DOI:
10.1039/D1QO00538C
(Research Article)
Org. Chem. Front., 2021,
8, 2893-2902
Self-assembled luminescent Cu(I) tetranuclear metallacycles based on 3,3′-bipyridine ligands†
Received
7th April 2021
, Accepted 11th May 2021
First published on 17th May 2021
Abstract
3,3′-Bipyridine ligand B was reacted with pre-assembled [Cu2(μ2-dppm)2] Cu(I) bimetallic flexible precursor A according to coordination-driven supramolecular chemistry synthetic principles. Outcomes obtained revealed the necessity to formally introduce bridging halide X ions (X = Cl, Br or I) in order to conduct selectively and successfully coordination-driven supramolecular syntheses. Therefore, [Cu2(μ2-dppm)2(μ2-X)] bimetallic connecting nodes presenting a potential coordination angle of ca. 120° are generated, which lead upon reaction with connecting ligand B to the selective formation of new tetranuclear metallacycles CX. These derivatives are luminescent in the solid-state at room temperature with high emission quantum yields and a study of the temperature dependence of their photophysical properties was conducted, suggesting a ligand B centered triplet origin for their luminescence.
Introduction
A fruitful and appealing alternative to classic synthetic methodologies for constructing complex discrete molecular scaffolds consists of the application of supramolecular self-assembly procedures.1 In these approaches, the spontaneous recognition of rationally designed individual building blocks occurs, affording selectively well-defined discrete supramolecular architectures. These self-assembly processes are promoted by non-covalent kinetically labile bond formations, which take place along self-sorting and self-correction events until the individual building blocks gather into the final thermodynamically stable target product. Considering in this context the use of the metal–ligand coordination interaction, a plethora of multimetallic supramolecular assemblies have blossomed in the last decade,2,3 in particular according to coordination driven supramolecular (CDS) chemistry synthetic principles.3 CDS processes rely on the use of pre-organized coordination complexes having predefined geometries (being in most cases hardly accessible from a single metal center coordination sphere) and vacant coordination positions.3 These pre-organized precursors, obtained from the reaction of metal ions with specific assembling ligands, are associated with connecting polytopic ligands allowing the formation of targeted multimetallic derivatives whose sizes and geometries are controlled by the symmetry of the linking sites of the individual building blocks. According to this synthetic approach, a variety of attractive multifunctional molecular devices or metallacages bearing remarkable ability for the selective encapsulation of certain guest species and/or original reactivity within their internal confined spaces could thus be prepared.3 Within the intricate CDS polymetallic assemblies reported, metallo-macrocycles are omnipresent. They constitute either the targeted scaffolds or serve as sub-units for the construction of more elaborated molecular architectures. So far, CDS systems based mostly on the Pt(II) and Pd(II) metal centers have been flourishing.2n–u,3a–d,4 Indeed, these ions combine strong preferences for a rigid square planar coordination sphere and highly directional thermodynamically stable but kinetically labile metal–ligand interactions with a large range of ligating coordination groups, which are key factors to ensure the success of CDS synthetic processes. Yet, in recent years, alternatives to these leading trends have appeared allowing the introduction of a larger variety of metal centers and ligating groups.5
Thus, we have recently initiated the introduction of pre-assembled Cu(I) precursors such as the [Cu2(μ2-dppm)2]2+ bimetallic fragment A (Scheme 1a, dppm = bis(diphenylphosphino)methane) in self-assembly procedures related to CDS syntheses.6 In these cases, the typical labile, flexible and low-directional coordination sphere of this ion, initially regarded a priori as strongly restrictive in conventional CDS chemistry, turned out to be very valuable to conduct the selective preparation of original CDS assemblies based on the Cu(I) ion. In addition, the obtained polymetallic derivatives present a variety of luminescence properties7 due to the versatile photophysical processes lying in Cu(I)-based derivatives (such as Thermally Activated Delayed Fluorescence (TADF)),7a,c drawing new perspectives in the ready design of innovative and inexpensive luminescent supramolecular compounds. Very importantly, these previous studies highlighted a win–win situation, promoting the introduction of Cu(I) metal centers in attractive luminescent CDS assemblies. Indeed, on the one hand, the integration of the Cu(I) ions within CDS intricate scaffolds bearing multiple chelates and metallacycle sub-units endows this Cu(I)-based species with significant thermodynamic stability. Therefore, selective self-assembly processes toward a single product can be directed in solution. This is a marked contrast compared to the multiple equilibria typical of the fluxionality of Cu(I) metal centres’ coordination spheres that can govern the conventional solution coordination chemistry of the Cu(I) ion and frequently result in unpredictable mixtures of hetero- and homoleptic structures.8 Moreover, this has allowed establishing that due to a suitable molecular design of pre-assembled Cu(I) polymetallic building blocks, it is possible to proceed to the rationalization of the adaptative behaviors exhibited by the intrinsically conformationally flexible polymetallic Cu(I) precursors used.6a,c On the other hand, in these CDS assemblies, the Cu(I) metal centers are embedded within polycyclic supramolecular scaffolds having constrained geometries. These metal centers are thus subject to the significantly reduced possibility of structural re-organization of their coordination sphere in the excited states. Therefore, the non-radiative deactivation pathways associated with such re-organization are greatly minimized within Cu(I)-based CDS assemblies which promotes the emergence of enhanced photophysical properties in such self-assembled derivatives.
|
| Scheme 1 a) Synthesis of derivatives Cx; (b) schematic representation of derivatives Cx. | |
Taking these observations into consideration, we have been motivated to explore further the use of CDS chemistry for the selective preparation of new luminescent Cu(I) metallacycles. Herein, we describe the one-step preparation of three new tetranuclear dicationic discrete metallacycles CX (X = Cl, Br, I). Their synthesis, characterization, X-ray single crystal molecular structure and solid-state luminescence properties are reported.
Results and discussion
While previous preparation of Cu(I)-based CDS luminescent assemblies mostly focused on the use of cyano-based inorganic linkers6 and nitrile-terminated organic ditopic ligands,9 we have been interested to extend these investigations to the reaction of the pre-organized [Cu2(μ2-dppm)2]2+ bimetallic fragment A with pyridyl-terminated organic ligands. Indeed, such electron-rich nitrogen-donor polytopic linkers predominate in CDS syntheses due to the strong affinity of these moieties toward a large variety of metal ions and due to the high directionality of the coordination bonds formed. In this study, we have focussed more particularly on the use of the ditopic 3,3′-bipyridine ligand B since it was demonstrated that bis-monodentate ligands bearing the 3-pyridyl moiety as a coordinating group present a strong tendency to form discrete polycyclic CDS-assemblies.2d,u,v,3e,4b Moreover, luminescent Cu(I) coordination polymers have been previously reported bearing B as the connecting ligand between the metal centers,10 demonstrating the appealing photophysical properties that can arise from the association of Cu(I) metal centers with B. In the course of this study, we have observed that it is mandatory to introduce an additional μ2-bridging halide anion on the Cu(I) bimetallic unit of the pre-assembled [Cu2(μ2-dppm)2]2+ precursor, in order to prepare selectively new Cu(I) discrete polymetallic derivatives. Indeed, when one equivalent of the in situ formed [Cu2(μ2-dppm)2]2+ unit was reacted in CH2Cl2 under air at room temperature (RT) with one equivalent of ligand B a colourless clear solution was obtained. The slow diffusion of pentane vapors in this solution afforded after a few days a mixture of different colourless polycrystalline species having a significantly distinct eye-perceived luminescence color under UV-Vis light excitation (λex = 365 nm), ranging from blue-green to yellow. Unfortunately, the quality of these crystallites and their very low stability once removed from the mother solution did not allow us to determine their X-ray crystal structures. It was also not possible to purify these species via manual separation since the crystals collapsed in polycrystalline powder very quickly once removed from the mother solution. Yet, after a few weeks, we observed that a small amount of well-shaped new colorless crystals of the species CCl appeared in the crystallisation experiments. These crystals display at RT in the solid state an eye-perceived blue-cyan intense luminescence upon UV-Vis light excitation (λex = 365 nm) and could be successfully collected in order to establish the solid-state molecular structure of CCl, thanks to a single crystal X-ray diffraction study experiment performed at low temperature. It revealed that this compound crystallizes in the triclinic space group P (Table 1) with an asymmetric unit containing half of the discrete supramolecular assembly CCl, one hexafluorophosphate counter-anion and five disordered CH2Cl2 solvent molecules. The derivative CCl is a centrosymmetric dicationic tetrametallic metallacycle (Scheme 1b, Fig. 1) resulting from the connection of two [Cu2(μ2-dppm2)(μ2-Cl)]+ dimeric units by two B ligands acting as ditopic linkers. The metal centers present similar P2Cl1N1 distorted tetrahedral coordination spheres (Table 2) and, compared to the other Cu(I) polymetallic assemblies based on this bimetallic unit, the overall metric data at the [Cu2(μ2-dppm)2] sub-unit are classical.6,9 Yet, the intermetallic distance is quite large (d(Cu–Cu) = 3.179(7) Å, above the limit usually proposed for cuprophilic interactions)11 as a result of the presence of a μ2-symetrically bridging chloro ligand (d(Cu–Cl) = 2.4034(12) and 2.4048(11) Å). Within assembly CCl, the two μ2-chloro ligands (separated by ca. 4.55 Å) are located toward the center of the metallacycle and are orientated slightly outward of the mean plane defined by the four Cu(I) ions (deviation to the mean plane: 0.753 Å). The coordination of ligands B on the two metal centers of the bimetallic units is also highly symmetrical with similar (Cu–Cu–N) angles (150.21 and 150.34°) and (Cu–N) bond lengths (both being 2.121(3) Å). The torsion angle between the two 6-membered rings of coordinated ligands B is 17.2° (Fig. 2c), which is significantly smaller than the torsion angle (43.6°) found in the previously reported Cu(I) 1D-CP based on ligand B, in which in addition shorter (Cu–N) bond lengths have been observed (d(Cu–N) = 2.034(3) Å).10 This highlights the steric constraints applied on the backbone of coordinated ligands B within the metallacyclic scaffold of CCl.
|
| Fig. 1 (a) Views of the molecular X-ray structures of dicationic metallacycle CCl (counteranions, H atoms and solvent molecules have been omitted for clarity). | |
|
| Fig. 2 Views of the molecular X-ray structures (counteranions, H atoms and solvent molecules have been omitted for clarity) of the dicationic derivatives (a) CBr and (b) CI; (c) simplified ‘lateral’ views of the X-ray structures of metallacycles CCl, CBr and CI. | |
Table 1 Crystal data and structural refinement of derivatives CCl, CBr and CI after squeeze treatment (values in italics are related to the relevant data before the squeeze treatment)
|
CCl
|
CBr
|
CI
|
Molecular formula |
C120H104Cl2Cu4F12N4P10(C130H112Cl22Cu4F12N4P10) |
C120H104Br2Cu4F12N4P10(C130H112Br2Cl20Cu4F12N4P10) |
C120H104I2Cu4N4P8(C132H98I2Cl24Cu4F12N4P10) |
CCDC |
2074606 |
2074608 |
2074607 |
Molecular weight |
2464.83 (3302.00) |
2553.75 (3390.92) |
2357.79 (3636.60) |
a (Å) |
14.113(2) |
14.182(3) |
14.308(2) |
b (Å) |
14.181(2) |
14.237(3) |
14.297(2) |
c (Å) |
18.602(2) |
18.585(3) |
18.459(2) |
α (°) |
87.110(4) |
87.431(6) |
68.40156 |
β (°) |
69.039(4) |
69.448(5) |
87.648(5) |
γ (°) |
84.128(4) |
84.493(6) |
85.23156 |
V (Å3) |
3458.0(8) |
3497.2(12) |
3498.7(3) |
Z
|
1 |
1 |
1 |
D
c (g cm−3) |
1.184 (1.586) |
1.213 (1.610) |
1.119 (1.726) |
Crystal system |
Triclinic |
Triclinic |
Triclinic |
Space group |
P |
P |
P |
Temperature (K) |
150(2) |
150(2) |
150(2) |
Wavelength Mo-Kα (Å) |
0.71069 |
0.71069 |
0.71069 |
Crystal size (mm) |
0.35 × 0.28 × 0.11 |
0.45 × 0.11 × 0.09 |
0.16 × 0.11 × 0.07 |
μ (mm−1) |
0.819 (1.215) |
1.343 (1.734) |
1.171 (1.682) |
F(000) |
1260 (1668) |
1296 (1704) |
1194 (1806) |
θ limit (°) |
2.02–27.57 |
2.19–27.63 |
2.17–27.55 |
Index ranges hkl |
−18 < h < 18 |
−18 < h < 18 |
−18 < h < 18 |
−17 < k < 18 |
−18 < k < 15 |
−17 < k < 18 |
−24 < l < 24 |
−24 < l < 24 |
−23 < l < 23 |
Reflections collected |
70583
|
55169 |
56861 |
Independent reflections |
15920
|
15866 |
15846 |
Reflections [I > 2σ(I)] |
12697 (12710) |
12432 (12827) |
10729 (10872) |
Data/restraints/parameters |
15920/0/719 (15920/0/854) |
15866/0/709 (15866/0/854) |
15846/0/622 (15846/0/875) |
Goodness-of-fit on F2 |
1.088 (1.058) |
1.088 (1.042) |
1.105 (0.988) |
Final R indices [I > 2σ(I)] |
R
1 = 0.0680 (0.0891) |
R
1 = 0.0852 (0.1127) |
R
1 = 0.0857 (0.1143) |
wR2 = 0.1995 (0.2353) |
wR2 = 0.2290 (0.2853) |
wR2 = 0.2219 (0.2866) |
R indices (all data) |
R
1 = 0.0802 (0.1082) |
R
1 = 0.1009 (0.1329) |
R
1 = 0.1188 (0.1607) |
wR2 = 0.2110 (0.2568) |
wR2 = 0.2418 (0.3035) |
wR2 = 0.2413 (0.3248) |
Largest diff peak and hole (e Å−3) |
1.483 and −1.383 (2.209 and −1.730) |
2.452 and −1.635 (4.816 and −1.559) |
2.247 and −1.797 (3.434 and −1.857) |
Table 2 Selected intermetallic distances [Å] and angles [°] in derivatives CCl, CBr and CI
|
CCl
|
CBr
|
CI
|
Cu–Cu |
3.180(4) |
3.261(5) |
3.362(5) |
Cu–N |
2.121(3) and 2.121(3) |
2.109(4) and 2.121(5) |
2.119(6) and 2.124(5) |
Cu–X |
2.4034(12) and 2.4048 (11) |
2.5218(11) and 2.5211(10) |
2.6646(11) and 2.6636(12) |
Cu–P |
2.2687(10), 2.2569(10), 2.2604(11) and 2.2527(11) |
2.2682(15), 2.2567(14), 2.2595(16) and 2.2546(16) |
2.2474(17), 2.2576(16), 2.2549(19) and 2.2539(19) |
Cu–Cu–N |
150.25(3), 150.37(4) |
150.76(5), 150.27(6) |
151.51(5), 151.15(5) |
Cu–X–Cu |
82.80(3) |
80.58(2) |
78.24(3) |
The origin of the bridging μ2-chloro ligand probably arises from slow chloride abstraction from CH2Cl2 solvent molecules under the crystallization conditions applied. Similar examples that involve chloride abstraction have also been observed for the preparation of other multi-nuclear copper complexes.12 Yet, considering the very slow crystallisation process of the metallacycle CCl, it is very likely that equilibria occur in the crystallisation tubes in which reactive secondary species are able to trap chloride atoms arising from CH2Cl2 solvent degradation. Indeed, after two additional months, the amount of crystals of CCl did not increase significantly, precluding further characterisation of this metallacycle at that stage.
Yet, this result suggests that the introduction of a μ2-bridging chloro ligand on the [Cu2(μ2-dppm)2]2+ building unit could favour the preparation of stable metallacyclic species based on ligand B, by forcing this conformationally flexible [Cu2(μ2-dppm)2]2+ fragment to adopt a suitable geometry promoting selective self-association processes.
In order to confirm this assumption, a CH2Cl2 solution of one equivalent of [Cu((CH3)CN)4]PF6, one equivalent of CuCl and two equivalents of the dppm ligand was prepared (Scheme 1a) and left upon stirring at room temperature (RT) under air for one hour, affording a colorless solution. To this solution one equivalent of ligand B dissolved in CH2Cl2 was added, leading to a slightly yellowish colored clear solution that was left upon stirring at RT overnight. The crude solution was then left to crystallize under air at RT upon pentane vapor diffusions. After one week a homogeneous batch of well-shaped single crystals was obtained, which were identified by a single crystal X-ray diffraction study as crystals of metallacycle CCl. After filtration, the sample was dried affording a homogeneous sample of a block-shaped colorless polycrystalline solid of Ccl with a yield of 66%.
Thus, the presence of chloride anions in the synthesis conducted induces complete alteration of the self-assembly processes occurring as the pre-assembled [Cu2(μ2-dppm)2]2+ precursor is reacted with ligand B. Indeed, instead of a mixture of unidentified species obtained in the first step, followed by a very slow and low-efficient conversion to derivative CCl, this metallacycle can be directly and selectively obtained in good yield if CuCl is introduced in the reaction. Along this synthetic procedure, formally, a [Cu2(μ2-dppm)2(μ2-Cl)]+ moiety can be considered as being formed as a pre-assembled building unit. Such an in situ formed precursor presents very likely a significantly restricted degree of conformation freedom compared to the [Cu2(μ2-dppm)2]2+ fragment since the μ2-bridging chloro ligand locks the geometry of the bimetallic unit. This results in the formation of a bimetallic rigid [Cu2(μ2-dppm)2(μ2-Cl)]+ connecting node bearing potentially two available coordination positions (one on each metal center) with a coordination angle of ca. 120°. In such a situation, selective CDS assembling processes take place along which ligand B is forced to adopt a N,N cisoid orientation of its two 3-pyridyl fragments resulting in the ready and selective formation of the metallacycle backbone of CCl.
Importantly, this approach affording new Cu(I) CDS metallacyles is not only restricted to the introduction of a μ2-bridging chloro ligand on the Cu(I) bimetallic building blocks. Using CuBr or CuI instead of CuCl (Scheme 1a), new metallacycles CBr and CI could also be obtained selectively according to a similar synthetic procedure. X-ray diffraction studies revealed that the crystals of these compounds are isostructural with those of CCl (Table 1), gathering two [Cu2(μ2-dppm)2(μ2-X] (X = Br or I) bimetallic building blocks in the tetrametallic metallacycle via their coordination with two B ligands (Fig. 2a and b). Within these dicationic assemblies, the intermetallic distance increases (CBr: 3.261(8) Å; CI: 3.362(7) Å) with the atomic radius of the bridging halide atom but the μ2-symetrically bridging coordination mode is preserved along the series (CBr: d(Cu–Br) = 2.5211(10) and 2.5218(11) Å; CI: d(Cu–I) = 2.6636(12) and 2.6646(11) Å, Table 2). Inside these metallacycles, the deviations of the μ2-bridging halide ions from the mean plane defined by the four Cu(I) ions (CBr: 0.812 Å; CI: 0.884 Å) are similar to the value found in derivative CCl. Regarding the coordination displayed by connecting ligands B, moderate differences are observed along the series of the three derivatives Ccl, CBr and CI, in which the (Cu–Cu–N) angles are also symmetrical (150.27° and 150.76° in CBr; 151.15° and 151.51° in CI). The (Cu–N) bond lengths are 2.109(4) Å and 2.121(5) Å in CBr and 2.119(6) Å and 2.124(5) Å in CI and therefore do not significantly differ from the values observed in CCl (Table 2). Finally, the torsion angle between the two rings of the coordinated ligands B is 15.9° in CBr and 9.8° in CI (Fig. 2c), confirming thus that ligands B within these assemblies are forced upon coordination to present a remarkable planarity whose extent is enhanced as the μ2-symetrically bridging ligand changes from chloride to bromide and to iodide. Therefore, in the molecular structure of a series of tetrametallic metallacycles Cx (X = Cl, Br, I), the variation of the nature of the μ2-bridging halide mostly affects the metric data at the Cu(I) dimer and the conformation presented by ligands B, but the gross molecular structures are similar. Interestingly, a related Cu(I) complex of tetramesityl substituted ferrocene bisphosphine [Fe(CpPMes2)2*(CuBr)2]2, which presents a comparable metallacyclic structure in which Cu(I) dimers are bridged by μ2-bromide atoms, was recently described by Pietschnig et al.13 In this derivative, the intermetallic distance in the Cu(I) dimer (d(Cu–Cu) = 2.93 Å) is shorter than that in CBr and the deviations from the mean plane defined by the four Cu(I) ions of 1.135 Å are significantly larger than those observed in CBr suggesting overall larger steric constrains within this metallacycle core.
The crystals of CCl, CBr and CI are colorless under visible light and display under UV irradiation (λex = 365 nm) eye-perceived light blue-cyan solid-state RT luminescence. The solid-state RT UV-visible absorption spectra of derivatives CCl, CBr and CI (Fig. S10–12†) exhibit a strong and broad absorption band in the near UV region centered at ca. 300 nm, typical of π–π* transition centered on the aromatic rings of dppm and ligands B. The excitation spectra (Fig. S4–S6†) of these compounds reveal two maxima at ca. 325 nm and ca. 370 nm. In their emission spectra, derivatives CCl, CBr and CI display at 300 K a broad featureless band centered at λmax = 475, 476 and 464 nm respectively (Fig. 3 and Table 3).‡ In the solid state, these compounds present RT lifetimes of the excited state of 74 μs, 119 μs and 70 μs and their RT emission quantum yields (EQYs) reach 80%, 60% and 54% for CCl, CBr and CI respectively.§ Such solid-state RT EQY values are remarkably high for derivatives bearing RT lifetimes whose values of several tenths of microseconds indicate a triplet origin for the luminescence observed. Moreover, the RT EQY value progression is reversed compared to the increase of the atomic number of the μ2-bridging halide ligand. This is quite unusual in luminescent Cu(I)-halide derivatives in which the increment of the spin–orbit coupling associated with heavier halides usually promotes efficient radiative relaxation processes via external heavy-atom effects. To gain more insights into the emission properties of derivatives CCl, CBr and CI, temperature dependent photophysical characterization was conducted upon cooling the temperature from 300 K to 80 K. In the emission spectra of CCl under excitation at 325 nm,‡ a gradual and very moderate red-shift (Fig. 3) of the large band observed upon cooling at 300 K (λmax = 475 nm) is observed with a net increase of the signal intensity. This intensity enhancement is accompanied at the lowest temperature by progressive structuration of the emission band yielding at 80 K a large signal bearing an apparent vibronic sub-structure with two maxima centered at 432 and 484 nm (for which is observed the highest intensity signal) and three shoulders at 452, 465 and 502 nm (Table 3). Regarding the thermal variation of the lifetimes of the excited state of CCl, a continuous and significant increase of the decay time is observed upon cooling, reaching 4.3 ms at 80 K (Fig. 3, Table 3).§ Comparable temperature dependent profiles are observed for the emission spectra and the lifetimes of the excited state of CBr and CI (Fig. 3 and Table 3). In comparison, the low temperature emission spectrum of free ligand B (Fig. S16†) is characterized by a large unstructured band centred at 455 nm (λex = 320 nm) associated with a considerably shorter decay time of the excited state (4.5 ns) at 80 K, typical of purely organic fluorescence. Note that in the temperature dependent emission spectra of derivative CBr (Fig. 3) a weak and large additional band appears between 375 and 425 nm associated with a decay time of the excited state of 3.5 ns that can likely be assigned to the residual ligand centred luminescence.
|
| Fig. 3 Temperature dependence (80 K to 300 K) of the solid-state emission spectra of metallacycles CCl, CBr and CI upon excitation at 325 nm.‡ Inset: plot of their emission decay lifetime against temperature (80 K to 300 K). | |
Table 3 Photophysical data ((λex = 325 nm) for derivatives CCl, CBr and CI at 298 K and 80 K in the solid state
|
λ
ema (nm) |
Φ
em
|
τ
obsa (μs) |
k
rb (s−1) |
k
nrc (s−1) |
Data recorded at 80 K are given in parentheses.
k
r = Φem/τobs.
k
nr = (1 − Φem)/τobs; s: shoulder.
|
CCl
|
475 (432, 452,s 465,s 484, 502s) |
80 |
74 (4315) |
1.1 × 104 |
2.7 × 103 |
CBr
|
476 (432, 452, 464, 484,s 500s) |
60 |
119 (7660) |
5.0 × 103 |
3.4 × 103 |
CI
|
464 (432, 452,s 462, 486, 50s) |
54 |
70 (5881) |
7.7 × 103 |
6.6 × 105 |
The values of the recorded emission lifetimes clearly indicate a triplet origin of the luminescence arising from these Cu(I) metallacycles and, together with the general thermal variation of the profiles of the emission spectra, preclude to suggest a TADF process to explain the overall temperature-dependent data collected for the photophysical properties of these three metallacycles, in spite of the high RT EQY measured.
Regarding specifically the RT photophysical behaviors for this series of metallacycles, the kr radiative rate constant values are in agreement with 3MLCT phosphorescence in which the high temperature large emission bands can be assigned to radiative processes involving likely electronic densities located on 3,3′-bipyridine ligands B. Yet, the large enhancement of the decay times of the excited states as the temperature decreases, together with the vibronic structuration that appears in the low temperature emission band, suggests at low temperature 3π–π* 3ILCT phosphorescence centered on the connecting ligands B. Such a vibronic structuration is indeed not observed in the thermal variation of related TADF luminescent polymetallic supramolecular assemblies based on the [Cu2(μ2-dppm)2] moiety and cyano-based connecting inorganic ligands,6b–d in which radiative processes mostly rely on transitions from the highest occupied molecular orbitals (HOMOs), being metal-cyano antibonding, to the lowest unoccupied molecular orbital (LUMO) having MLCT character involving the four metal centres of the metallacycle and the dppm ligands. Conversely, in a 1D-coordination polymer based on related [Cu2(μ2-dppm)2(μ2-OH2]2+ dicationic fragments connected by 1,4-dicyanobenzene connecting ditopic ligands,9d similar progressive structuration of the emission band is observed upon cooling the temperature. In the case of this 1D-coordination polymer, the low temperature photophysical properties were assigned to 1,4-dicyanobenzene ligand-centered 3π–π* phosphorescence which supports the activation of such radiative processes in the low temperature luminescence properties of derivatives CCl, CBr and CI. Considering these observations, it is likely that purely ligand-centered 3π–π* phosphorescence occurs at low temperature and tends to vanish at higher temperatures due to a thermally activated interconversion between 3ILCT and 3MLCT states.8,14
Interestingly, it is worth noting that only a minor contribution of the orbital lying on the semi-bridging aqua ligand μ2-OH2 was observed in the electronic excitation process in the previously reported 1D-coordination polymer based on the [Cu2(μ2-dppm)2(μ2-OH2]2+ dicationic unit and the 1,4-dicyanobenzene connecting ditopic ligand.9d Regarding the similarities in the local molecular structures of the Cu(I) dimer in this coordination polymer and the metallacycles reported herein ([Cu2(μ2-dppm)2(μ2-OH2]2+ fragments versus [Cu2(μ2-dppm)2(μ2-X2]+ moieties, X = Cl, Br, I), a similar electronic structure could explain the relatively low and unusual impact of the variation of the μ2-bridging halide atom on the photophysical properties of metallacycles CCl, CBr and CI. Unfortunately, the computational cost of the full TD-DFT geometry optimizations of the excited states of large assemblies CCl, CBr and CI studied here, which would allow gaining deep insights into the photophysical mechanisms, revealed to be too prohibitive to be conducted along this study. In this context, it is not straightforward to account for the origin of the high solid-state RT EQY exhibited by these metallacyclic triplet luminophores. It was previously observed that the overall multicyclic networks built in such Cu(I)-based CDS assemblies clearly induce structural constraints that significantly hamper highly detrimental non-radiative relaxation pathways and structural re-organisation in the excited states. The RT values of the knr non-radiative rate constants in this series of metallacycles reveals that non-radiative decays are quite small and more effectively suppressed in the case of lighter bridging halides. This may be related to backbones bearing shorter intermetallic distances. Indeed, on the one hand, this might be responsible for the overall lower degrees of conformational flexibilities allowed in the solid state in more compact and rigid assemblies. On the other hand, shorter intermetallic distances associated with lighter bridging halides also induce higher spin–orbit coupling constants6b which impact the electronic processes, facilitating radiative de-excitation pathways. This is supported by the higher kr radiative rate constant values obtained for the μ2-Cl bridged derivative CCl (Table 3). Therefore, varying the nature of the bridging halides in this family of metallacycles leads to a dual effect, favouring the lighter halide regarding both radiative and non-radiative processes for the exaltation of the solid-state luminescence properties.
Finally, the pronounced planarity observed in the solid-state for 3,3′-bipyridine ligands B in CCl, CBr and CI reveals that the coordination of these ditopic ligands on the [Cu2(μ2-dppm)2(μ2-X)]+ units locks their conformation within these self-assembled metallacycles in an arrangement that promotes an efficient overlap of the π-orbitals along the quasi-planar backbones of ligands B. This induces the stabilization of the molecular orbitals located on these 3,3′-bipyridine ligands in CCl, CBr and CI and supports the assumptions that 3MLCT and 3ILCT phosphorescence radiative relaxation processes occur in these metallacycles being based on molecular orbitals lying at least partially on connecting ligands B. Very likely, such conformational constrains applied on coordinated ligands B in derivatives CCl, CBr and CI contribute to the differences observed between the photophysics of these metallacycles and those of the previously reported luminescent Cu(I) coordination polymer bearing 3,3′-bipyridine ligands in a twisted conformation.10 Indeed, in the latter case, it was concluded that the recorded emission could be attributed to the delayed fluorescence from the 1(M + X)LCT excited state at RT and changed to simple phosphorescence from the same triplet excited state at 77 K, suggesting radiative relaxation processes involving a larger contribution of molecular orbitals centred on the inorganic part of this derivative.10
Therefore, by forcing upon self-assembly processes the 3,3′-bipyridine scaffolds being almost planar (Fig. 2c), the radiative relaxation pathways in derivatives CCl, CBr and CI are significantly altered compared to the luminescent Cu(I) coordination polymer bearing 3,3′-bipyridine ligands reported previously. This clearly demonstrates in such Cu(I)-based supramolecular assemblies the great dependence of the photophysical properties on the molecular engineering applied.
Conclusions
All in all, this study confirms the interest of synthetic approach adapting the CDS chemistry principles to conformationally flexible Cu(I) precursors. In particular, the versatility of [Cu2(μ2-dppm)2] bimetallic units is highlighted, revealing in the case of the use of 3-pyridyl terminated connecting ligands that it is necessary to introduce μ2-X bridging halide ligands to lock the Cu(I) dimer fragment in a conformation that allows conducting selective CDS self-assembly processes. As a result, bimetallic node presenting potential coordination directions of ca. 120° are obtained. Moreover, the variety and peculiarities of the photophysical processes reported for Cu(I) CDS supramolecular assemblies are enriched with this new series of tetrametallacycles that behave as ligand centred triplet luminophores bearing a high RT EQY. These behaviours are assigned to the specific molecular organisation forced within these self-assembled structures and draw appealing perspectives for future investigations varying in particular the internal cores of the 3-pyridyl terminated connecting ligands involved in these reactions. Finally, it is worth stressing that both the gross structural parameters of these metallacycles and their photophysics in the solid-state are comparable, regardless of the nature of the bridging halide atoms. This is rather unusual and highlights on the one hand the specificities that can be associated with the use of conformationally flexible Cu(I) bimetallic precursors. On the other hand, this reveals the originality of the radiative relaxation processes that can lay in such self-assembled CDS assemblies based on the Cu(I) ion.
Author contributions
Florent Moutier: Investigation and formal analysis. Janna Schiller: Investigation and formal analysis. Guillaume Calvez: Formal analysis. Christophe Lescop: Project administration, formal analysis, and writing.
Conflicts of interest
There are no conflicts to declare.
Acknowledgements
This work was supported by the ANR (ANR PRC SMAC and ANR PRCI SUPRALUM), the CNRS, the French ‘Ministère de l′Enseignement supérieur, de la Recherche et de l′Innovation’ and the French ‘Ministère des Affaires Etrangères’. C. L. thanks the Alexander von Humboldt Foundation for a fellowship for experienced researchers.
Notes and references
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Footnotes |
† Electronic supplementary information (ESI) available. CCDC 2074606–2074608. For ESI and crystallographic data in CIF or other electronic format see DOI: 10.1039/d1qo00538c |
‡ These temperature dependant behaviour do not depend on the excitation energy and similar results were obtained with λex = 375 nm. |
§ These emission decay times are mono-exponential. |
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