Organotellurium-catalyzed oxidative deoximation reactions using visible-light as the precise driving energy

Xin Deng,Rongrong Qian,Hongwei Zhou*,Lei Yu*

a School of Chemistry and Chemical Engineering,Yangzhou University,Yangzhou 225002,China

b College of Biological,Chemical Sciences and Engineering,Jiaxing University,Jiaxing 314001,China

c Jiangsu College of Tourism,Yangzhou 225127,China

ABSTRACT Irradiated by visible light,the recyclable(PhTe)2-catalyzed oxidative deoximation reaction could occur under mild conditions.In comparison with the thermo reaction,the method employed reduced catalyst loading(1 mol%vs.2.5 mol%),but afforded elevated product yields with expanded substrate scope.This work demonstrated that for the organotellurium-catalyzed reactions,visible light might be an even more precise driving energy than heating because it could break the Te--Te bond accurately to generate the active free radical catalytic intermediates without damaging the fragile substituents(e.g.,heterocycles)of substrates.The use of O2 instead of explosive H2O2 as oxidant affords safer reaction conditions from the large-scale application viewpoint.

Keywords:Photocatalysis Tellurium Deoximation Sustainable energy Ketone

Visible light-driven reactions receive comprehensive attention in recent years not only for the mild reaction conditions,but also for the possibility of utilizing sustainable energy in chemical industry production instead of the traditional fossil energy to reduce the CO2emissions[1].A plenty of protocols have been developed for the photocatalysis processes,but many of them are far from the practical applications for some technical defects.For example,the reactions require expensive metal or non-metal catalysts,some of which are high loading and not recyclable[2].The use of stoichiometric/excess photo sensors or additives brings on the reaction waste generation[3].In some reactions,environment-unfriendly solvents containing halogen,nitro,etc.are employed and unavoidable[4].Developing new photocatalytic systems to avoid the above defects is the key for practical applications of related photocatalysis technology in the actual chemical production.

On the other hand,deoximation reaction is an important transformation with great industrial application potential[5].Most oximes are stable crystals with constant melting points,making the oximation-deoximation processes able to be applied in the protection,purification and characterization of carbonyls.The related oximation-deoximation strategies have been widely applied in the total synthesis of natural products and medicines(e.g.,in the total synthesis of erythronolide A by Corey group)[6].In fine chemical production,the deoximation reactions are used to synthesize ketones from non-carbonyl starting materials.For example,the industrial synthesis of high-value-added spice carvone from limonene involves a deoximation step[7].However,the present deoximation techniques require explosive oxidants such as H2O2[8],or use equivalent/excess additives leading to wastes[9],or use the environment-unfriendly solvents[10],or suffer the narrow substrate scope[11],or use the expensive noble metal catalysts[12],or employ the fragile enzyme catalysts that have to be used under dilute conditions restraining the production capacity[13].Recently,people paid much attention to green deoximation technologies using novel catalytic materials[14].In our cases,it was found that the organotellurium compounds are highly active[15]and could catalyze the thermal oxidative deoximation reactions via an unusual free radical mechanism[15a].Herein,we wish to report an advanced low-loading(PhTe)2-catalyzed deoximation reaction with O2using visible light as the precise driving energy.

The benzophenone oxime(1a)substrate and 2.5 mol% of(PhTe)2catalyst were initially mixed together and the reaction was performed under solvent-free conditions.The mixture was irradiated by LEDs blue light and exposed in O2atmosphere.It was a gas-solid reaction and the reaction mixture gradually melted along with the process.The desired product benzophenone(2a)could be obtained in 91%yield after 24 h reaction(Table 1,entry 1).The catalyst loading could be further reduced and using 1 mol%of(PhTe)2was screened out to be the better conditions,affording 2a in 93%yield(entries 3 vs.1,2,4–6).The reactions with solvent were also tested and using MeCN,EtOAc,1,4-dioxane,or acetone could led to excellent product yields,while the protonic solvent EtOH was unfavorable(entries 8 vs.7,9–11).

Table 1 Reaction condition optimization for the(PhTe)2-catalyzed oxidative deoximation of benzophenone oxime(1a).a

A series of oximes were then employed as substrates to test the application scope of the reaction(Table 2).Different to the reaction of 1a,the reaction of di-p-tolylmethanone oxime(1b)required EtOAc solvent,otherwise its speed was very slow and was notcompletely converted within 24 h(entries 2 vs.1).Similarly,the reactions of electron-enriched or deficient diaryl ketones 1c-f occurred in EtOAc solvent,while the solvent-free reaction conditions were not preferable(entries 3–6).For(E)-1-phenylethan-1-one oxime substrate(1g),no reaction occurred without solvent,and only traces of the desired product 2g was obtained in EtOAc solution.Fortunately,it could afford 2g in 82% yield when using MeCN as the reaction solution(entry 7).The product and solvent could be separated via distillation in the 100 mmol reaction,while the residue could be used as the catalyst again and afforded the product without yield decreasing(entry 7).For methyl ketones 1h–k,MeCN solvent was necessary to ensure the generation of related ketones in good yields(entries 8–11).Notably,the substrate 1l bearing bulky substituent 2-C10H7could be smoothly converted to give the desired ketone 2l in 93% yield(entry 12).The reaction was tolerable for NO2and CN substituents in substrates 1m and 1n,affording the desired products 2m and 2n in 75% and 81% yields respectively(entries 13 and 14).Protonic groups such as COOH disturbed the reaction,but the carboxylic COOMe was tolerable(entries 15 vs.16).Since the reaction was performed under oxidative conditions,reductive groups in substrates,such as NH2and SH,were incompatible(entries 17 and 18).Deoximation of aldoximes suffered the poor reaction selectivity caused by the competitive side reactions such as the dehydration and deep oxidation of the products.For example,the reaction of benzaldoxime led to the mixtures of benzaldehyde,benzonitrile and benzoic acid in 16%,23% and 46% yields respectively.

Table 2 Photocatalytic oxidative deoximation reaction with(PhTe)2 catalyst and without solvent.a

In comparison with the previously reported thermo reaction[15a],the photocatalytic reactions of heterocycle-containing oximes 1s and 1t afforded even higher product yields because the mild reaction conditions could significantly restrain the byproduct generation,e.g.,the break of the fragile heterocycles(Table 3,entries 1 and 2).For cyclic ketoximes 1u and 1v,the(PhTe)2-catalyzed thermo reactions resulted in very poor product yields for the higher substrate steric hindrances of the carbocycles preventing the attack of the catalytic Te species from the back side of C=N[15a].Interestingly,the same reactions could be significantly improved by using the photocatalytic protocol,affording the related cyclic ketones 2u and 2v in high yields over 80%(entries 3 and 4).

A series of control experiments were performed to disclose the possible reaction mechanism.They were all catalyzed by 1 mol%of(PhTe)2driven by the LEDs blue light.First,the reaction of 1a under N2protection produced 2a in only 8% yield,indicating that although deoximation process might occur via other methods(e.g.,acid-promoted reaction),the oxidative deoximation reaction was the major process in the presence of(PhTe)2with visible light irradiation(Table 4,entry 1).The reaction,despite the solvent-free reaction or the reaction in EtOAc solvent,were both restrained by TEMPO(i.e.,2,2,6,6-tetramethylpiperidine-1-oxyl),a common free radical scavenger(entries 2 and 3).Comparison of the results in Table 4,entries 4 vs.5 showed that the free radical initiator AIBN(i.e.,azodiisobutyronitrile)could promote the reaction with 1 mol%of(PhTe)2under visible light irradiation under O2.Therefore,it could be concluded that the visible light promoted oxidative deoximation reaction occurred via the free radical reaction mechanism.Moreover,without(PhTe)2or kept in dark,the deoximation could not occur,showing that both(PhTe)2and visible light irradiation were necessary for the transformation.

XPS(i.e.,X-ray photoelectron spectroscopy)analysis of the reaction mixture could provide additional information on the element valences.To prepare the test sample,silica was added into the reaction liquid as an adsorbent and the solvent was then removed by distillation with an evaporator.Spectrum of the residue indicated that Te was completely oxidized into Te4+afterthe reaction(Fig.S1a in Supporting information),while ca.43%of nitrogen from the oxime group existed in the nitrate(NO3-)form(Fig.S1b in Supporting information).Interestingly,the low-valent N–O species was also observed in the XPS spectrum,attesting the existences of the intermediate HNO species,which was difficult to capture for its high reducibility in the previous studies[16].Owing to the mild oxidation condition of this reaction,partial of the active low-valent HNO species could be reserved.The mild reaction condition also led to the high product yields by restraining the byproduct generation,especially for the substrates bearing the fragile heterocyclic substituents(Table 3,entries 1,2).

Table 3 Comparison of the photocatalytic reaction vs.thermo reaction of heterocyclic containing and cyclic ketoxime substrates.

Table 4 Control experiments.a

On the basis of the above experimental results as well as the literature reports[15a,17–19],a plausible mechanism of this photocatalytic oxidative deoximation reaction was supposed(Scheme 1).First,as a brown color chemical,(PhTe)2could well absorb the visible light to utilize its energy like(PhSe)2[17].The process was even easier to occur than(PhSe)2for the weaker Te--Te bond[17c].The visible light-driven homolytic cleavage of Te-Te bond in(PhTe)2produced the benzenetellurol radical 3(Scheme 1),which was highly active and could be oxidized into the high valent benzenetellurinic acid radical 4,as being reflected by the XPS analysis(Fig.S1a)[15a,18].The addition of 4 to oxime 1 led to the intermediate 5(Scheme 1).The process occurred via the free radical attack of 4 from the back side of C=N in oxime,which might be retarded when using cyclic oxime substrates bearing large steric hindrances such as 2o and 2p under thermo reaction conditions(Table 3,entries 3,4).The decomposition of 5 produced the product 2,the phenyltellanol radical 6 and the HNO species[19].Oxidation of 6 led to the radical 4 and restarted the catalysis circle,while HNO might be oxidized into NO3-(Scheme 1).

Scheme 1.Possible mechanism of the(PhTe)2-catalyzed oxidative deoximation reaction driven by visible light.

In conclusion,we found that being irradiated by visible light,the(PhTe)2-catalyzed oxidative deoximation reaction could occur under mild conditions.In comparison with the previously reported thermo reaction,this work not only provided a better method using reduced catalyst loading and affording elevated product yields with expanded substrate scope,but also demonstrated that for organotellurium-catalyzed reactions,visible light might be an even more precise driving energy than heating.Tellurium was the catalytic centre for the oxygen transfer reaction like selenium[20],but did not require metal additives to utilize molecular oxygen as oxidant[21],while the visible light irradiation could precisely break the Te--Te bond to generate the active free radical catalytic intermediates,and the fragile substituents,e.g.,heterocycles,in substrate could be well tolerated to reduce the side reactions.Further investigations on the applications of chalcogen-containing compounds/materials are ongoing in our laboratory[22].

Declaration of competing interest

The authors report no declarations of interest.

Acknowledgments

We thank the Natural Science Foundation of Jiangsu Province(No.BK20181449),Natural Science Foundation of Zhejiang Province(No.LY19B020004),Jiangsu Provincial Six Talent Peaks Project(No.XCL-090)and Priority Academic Program Development of Jiangsu Higher Education Institutions(PAPD)for financial support.

Appendix A.Supplementary data

Supplementary material related to this article can be found,inthe online version,at doi:https://doi.org/10.1016/j.cclet.2020.09.012.