the homolysis of the bromine(III)-OH bond.

Alkenyl- 3 -bromanes
Hypervalent 1-alkenyl(phenyl)- 3 -iodanes demonstrate rich chemistry in modern organic synthesis. 49The tenacious leaving group affinity of phenyl- 3 -iodanyl groups mean they serve as superb precursors for the generation of alkylidene carbenes and undergo unusual vinylic nucleo-philic displacement by a wide array of nucleophiles. 50On the other hand, the chemistry of the analogous alkenyl- 3bromanes has been remarkably under explored in comparison because user-friendly synthetic methods are not wellestablished.Most of the proficient synthetic techniques towards these compounds rely on difluoro- 3 -bromanes as key reagents, yielding alkenyl- 3 -bromanes, often with limited stability.Their thermal stability varies over a broad range depending on the nature of the ligands and propensity for polymerization.From an historical perspective, the first preparation of an alkenyl- 3 -bromane was performed in 1985 by Olah and co-workers, which was only characterized by NMR. 51The method proceeded via the alkylation of the corresponding vinyl bromides (Scheme 17).For stance, treatment of vinyl bromide, in SO 2 ClF at -78 °C, with a fourfold excess of freshly prepared CH 3 F•SbF 5 complex, yielded a yellow-colored solution of methyl(vinyl)- 3 -bromane, the 13 C NMR spectrum of which at -90 °C showed three absorptions at 132.9 (C  ), 120.9 (C  ) and 44.1 (Me) ppm.Similarly, the ethylvinyl bromonium ion was prepared by using the CH 3 CH 2 F•SbF 5 complex in a SO 2 solution.However, these alkenyl- 3 -bromanes were unstable due to their high tendency for polymerization and they consequently decomposed over several hours (roughly 4 h), even at -78 °C.Facile anti--elimination of the hydrogen and bromanyl group, yielding the corresponding alkynes, is the rationality behind the low thermal stability of such reagents.Hence, because of the lack of stability of such compounds, they were not demonstrated in synthetic applications.

Scheme 17
The first preparation of an alkenyl- 3 -bromane Noteworthily, the corresponding alkenyl- 3 -iodanes could not be prepared under these conditions due to the preferential oxidation of vinyl iodides.In reality, this method has relatively low practical value for application because of the low stability and tedious preparation of such compounds.But, considering the sustained success in the development of procedures for the synthesis of alkenyl- 3 -bromanes, it is obvious that the work served as a pivotal building block for the development of these compounds.Procedures following the ligand exchange of difluoro- 3bromanes with alkynes generally afford the alkenyl- 3 -bromanes in greater yields compared to the alkylation of vinyl bromides.The first fully characterized, stable alkenyl- 3bromanes were prepared by Ochiai, Frohn and colleagues in 2005 from difluoro- 3 -bromanes and the corresponding alkynes (Scheme 18). 52In marked contrast to the Olah's efforts, the prepared (E)--halovinyl(aryl)- 3 -bromanes 14 had much higher thermal stabilities and could even be stored at ambient temperature.

Short Review Synthesis
Scheme 18 The first fully characterized, stable alkenyl- 3 -bromanes prepared by Frohn and colleagues in 2005   In this reaction, exposure of 1-decyne to difluoro- 3bromane (1.5 equiv) and BF 3 .Et 2 O (1.5 equiv) at -78 °C in dichloromethane under argon yielded 62% of -fluoro-1-decenyl- 3 -bromane stereoselectively in an E/Z ratio of 96:4, after repeated decantation with hexane.(E)--Ethoxy (7%) and (E)--chloro-1-decenyl- 3 -bromane (4%) were obtained as by-products.The -ethoxy group originated from BF 3 •OEt 2 , so the formation of -alkyoxybromanes could be limited using the more sterically demanding BF 3 •O(iPr) 2 .Meanwhile, the -chlorodecenyl- 3 -bromane by-product, arising from chloride transfer from the solvent to reactive intermediates, could be minimized by using less nucleophilic solvents like CH 3 Cl or CCl 4 instead of CH 2 Cl 2 .Ochiai and co-workers prepared compound 15 by the ligand exchange of p-F 3 CC 6 H 4 BrF 2 , on the bromine(III) atom, with potassium cyclopentenyltrifluoroborate (5 equiv) in MeCN at low temperature in 61% yield (Scheme 19).18a The resulting bromane does not decompose at room temperature for a short period of time (after 3 days, >92% remains).Complexation of 15 with a crown ether could increase the stability: slow evaporation of a n-hexane/ethyl acetate/dichloromethane solution of a 1:2 mixture of 15 and [18]-crown-6 at 4 °C afforded colorless crystals of a 1:1 complex of 15•[18]crown-6, which were thermally stable and could be left standing under ambient conditions for two weeks.Even though 15 was stable in the solid state, solvolysis took place at room temperature.
Scheme 19 Ochiai and co-workers prepared compound 15 by the ligand exchange of p-F 3 CC 6 H 4 BrF 2 , on the bromine(III) atom, with potassium cyclopentenyltrifluoroborate Latterly, Ochiai et al. reported the first stereoselective synthesis of (E)--alkylvinyl(aryl)- 3 -bromanes via a boron- 3 -bromane exchange reaction (Scheme 20). 53The 1alkenyl- 3 -bromanes with a -fluoro or -chloro group were formed through a stereoselective anti-Markovnikov addition of difluoro- 3 -bromane to terminal alkynes.For instance, the ligand exchange of Frohn's reagent with (E)-1decenyldifluoroborane (generated in situ from the reaction of potassium decenylborate with BF 3 •OEt 2 ) at -78 °C for 1 hour afforded the corresponding (E)-vinyl- 3 -bromane in 85% yield.A series of vinyl- 3 -bromanes could be synthesized in moderate to high yields, but they were thermally labile at ambient temperature and moisture sensitive.However, compound 16 could be stored for several weeks in its solid state at -78 °C.Interestingly, compounds of the type 16 were able to facilitate efficient S N 2 substitution at a vinylic carbon under mild reaction conditions.

Scheme 20
The first stereoselective synthesis of (E)--alkylvinyl(aryl)- 3 -bromanes Weakly nucleophilic anions such as HBF 4 , TfOH and Tf 3 CH could all function as nucleophiles towards the vinyl- 3 -bromanes.For example, the in-plane vinylic S N 2 substitution of (E)-vinyl- 3 -bromanes with potassium bis(triflyl)methanide proceeds to give the (Z)-vinyloxy oxosulfonium ylides 17 exclusively.Noteworthily, (E)--alkylvinyl- 3 -iodanes failed to undergo similar vinylic S N 2 reactions with the same weak nucleophiles, which likely signifies the higher nucleofugality of aryl- 3 -bromanyl groups in comparison to aryl- 3 -iodanyls.In general, all of the significant experimental methods for the preparation of alkenyl- 3bromanes involve difluoro- 3 -bromane as the principal reagent.Clearly, these synthetic methods would benefit from the exclusion of fluorinating reagents in order to increase the safety and synthetic convenience for researchers.Nevertheless, the recently conveyed methods are generally high yielding and give rise to sufficiently stable alkenyl- 3 -bromanes, such that novel and synthetically valuable procedures could be demonstrated.

Scheme 22 The first synthesis of alkynyl- 3 -bromanes
In this reaction, an excess amount of difluorobromane (1.5 equiv) was required.Selective stannane-Br(III) exchange could be achieved with various primary, secondary, and tertiary alkylethynyl stannanes in good yields (76-89%).However, the ligand exchange with phenylethynyl stannane was not successful and gave a tarry matter.Contamination of these oily  3 -bromanes with a small amount (4-9%) of (E)--fluorovinyl- 3 -bromanes was noted in every case.Furthermore, due to their high Michael-accepting ability, these bromanes were relatively labile and gradually decomposed to give p-bromo(trifluoromethyl)benzene upon standing at room temperature.However, they could be handled under air for brief moments at a time.The bromanes were also highly water sensitive: the half-life (t 1/2 ) of 18 in CDCl 3 was decreased from 13 days to just 25 minutes in the presence of a small amount of water.Despite this, full structural conformation of the prepared bromanes was still possible by the complexation of 19 with a crown ether.The slow evaporation of a dichloromethane/diethyl ether (1:1) solution of a 2:1 mixture of  3 -bromane 19 and [18]-crown-6 at 4 °C under argon afforded colorless single crystals of a 2:1 complex that was suitable for X-ray crystallography.Complexation of  3 -bromanes with crown ethers seems to be a valuable technique for stabilizing such structures of this type and has been reported since.As expected, the strong electron-withdrawing nature of the phenyl- 3 -bromanyl moiety combined with the long C-C triple bond length made these alkynyl bromanes highly efficient Michael acceptors.The compounds underwent tandem Michael-carbene rearrangement in the presence of a variety of nucleophiles under mild conditions.For instance, exposing compound 18 to Bu 4 OTs in dichloromethane at room temperature afforded the alkynyl tosylate in 55% yield, alongside the cyclic alkenyl tosylate as a minor product (5% yield).In fact, weakly nucleophilic superacid conjugate bases could also participate as a Michael donor, which cannot be observed in iodine chemistry.Attack of the -acetylenic carbon of 18 by a sulfonate anion generated the alkylidene carbene.A variation of this procedure using alkynyl stannanes as nucleophiles can be used to product polyynes. 56ore recently, Frohn and co-workers accessed alkynyl-(aryl)-and bis(alkynyl)- 3 -bromonium salts starting from aryldifluoro bromanes (Scheme 23). 21,57Firstly, alkynyl-(aryl)bromonium tetrafluoroborates could be obtained in excellent yields by the reaction of p-F 3 CC 6 H 4 BrF 2 with alkynyltrimethyl stannanes bearing electron-rich alkynyl groups under acidic conditions at -70 °C.

Short Review Synthesis
mane 21 in 1,1,1,3,3-pentafluorobutane (PFP), and was isolated as a reasonably stable white solid after removal of all volatiles.In the same fashion, the reaction of trans-pentafluoroprop-1-en-1-yl(difluoro)borane (26) with the same bromane (21) yielded the perfluorinated product 27 with retention of configuration (Scheme 25).Interestingly, this retained configuration is different from the synthesis of [(CF 3 CF=CF) 2 Br][CF 3 CF=CFBF 3 ] by the reaction of a borane and BrF 3 , where partial conversion into the cis-isomer transpires. 21Transformation of the polarizable triple bond in the perfluoroalkynyl moiety, bonded to bromine(III), was possible due to the highly electron-deficient property of the C-C triple bonds.Upon slow addition of weakly nucleophilic hydrogen fluoride at 24 °C to 23, a 38% yield of 24 was obtained after 12 hours.Extension of the reaction time to 60 hours resulted in the isolation of bromopentafluorobenzene and 1H,1H-octafluoropentan-2-one (25), likely caused by the presence of trace amounts of water.Formation of the ketone indicates the enhanced electrophilicity of the perfluoroalkynyl- 3 -bromanes.Despite the proficiency of the methods for the synthesis of alkynyl- 3 -bromanes, they do not comply with contemporary demands for safe and accessible procedures that are required for the widespread utilization of these compounds.In essence, the prerequisite for fluorinating reagents remains prevalent in all methods, including modern-day literature.Certainly, methodology that can avoid the necessary ligand exchange of ArBF 2 , that are typically troublesome to handle, would improve the expediency of such synthetic techniques.

Conclusion Prospects
Unlike hypervalent organo- 3 -iodanes, the chemistry of  3 -bromanes is greatly underdeveloped despite their synthesis being known since 1952.This can be attributed to the limitations in user-friendly synthetic methods for their syntheses, as well as their lack of stability.Consequently, their reactivity profile is largely under-explored in terms of synthetic application.Overall, the progress in the field of hypervalent bromine chemistry is surprisingly slow compared to the rapid growth of hypervalent iodine chemistry.However, the recent breakthroughs reported in this year (2021) certainly simplify the synthesis techniques significantly, and as such improve the accessibility of different hypervalent bromine compounds.We believe this will be pivotal in unfolding their unique reactivities and attracting more research groups to explore the largely uncharted field of hypervalent bromine compounds.