Substituent Effects on Isocyanate Insertion into a Lanthanide−Sulfur Bond. Unexpected Construction of a Coordinated Thiazolate Ring

Structurally isomeric ditopic 2-mercaptobenzoxazole and 2-hydroxybenzothiazole as ligands for design of 2D sodium-based luminescent coordination polymers

The novel ditopic centrosymmetric soft-base ligands 3,7-dihydrobenzo[1,2-d:4,5-d']bis(oxazole)-2,6-dithione (H2L1) and 3,7-dihydrobenzo[1,2-d:4,5-d']bis(thiazole)-2,6-dione (H2L2) were obtained via a one-pot method. Both compounds form 2D coordination polymers (CPs) through the reaction of free ligands with sodium bis(trismethylsilyl)amide in various solvent media. H2L1 containing products were [Na2L1(DME)2]n (1) and [Na2L1(DMSO)4]n (2), and for H2L2, [Na6L23(DMSO)12]n (3) was formed. X-ray analysis revealed that compound 1 is a 2D CP, in which deprotonated H2L1 acts as a tetratopic linker, linking four sodium atoms via nitrogen and bridging sulfur. Unlike 1, in CP 2, deprotonated H2L1 acts as a ditopic linker coordinating sodium atoms in an unprecedented Na4O4 metallocenter formed by the oxygens of DMSO molecules. Compound 3 is a 2D CP featuring rare Na3O6 secondary building unit (SBU), whereas H2L2 exhibits both bridging and mixed chelating/bridging mode, linking four sodium atoms via nitrogen and oxygen atoms. Despite the fact that free ligands H2L1 and H2L2 are non-luminescent in solution and in the solid state, their deprotonated forms at 298 K in DME media demonstrate moderate photoluminescence (PL) in DME solutions with broad bands in the range of 360-500 nm. At 77 K, the same solutions show broadened and intense PL consisting of bands in the 360-670 nm region corresponding to ligand fluorescence and phosphorescence. CPs 1-3 in the solid state exhibit PL at 298 and 77 K. At 298 K, CPs 1 and 3 exhibit intense fluorescence in the range of 370-450 nm and moderate microsecond timescale phosphorescence in the range of 500-670 nm, while CP 2 exhibits only fluorescence. Upon cooling to 77 K, all three CPs demonstrate both fluorescence and phosphorescence. Based on the low-temperature phosphorescence spectra of 1 and 3 in DME solutions, the triplet energy levels of H2L1 and H2L2 were established at 21 000 and 20 800 cm-1, respectively.

Luminescent Cerium(III) Complexes with Poly(mercaptoimidazolyl)borate: A New Emitter Based on S-Coordinating Ligands

Lanthanide ions are hard Lewis acids and usually form weak bonds with soft sulfur donors, which result in the supposed instability of their complexes with S-coordinating ligands. Compared with luminescent lanthanide complexes with hard nitrogen or oxygen donor ligands, the development of luminescent lanthanide complexes based on sulfur-donor ligands currently lags behind. In this work, two types of poly(mercaptoimidazolyl)borate ligands, one is tridentate and the other is tetradentate, were used for the design and synthesis of two series of novel S-coordinating cerium(III) (Ce(III)) complexes, which were found to be not only luminescent but also with moderate to surprisingly good stability in air. By tuning the ligand type and substituents, blue- and yellow-green-emitting Ce(III) complexes with different emission mechanisms of d-f transition, delayed d-f transition, and ligand-centered fluorescence/phosphorescence were obtained, among which the highest photoluminescence quantum yield (PLQY) was 97%, and the most stable one can still maintain 74% of the initial PLQY even after exposure to air for 1 month. Furthermore, we investigated the degradation mechanism of these complexes in air, revealing the oxidation of low-valence sulfur(II) to high-valence sulfur-containing S═O bonds. This work shows the potential of S-coordinating ligands in luminescent Ce(III) complexes and provides new perspectives for designing Ce(III) complexes with soft donors.

Half-Sandwich Cerium and Lanthanum Dialkyl Complexes: Synthesis, Structure, and Reactivity Studies

Cerium and lanthanum dialkyl complexes [η5-1,2,4-(Me3C)3C5H2]Ln(CH2C6H4-o-NMe2)2 (Ln = Ce 1 and La 2), supported by a tri-tert-butylcyclopentadienyl ligand, have been successfully synthesized. Studies demonstrate that these complexes possess diverse reactivity toward various small molecules. For example, the reaction of complexes 1 and 2 with diphenyl dichalcogenides PhEEPh (E = S, Se) results in the formation of lanthanide thiolates [(η5-1,2,4-(Me3C)3C5H2)Ln(SPh)(μ-SPh)]2 (Ln = Ce 3 and La 4) and selenolates [(η5-1,2,4-(Me3C)3C5H2)Ln(SePh)(μ-SePh)]2 (Ln = Ce 5 and La 6), concomitantly releasing PhE(CH2C6H4-o-NMe2). Furthermore, complexes 1 and 2, upon reaction with dibenzyl disulfide, yield tetranuclear rare-earth metallomacrocyclic compounds {[(η5-1,2,4-(Me3C)3C5H2)Ln(μ-SCH2C6H5)]2(μ-η3:η3-SCHC6H5)}2 (Ln = Ce 7 and La 8). This reaction may involve a process of σ-bond metathesis and C-H activation. While the reaction of 1 and 2 with dibenzyl diselenide in the presence of LiCH2C6H4-o-NMe2 leads to the formation of lanthanide-lithium selenido clusters [(η5-1,2,4-(Me3C)3C5H2)La(μ-SeCH2C6H5)]3(μ3-Se)[μ3-SeLi(THF)3] (Ln = Ce 9 and La 10). Meanwhile, lanthanide selenido clusters [(η5-1,2,4-(Me3C)3C5H2)La(μ-SeCH2C6H4-o-NMe2)]4(μ3-Se)2 (Ln = Ce 11 and La 12) can be obtained by treating 1 and 2 with elemental selenium in a 1:2 molar ratio. Additionally, the treatment of 1 and 2 with benzoxazole generates ring-opening/C-C coupling/C-N coupling products {(η5-1,2,4-(Me3C)3C5H2)La[μ-OC6H4-o-N═CHN(CH(CH2C6H4-o-NMe2)2C6H4-o-O]}2 (Ln = Ce 13 and La 14). All new compounds were characterized by various spectroscopic methods, and their solid-state structures were confirmed by single-crystal X-ray diffraction analyses.

Lanthanocene and Cerocene Alkyl Complexes: Synthesis, Structure, and Reactivity Studies

Lanthanocene and cerocene alkyl complexes [η⁵-1,3-(Me₃C)₂C₅H₃]₂Ln(CH₂C₆H₄-o-NMe₂) (Ln = La 3 and Ce 4) were obtained from the salt metathesis of {[η⁵-1,3-(Me₃C)₂C₅H₃]₂Ln(μ₃-κ³-O₃SCF₃)₂K(THF)₂}₂·THF (Ln = La 1·THF and Ce 2·THF) with LiCH₂C₆H₄-o-NMe₂. Reactivity of 3 and 4 toward various small molecules provides access to a series of lanthanide derivatives. For example, reactions of 3 and 4 with elemental chalcogens (sulfur and selenium) in 1:1 molar ratio give the lanthanide thiolates {[η⁵-1,3-(Me₃C)₂C₅H₃]₂Ln(μ-SCH₂C₆H₄-o-NMe₂)}₂ (Ln = La 5 and Ce 6) and selenolates {[η⁵-1,3-(Me₃C)₂C₅H₃]₂Ln(μ-SeCH₂C₆H₄-o-NMe₂)}₂ (Ln = La 7 and Ce 8). The compounds 3 and 4 react with two equivalents of elemental chalcogens (sulfur and selenium) to afford the lanthanide disulfides {[η⁵-1,3-(Me₃C)₂C₅H₃]₂Ln}₂(μ-η²:η²-S₂) (Ln = La 9 and Ce 10) and diselenides {[η⁵-1,3-(Me₃C)₂C₅H₃]₂Ln}₂(μ-η²:η²-Se₂) (Ln = La 11 and Ce 12). The lanthanide disulfides (9 and 10) or diselenides (11 and 12) can also be readily obtained through oxidation of the corresponding lanthanide thiolates (5 and 6) or selenolates (7 and 8) by elemental chalcogens concomitant with the (Me₂N-o-C₆H₄CH₂)₂E₂ (E = S or Se) release. Treatment of 3 and 4 with one equivalent or two equivalents of benzonitrile produces the serendipitous lanthanum and cerium-1-azaallyl complexes [η⁵-1,3-(Me₃C)₂C₅H₃]₂Ln[N(H)C(Ph)═CHC₆H₄-o-NMe₂] (Ln = La 13 and Ce 14) or amidine complexes [η⁵-1,3-(Me₃C)₂C₅H₃]₂Ln[N(H)C(Ph)NC(Ph)═CHC₆H₄-o-NMe₂]·C₇H₈ (Ln = La 15·C₇H₈ and Ce 16·C₇H₈), respectively. The compound 15 or 16 can also be readily synthesized by further insertion of one benzonitrile molecule into the 1-azaallyl complex 13 or 14. Insertion of N,N'-dicyclohexylcarbodiimide or phenyl isothiocyanate into Ln-C bonds within 3 and 4 results in the formation of the amidine complexes [η⁵-1,3-(Me₃C)₂C₅H₃]₂Ln[CyNC(CH₂C₆H₄-o-NMe₂)NCy] (Cy = cyclohexyl, Ln = La 17 and Ce 18) or thioamidato complexes [η⁵-1,3-(Me₃C)₂C₅H₃]₂Ln[SC(CH₂C₆H₄-o-NMe₂)NPh] (Ln = La 19 and Ce 20). All of the new compounds were characterized by various spectroscopic methods, and their solid-state structures were further confirmed by single-crystal X-ray diffraction analyses.

LMCT facilitated room temperature phosphorescence and energy transfer in substituted thiophenolates of Gd and Yb

To obtain luminescent lanthanide complexes with a low energy LMCT state the 2-(2'-mercaptophenyl)benzothiazolates, Ln(SSN)₃, and 2-(2'-mercaptophenyl)benzoxazolates, Ln₂(OSN)₆ (Ln = Gd, Yb), were synthesized by the reaction of amides Ln[N(SiMe₃)₂]₃ with respective thiophenols. Ytterbium complexes were structurally characterized by X-ray diffraction analysis. Cyclic voltammetry revealed that the deprotonated mercaptophenyl ligands have significantly lower oxidation potentials than their phenoxy analogues and some β-diketones. The photophysical properties of Gd and Yb compounds were studied both in solution and in the solid state. The fluorescence spectra of the compounds in solution display the bands of the keto and enol forms of the ligands. No energy transfer from the organic part to Yb³⁺ has been detected in solutions of both Yb complexes, whereas in solids an intense metal-centered emission in the near infrared region was observed. The solid Gd compounds exhibited room temperature phosphorescence caused by unusually efficient intersystem crossing facilitated by the essentially reducing properties of OSN and SSN ligands. To explain the sensitization process occurring in solids Yb₂(OSN)₆ and Yb(SSN)₃ a specific non-resonant energy transfer mechanism via a ligand to metal charge transfer state has been proposed. Based on the Yb derivatives, NIR-emitting OLEDs with 860 μW cm^-2 maximal irradiance were obtained. Their Gd counterparts showed bright electrophosphorescence (up to 1350 cd m^-2) in the devices containing doped emission layers.

Selective Reaction Based on the Linked Diamido Ligands of Dinuclear Lanthanide Complexes

The dinuclear ytterbium pyridyl diamido complexes [Cp(2)Yb(THF)](2)[mu-eta(1):eta(2)-(NH)(2)(C(5)H(3)N-2,6)] (1a) and [Cp(2)Yb(THF)](2)[mu-eta(1):eta(2)-(NH)(2)(C(5)H(3)N-2,3)] (1b) are easily prepared by protonolysis of Cp(3)Yb with 0.5 equiv of the corresponding diaminopyridine in accepted yields, respectively. Treatment of 1a with 2 equiv of dicyclohexylcarbodiimide (CyN=C=NCy) in THF at low temperature leads to the isolation of the formal double N-H addition product (Cp(2)Yb)(2)[mu-eta(2):eta(2)-(CyN(CyNH)CN)(2)(C(5)H(3)N-2,6)] (2) in 42% yield. Compound 2 is unstable to heat and slowly isomerized to the mixed neutral/dianionic diguanidinate complex (Cp(2)Yb)(2)[mu-eta(2):eta(2)-(CyNH)(2)CN(C(5)H(3)N-2,6)NC(NCy)(2)](THF) (3) at room temperature. Similarly, treatment of 1b with 2 equiv of CyN=C=NCy gives the addition/ isomerization product (Cp(2)Yb)(2)[mu-eta(2):eta(2):eta(1)-(CyNH)(2)CN(C(5)H(3)N-2,3)NC(NCy)(2)] (4). Moreover, the reaction of various ytterbium aryl diamido complexes (prepared in situ from [Cp(2)YbMe](2) and aryldiamine, respectively) with CyN=C=NCy affords the corresponding addition products (Cp(2)Yb)(2)[mu-eta(2):eta(2)-{CyN(CyNH)CN}(2)(C(6)H(4)-1,4)] (5), (Cp(2)Yb)(2)[mu-eta(2):eta(2)-{CyN(CyNH)CN}(2)(C(6)H(4)-1,3)](6), and (Cp(2)Yb)(2)[mu-eta(2):eta(2)-{CyN(CyNH)CN}(2)(C(13)H(8)-2,7)] (7), respectively. In contrast to pyridyl-bridged bis(guanidinate monoanion) complexes, aryl-bridged bis(guanidinate monoanion) complexes 5-7 are stable even with prolonged heating at 110 degrees C. All the results not only demonstrate that the presence of the pyridyl bridge can impart the diamido complexes with a unique reactivity and initiate the unexpected reaction sequence but also indicate evidently that the number and distribution of negative charges of the diguanidinate ligand is tunable from double monoanionic units to mixed neutral/dianionic isomers. All the complexes are characterized by elemental analysis and IR spectroscopies. The structures of complexes 1a, 3, 5, 6, and 7 are also determined through X-ray single-crystal diffraction analysis.

Facile construction of novel organolanthanide square-planar macrocycles through addition of carbodiimide to an amino group

The reactivity of lanthanocene derivatives containing the p-aminothiophenolate ligand towards carbodiimide was examined. Reaction of Cp2Ln(p-SC6H4NH2)(THF) with RN=C=NR in THF at room temperature gave four novel organolanthanide guanidinate complexes [Cp2Ln(p-SC6H4N(H)C(NHR)=NR)]4 (R = iPr, Ln = Yb (1a), Er (2a); R = Cy, Ln = Yb (2a), Er (2b)), formed by the addition of the C[double bond, length as m-dash]N double bonds of the carbodiimide molecule to the para-position amino group. Their unique square-planar macrocycle structures have been determined through X-ray single-crystal diffraction analysis. This result provides a potential method for the construction of organolanthanide macrocycles.

Facile Construction of Lanthanide Metallomacrocycles with the Bridging Imidazolate and Triazolate Ligands and Their Ring Expansions

Four novel tri- or tetranuclear organolanthanide metallomacrocycles [Cp2Ln(mu-Im)(THF)3 (Cp = C5H5, Ln = Yb (1), Er (2)], [Cp2Dy(mu-Im)]4(THF)]3 x 2THF (3), and [Cp'2Yb(mu-eta1:eta2-Tz)]4 x 2THF (Cp' = CH3C5H4) (4) have been synthesized through protolysis of Cp3Ln or Cp'3Yb with imidazole or triazole, indicating that both the bridge-ligand size and the lanthanide-ion radii can be applied in the modulation of the metallomacrocycles. Further investigations on the reactivity of complexes 1, 3, and 4 toward phenyl isocyanate reveal that PhNCO inserts readily into the simple bridge Ln-N bonds of 1 and 3 to yield the corresponding insertion products [Cp2Ln(mu-eta1:eta2-OC(Im)NPh)]3 (Ln = Yb (5), Dy (6)) but cannot insert into the Ln-N bond with a mu-eta1:eta2-bonding mode in 4. The novel bridge ligand [OC(Im)NPh] can expand the numbers of the ring members from 12 to 18 in 5 or 16 to 18 in 6. The number of metal atoms in the metallacycles with the ligand [OC(Im)NPh] is independent of the lanthanide-ion size; both trinuclear lanthanide macrocycles are observed in 5 and 6. All of these new complexes have been characterized by elemental analysis and spectroscopic properties, and their structures have also been determined through X-ray single-crystal diffraction analysis.

Reactivity of Lanthanocene Amide Complexes toward Ketenes: Unprecedented Organolanthanide-Induced Conjugate Electrophilic Addition of Ketenes to Arenes

This paper presents some unusual types of reactions of lanthanocene amide complexes with ketenes, and demonstrates that these reactions are dependent on the nature of amide ligands and ketenes as well as the stoichiometric ratio under the conditions involved. The reaction of [{Cp(2)LnNiPr(2)}(2)] with four equivalents of Ph(2)CCO in toluene affords the unexpected enolization dearomatization products [Cp(2)Ln(OC{2,5-C(6)H(5)(==CPhCONiPr(2)-4)}==CPh(2))] (Ln = Yb (1 a), Er (1 b)) in good yields, representing an unprecedented conjugate electrophilic addition to a non-coordinated benzenoid nucleus. Treatment of [{Cp(2)LnNiPr(2)}(2)] with four equivalents of PhEtCCO under the same conditions gives the unexpected enolization dearomatization/rearomatization products [{Cp(2)Ln(OC{C(6)H(4)(p-CHEtCONiPr(2))}==CEtPh)}(2)] (Ln = Yb (2 a), Er (2 b), Dy (2 c)). However, reaction of [{Cp(2)YbNiPr(2)}(2)] with PhEtCCO in THF forms only the mono-insertion product [Cp(2)Yb{OC(NiPr(2))==CEtPh}](THF) (3). Hydrolysis of 2 afforded aryl ketone PhEtCHCOC(6)H(4)(p-CHEtCONiPr(2)) (4) and the overall formation of aryl ketone 4 provides an alternative route to the acylation of aromatic compounds. Moreover, reaction of [{Cp(2)LnNHPh}(2)] with excess of PhEtCCO or Ph(2)CCO in toluene affords only the products from a formal insertion of the C==C bond of the ketene into the N--H bond, [(Cp(2)Ln{OC(CHEtPh)NPh})(2)] (Ln = Yb (5 a), Y (5 b)) or [(Cp(2)Er{OC(CHPh(2))NPh})(2)] (6), respectively, indicating that an isomerization involving a 1,3-hydrogen shift occurs more easily than the conjugate electrophilic addition reaction, along with the initial amide attack on the ketene carbonyl carbon. [{Cp(2)ErNHEt}(2)] reacts with an excess of PhEtCCO to give [(Cp(2)Er{PhEtCHCON(Et)COCEtPh})(2)] (7), revealing another unique pattern of double-insertion of ketenes into the metal-ligand bond without bond formation between two ketene molecules. All complexes were characterized by elemental analysis and by their spectroscopic properties. The structures of complexes 1 b, 2 a, 2 b, 5 a, 5 b, 6, and 7 were also determined through X-ray single-crystal diffraction analysis.

Unusual modification methods for the ureido ligand of lanthanocene derivatives

(C5H5)2Ln[OC(PzMe2)=NPh](THF) (Ln = Dy (1a), Er (1b), Yb (1c), Y (1d)) were prepared in good yields by the PhNCO insertion into the Ln-N bond of (C(5)H(5))(2)Ln(PzMe(2))(THF) (PzMe(2) = 3,5-dimethylpyrazolate) in THF at room temperature. Treatment of with p-aminothiophenol in THF at room temperature gives unusual ligand-based substitution derivatives {(C5H5)2Ln[mu-eta1:eta3-OC(p-H2NC6H4S)NPh]}2.2THF (Ln = Dy (2a), Er (2b), Yb (2c), Y (2d)), while reaction of 1c with o-aminothiophenol instead of p-aminothiophenol allows the occurrence of a tandem substitution/cyclization/elimination to form unexpected benzothiazole-2-oxide complex [(C5H5)2Yb(mu-eta1:eta3-OSNC7H4)]2 (3c), representing a novel modification method for non-cyclopentadienyl ligands of lanthanocene derivatives. However, complex does not react with benzyl thiol, indicating that the nature of thiols has a profound influence on the substitution reaction. All complexes were characterized by elemental analysis and spectroscopic properties. The X-ray diffraction analysis reveals that and are solvated monomeric structures, while and are centrosymmetric dimeric ones with an unusual intermolecular hydrogen bond interaction involving THF.