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. 2021 Feb 26;23(6):2007–2012. doi: 10.1021/acs.orglett.1c00136

1,1,4,4-Tetracyanobutadiene-Functionalized Anthracenes: Regioselectivity of Cycloadditions in the Synthesis of Small Near-IR Dyes

Clotilde Philippe , Anh Thy Bui , Sabrinah Batsongo-Boulingui , Ziemowit Pokladek , Katarzyna Matczyszyn , Olivier Mongin , Loïc Lemiègre , Frédéric Paul , Trevor A Hamlin §,*, Yann Trolez †,*
PMCID: PMC8155560  PMID: 33635667

Abstract

graphic file with name ol1c00136_0004.jpg

Two small 1,1,4,4-tetracyanobutadiene-functionalized chromophores were obtained by careful leverage of the regioselectivity of the cycloaddition reaction of tetracyanoethylene with anthracene–ynamide derivatives, inducing either a [2 + 2] or a [4 + 2] Diels–Alder process. DFT calculations unraveled the mechanism of the [2 + 2] cycloaddition–retroelectrocyclization reaction sequence with ynamides and elucidated the differing mechanisms in the two substrates. The synthesized dyes presented panchromatic absorption extending into the near-IR and far-red/near-IR photoluminescence in the solid state up to 1550 nm.

Push–pull chromophores, consisting of electron donor and acceptor groups bridged together by a π-conjugated backbone, are a class of molecules that play a prominent role in organic molecular materials.1 Thanks to their particular arrangement that facilitates intramolecular charge transfer (ICT) interactions, they feature in scores of applications including nonlinear optics (NLO)2 and organic photovoltaics (OPVs).3 This persistently intriguing topic has stimulated the exploration of 1,1,4,4-tetracyanobutadiene (TCBD) derivatives and their chemistry by several groups in the past decade.412 The elegance of their approach stems from the simplicity of its synthetic route: the TCBD motif can indeed be installed via a facile, high-yield, catalyst-free [2 + 2] cycloaddition-retroelectrocyclization (CARE) sequence, using tetracyanoethylene (TCNE) and an electron-rich alkyne,10 thus allowing for practical synthetic strategies such as postpolymerization functionalizations.13 TCBD is now established as a valuable strong electron acceptor group, with a rapidly expanding family of dyes including this motif. Beyond its straightforward incorporation in push–pull chromophores, other advantages of TCBD were put forward: its twisted conformation was shown to increase chromophore solubility and reduce aggregation, thereby improving the poling process efficiency in NLO materials.14 Despite a number of studies that have promisingly demonstrated photoinduced charge separation in TCBD-appended chromophores, fast nonradiative deactivation of the excited state in these molecules constitutes a major drawback to their implementation in optoelectronic applications. As suggested by Armaroli et al., in anilino-TCBDs, torsional motions following photoexcitation give rise to a low-energy twisted intramolecular charge transfer (TICT) state that can deactivate to the ground state through accessible conical intersections.15 As a direct consequence, these molecules are generally nonluminescent and fluorescence that involves a TCBD moiety has seldom been reported.16

In an effort to modify the prototypical anilino-TCBD fragment, our group discovered that ynamides can engage in the [2 + 2]-CARE reaction with TCNE to form a sulfonamido-TCBD motif, producing dyes with markedly altered optoelectronic properties.1719 We recently revealed that such chromophores could exhibit near-infrared (NIR) luminescence in the solid state, extending to 1350 nm.20 This surprising result prompted us to further investigate compounds based on a similar design, i.e. sulfonamido-TCBD-PAH (polycyclic aromatic hydrocarbon). Interestingly, others have also described solid-state fluorescence involving an ICT to TCBD in push–pull chromophores bearing a PAH.21

While examining the structures of photoactive multicomponent systems that integrate TCBD units, one can remark that anthracene is a strikingly rare building block, with only two examples (to the best of our knowledge) bearing a TCBD motif attached to strong electron-donating groups and remote from the anthracene moiety.22,23 A possible explanation is the presence of a competing Diels–Alder (DA) reaction which makes this PAH seemingly incompatible with the [2 + 2]-CARE sequence—a pitfall that was also encountered with other acenes.24 Herein we report a synthetic strategy to overcome this limitation, a complete mechanistic picture by density functional theory (DFT) calculations, and the optical properties of the synthesized molecules A-TCBD and DPA-TCBD (Scheme 1).

Scheme 1. Reaction Pathways for the Synthesis of A-TCBD and DPA-TCBD.

Scheme 1

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We have previously identified the lack of reactivity of the triple bond when the ynamide is grafted to the 9-position of anthracene,18 which prompted us to investigate anthracenes functionalized in a different position. Brominated derivatives 1a and 1b were therefore selected as starting molecules to access 2-substituted anthracenes. Sonogashira cross-coupling with trimethylsilylacetylene and subsequent deprotection gave the precursor compounds 3a(25) and 3b. The terminal alkynes were brominated to afford compounds 4a and 4b in 78% and 70% yield, respectively. The latter underwent copper-catalyzed amidation using Hsung’s conditions,26 leading to ynamides 5a in moderate yield (36%) and 5b in very good yield (89%). Compounds 5a and 5b were then reacted with one equivalent of TCNE. While 9,10-diphenylanthracene derivative 5b yielded DPA-TCBD (62%), compound A-TCBD was not isolated and the DA product 6 was obtained instead (80% yield).

The [4 + 2] cycloaddition of anthracene with TCNE has already been well documented by several groups.2729 The modulation of the equilibrium for addition of TCNE to anthracene by the solvent was discussed by Brown and Cookson and the dissociation was found to be favored in dioxane.30 Furthermore, Sauer et al. demonstrated the recovery of the anthracene addend using a different anthracene derivative to trap TCNE.31 In the light of these studies, we sought to harness the reversibility of the DA reaction by testing various methods for the recovery of the anthracene structure and formation of the TCBD group. When 5a was heated at 80 °C in dioxane in the presence of 1 equiv of TCNE, even though the retro-DA reaction is expected to be feasible under these conditions, the ynamide degraded without significant conversion into A-TCBD. At room temperature, the same reaction led only to cycloadduct 6 in 62% yield. Under UV irradiation (365 nm) in toluene, compound 5a did not provide the [4 + 4] photodimerization product and its degradation was exclusively observed, invalidating the preliminary protection of the 9,10-positions of the anthracene core by formation of a dimer as an alternate strategy. We endeavored to construct the TCBD motif from cycloadduct 6 instead. In the presence of a second equivalent of TCNE, compound 6 was successfully converted into bisadduct 7 in 50% isolated yield. Using 5 equiv of TCNE, 5a could be directly transformed into 7 in a much higher yield (73%) than through the combined two-step procedure (40%). Both cycloaddition products 6 and 7 were moderately stable and decomposed in solution within a few hours. Different conditions for the extrusion of TCNE from the anthracene core were then assessed. When a 0.01 M solution of 7 in dioxane was heated at 80 °C, A-TCBD could be isolated in only 3% yield after 3 h. To inhibit the forward [4 + 2] cycloaddition, rather than another anthracene derivative and DA reaction, 1.5 equiv of commercially available 4-ethynyl-N,N-dimethylaniline 8 were used to scavenge extruded TCNE, considering the known efficiency32 and irreversibility of the [2 + 2]-CARE reaction. Thus, when stirred for 3 h at 80 °C in the presence of 8, a solution of 7 in dioxane provided compound A-TCBD in a satisfactory yield of 76%. The newly synthesized dyes A-TCBD and DPA-TCBD were characterized by 1H and 13C NMR spectroscopy, HRMS, and cyclic voltammetry (Supporting Information).

Density functional theory (DFT) calculations at COSMO(DCM)-BLYP-D3(BJ)/TZ2P using ADF (see the Supporting Information for computational details) were carried out to pinpoint the origin of disparate regioselectivity of 5a and 5b. For the calculations, the tosyl group (Ts) of 5a and 5b was replaced with mesyl group (Ms) and the substrates are denoted as 5a′ and 5b′. The energy profiles associated with the [2 + 2]-CARE and [4 + 2] DA sequences of 5a′ and 5b′ are provided in Figure 1 and are in line with others in the literature.24 It can be seen that 5a′ preferentially reacts via the DA sequence, whereas 5b′ reacts via the [2 + 2]-CARE sequence. The origin of this observed regioselectivity is traced back to the steric bulk at the 9- and 10-position of the anthracene: the unsubstituted 5a′ can facilitate the DA reaction of TCNE at anthracene to afford 6′, whereas the 9,10-diphenylanthracene 5b′ is too sterically demanding for the DA reaction and the [2 + 2]-CARE pathway becomes more energetically viable.

Figure 1.

Figure 1

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(a) Energy profiles (ΔEDCM in kcal mol–1) for the competing catalyst-free [2 + 2] cycloaddition-retroelectrocyclization (CARE, in black) and [4 + 2] Diels–Alder (DA) reactions (in blue) of 5a′ and 5b′ with TCNE; (b) key transition state geometries (in Å) and activation strain analysis (ΔEDCM = ΔEDCM, strain + ΔEDCM, int, in kcal mol–1). All data computed at COSMO(DCM)-BLYP-D3(BJ)/TZ2P.

First, we focus on the reactivity of the unsubstituted anthracene 5a′. The DA sequence of 5a′ (Figure 1a, go left) begins with the formation of a reactant complex 5a′-INT1* that is more stable (from enhanced π–π stacking) than the corresponding complex 5a′-INT1 of the [2 + 2]-CARE pathway. From 5a′-INT1*, the DA reaction proceeds through a concerted asynchronous transition state 5a′-TS1*E = 0.4 kcal mol–1) to afford the experimentally isolated analog 6′. The first step of the [2 + 2]-CARE sequence involves the nucleophilic attack of 5a′ at TCNE, which goes via an unfavorably high energy transition state 5a′-TS1E = 2.6 kcal mol–1) and formation of an unstable zwitterionic intermediate.

Now, we analyze the reactivity of the 9,10-diphenylanthracene derivative 5b′ (Figure 1a, go right). The reactant complex 5b′-INT1* is a resting state on the energy surface and cannot proceed further due to an unsurmountable DA barrier via 5b′-TS1*E = 10.0 kcal mol–1) that goes with a highly destabilizing strain (ΔEstrain = 100.3 kcal mol–1) due to steric clash between TCNE and the phenyl groups at the 9- and 10- positions of the anthracene (Figure 1b). Instead, 5b′-INT1* reversibly dissociates to the reactants and then can form the slightly less stable 5b′-INT1, which undergoes the nucleophilic attack via 5b′-TS1* to generate a metastable zwitterionic intermediate 5b′-INT2. The facile rotation and subsequent cyclization via 5b′-TS2 accomplishes the stepwise [2 + 2] cycloaddition and generates the cycloadduct 5b′-INT3. Retrocyclization via 5b′-TS3 provides the s-cisDPA-TCBD′ which can then isomerize to complete the CARE sequence and furnish s-transDPA-TCBD′.

The UV–vis absorption spectra of A-TCBD and DPA-TCBD were recorded in dichloromethane (Figure 2A). Compared to their ynamide precursors, the clear and characteristic finger-like structured absorption bands of anthracene that were observed between 335 and 400 nm in 5a and 5b are now indistinct. New features arose in both TCBD derivatives, causing their absorption spectra to span the whole visible range. Most remarkably, a very broad and structureless low-energy absorption band, attributed to an ICT transition resulting from interactions between the PAH moiety and TCBD, covers the visible region between 450 and 800 nm, with a maximum located at 527 nm (ε = 3.5 × 103 M–1 cm–1) for A-TCBD and at 557 nm (ε = 4.3 × 103 M–1 cm–1) for DPA-TCBD. Comparison with published data on pyrene and perylene derivatives decorated with a TCBD unit20 reveals a pronounced bathochromic effect as well as a slight hyperchromic effect associated with the increase in the PAH π-conjugation and/or resonance stabilization (Table S2).

Figure 2.

Figure 2

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(A) UV–vis absorption spectra of ynamide precursors 5a and 5b and compounds A-TCBD and DPA-TCBD in dichloromethane. Inset: zoom on the low-energy band of A-TCBD and DPA-TCBD. (B) Normalized photoluminescence spectra of A-TCBD and DPA-TCBD in PMMA (λexc = 500 and 515 nm, respectively), organic glass (MeTHF at 77 K, λexc = 480 and 520 nm, respectively), and powders (λexc = 585 and 600 nm, respectively). The different detectors used are represented as follows. Continuous line: R928; filled symbols: R2658; open symbols: InGaAs.

Finally, the photoluminescence (PL) properties of A-TCBD and DPA-TCBD were examined. As reported with analogous dyes,20 no emission was detected in dichloromethane, but in rigid media, both compounds displayed a very comparable and broad PL band (Figure 2B). In diluted rigid matrices (2-methyltetrahydrofuran at 77 K and PMMA at room temperature, Table S3), where the intermolecular interactions33 are minimized, this band lied between the red and the first near-infrared window (NIR-I, 700–950 nm). Powders of the products exhibited PL in the NIR-I region with a maximum centered at 865 and 875 nm for A-TCBD and DPA-TCBD respectively, and a remarkably long tail extending to 1550 nm in the second near-infrared window (NIR-II, 1000–1700 nm), even farther than the upper limit in pyrene and perylene derivatives (ca. 1350 nm). This PL enhancement in the solid-state can be ascribed to the restriction of molecular motions following light absorption, which helps reduce the nonradiative losses in these environments.21

Besides the successful synthesis of two TCBD-appended anthracene derivatives A-TCBD and DPA-TCBD, our joined experimental and theoretical investigations showed that the regioselectivity of the cycloaddition reaction of TCNE with 5a and 5b, favoring either a [4 + 2] Diels–Alder process with the anthracene core in 5a or a [2 + 2]-CARE reaction with the triple bond in 5b, is dictated by steric effects at the 9,10-positions. DFT calculations uncovered the mechanism of the [2 + 2]-CARE sequence with ynamides for the first time, demonstrating that the reaction proceeds through stepwise [2 + 2] cyclization to produce a cyclobutene intermediate which then opens to give the TCBD moiety. When the DA reaction was preferential, it could advantageously be used to deactivate the 9,10-positions prior to the [2 + 2]-CARE, then its reversibility exploited to unmask the anthracene core thanks to a scavenger. In addition to insight into the reactivity of some π-systems with TCNE, we expect the synthetic method developed to obtain A-TCBD to be applicable to other acene-TCBD targets. Both A-TCBD and DPA-TCBD displayed optical properties that were remarkable for such small dyes. They presented panchromatic absorption in DCM that extends into the NIR-I region, and solid-state PL signals lying between the far-red and the NIR-II range. This latter feature, rare in TCBD-functionalized molecules, thus further substantiates that new molecular designs comprising this fragment can offer room for unusual photophysical properties.34

Acknowledgments

This study is part of the project ANR JCJC Fluotet 17-CE07-0038-01 from the Agence Nationale pour la Recherche. A.T.B. and C.P. thank the Région Bretagne for funding postdoctoral and doctoral grants, respectively. PHC Polonium 37629XG (2017-2018) is aknowledged for funding. The authors would like to acknowledge Dr. Olivier Maury (Laboratoire de Chimie at ENS de Lyon) for access to the Horiba Jobin-Yvon fluorometers. Dr. François Riobé (Laboratoire de Chimie at ENS de Lyon) is also thanked for assistance with the corresponding measurements and fruitful discussions. T.A.H. thanks The Netherlands Organization for Scientific Research (NWO) for support.

Supporting Information Available

The Supporting Information is available free of charge at https://pubs.acs.org/doi/10.1021/acs.orglett.1c00136.

  • General and synthetic procedures, characterization data, cyclic voltammograms, complementary UV–vis and photoluminescence data, excitation spectra, and full computational details (PDF)

The authors declare no competing financial interest.

Dedication

This work is dedicated to the memory of François Diederich.

Supplementary Material

ol1c00136_si_001.pdf (2.9MB, pdf)

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Associated Data

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Supplementary Materials

ol1c00136_si_001.pdf (2.9MB, pdf)

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