Abstract
Single-ion anisotropy is vital for the observation of Single-Molecule Magnet (SMM) properties (i.e., a slow dynamics of the magnetization) in lanthanide-based systems. In the case of europium, the occurrence of this phenomenon has been inhibited by the spin and orbital quantum numbers that give way to J = 0 in the trivalent state and the half-filled population of the 4f orbitals in the divalent state. Herein, by optimizing the local crystal field of a quasi-linear bis(silylamido) EuII complex, the [EuII(N{SiMePh2}2)2] SMM is described, providing an example of a europium complex exhibiting slow relaxation of its magnetization. This behavior is dominated by a thermally activated (Orbach-like) mechanism, with an effective energy barrier of approximately 8 K, determined by bulk magnetometry and electron paramagnetic resonance. Ab initio calculations confirm second-order spin-orbit coupling effects lead to non-negligible axial magnetic anisotropy, splitting the ground state multiplet into four Kramers doublets, thereby allowing for the observation of an Orbach-like relaxation at low temperatures.
Similar content being viewed by others
Introduction
Single-molecule magnets (SMMs) have garnered much attention owing to their potential application in molecular-level memory storage devices as well as for quantum information technologies1,2,3,4. These SMM properties arise from an intrinsic energy barrier to the reorientation of the magnetic moment. The strong unquenched orbital contribution of the core 4f-orbitals leads to large inherent magnetic anisotropy in many of the lanthanide series, and the half-integer angular momentum projection of ions such as DyIII (6H15/2) ensures a doubly degenerate ground state, as dictated by Kramers theorem5. Recently, the use of lanthanide (Ln) ions in the design of SMMs has led to significant breakthroughs in performance and operation temperatures beyond that of liquid nitrogen (T = 77 K)6,7,8,9. These remarkable improvements are largely thanks to the exceptional synthetic control of the crystal field splitting and axiality (i.e., ligand design and coordination geometry)10.
Beyond the crystal field, the inherent magnetic moment of the metal center is an important consideration, as a greater magnitude of J can reduce ground-state quantum tunneling of the magnetization (QTM) between degenerate states and lead to overall improvements in the coercivity and blocking temperature11,12. However, altering the effective magnetic moment of a given 4f ion is challenging as the trivalent oxidation state is the most stable for Ln ions13. New discoveries in synthetic 4f chemistry have resulted in the expansion of accessible oxidation states14,15. These discoveries have led to record magnetic moments for the divalent complexes [(Cp’)3LnII]- (Cp’ = trimethylsilylcyclopentadienyl, Ln = DyII, HoII), originating from the 4fn5d1 configuration16. Despite this attractive feature, [(Cp’)3LnII]- do not display slow magnetization dynamics. Nevertheless, ab initio calculations have recently demonstrated that divalent complexes have the potential to possess very strong magnetic anisotropy and very large magnetization blocking barriers (∆/kB > 3000 K) when the geometry around the metal ion is highly symmetric and/or low coordinate17. As an illustration, the divalent metallocene [TbII(CpiPr5)2] (CpiPr5 = pentaisopropylcyclopentadienyl, Ln = TbII) possesses an impressive barrier of 1738 K (1205 cm–1) and a blocking temperature of 52 K18. Ultimately, a clear trend has yet to be established for the effects of oxidation states on the splitting of the ground and excited states, as well as variations in metal-ligand covalency19,20.
The spin contribution to the magnetic moment is the highest in the case of a half-filled 4f-shell (4f7), such as GdIII. However, this electronic configuration is largely considered to be magnetically isotropic as a result of the spherically symmetric charge density of the 8S7/2 ground state that lacks orbital angular momentum (S = 7/2, L = 0). Nonetheless, some GdIII complexes displaying slow magnetization relaxation have been documented21,22,23,24,25,26,27,28,29,30,31,32,33,34,35. Combined with the inclusion of the isoelectronic TbIV, the 4f7 valence series (EuII, GdIII, and TbIV) provides unique insight into the minutia that govern the electronic properties of lanthanides beyond the trivalent oxidation state, serving as an excellent model to examine the precise effects of the coordination environment on the electronic structures of Ln ions with uncommon oxidation states. However, until now, the magnetic studies of Eu-based complexes have been limited to their static susceptibility properties. In order to expand the prevalence of elements displaying slow magnetization relaxation, we present herein the quasi-linear complex, [EuII{N(SiMePh2)2}2] (1), which is to the best of our knowledge, the first example of a europium SMM.
Results and discussions
Synthesis and structural analysis
Compound 1 was prepared by the reaction of one equivalent of EuI2 with two equivalents of K(THF)N(SiMePh2)2 in THF, in accordance with the previously reported procedure for [YbII{N(SiMePh2)2}2] (Fig. 1a)36. Crystallization from an n-hexane solution gave [EuII{N(SiMePh2)2}2] (1) as orange crystals in ~68% yield.
Single-crystal X-ray diffraction reveals 1 crystallizes in the monoclinic P21/c space group (Supplementary Table 1). The complex has a near-linear geometry with an N–Eu–N angle of 169.808(83)° and metal-nitrogen distances of 2.4884(26) Å and 2.4612(26) Å, comparable to the YbII analog36. The slightly longer bond lengths in 1 compared to the YbII analogue is consistent with the increased ionic radius of the EuII ion. Two phenyl moieties from each –N(SiMePh2)2 ligand act to encapsulate the metal ion with Eu•••C interactions between 2.93 and 3.04 Å, preventing any further aggregation or interactions with solvent molecules. The individual complexes are well separated in the lattice by a distance of 10.64 Å (Supplementary Fig. 1).
Photoluminescence spectroscopy
The excitation spectrum of 1 obtained at 10 K (Supplementary Fig. 2) reveals a broad signal in the UV range at 270 nm due to the ligand and EuII 5d centered absorptions. A single component centred at 518 nm (19,305 cm−1) is observed in the emission spectrum (Supplementary Fig. 3a), characteristic of EuII 5d → 4f transitions. A blue shift of the transition is observed at 293 K, with the center being shifted to 496 nm (20,161 cm−1). At room temperature, the emitter level lifetime is 2.45 µs (Supplementary Fig. 4). It is noteworthy that vibrational components are observable at room temperature, suggesting strong vibronic coupling. Deconvolution of the emission band results in seven different components equally separated (~1550 cm−1), suggesting possible vibronic coupling between the excited 5d state and the vibration located at 1561 cm−1 in the FT-IR (Supplementary Fig. 3b). Attempts to oxidize the divalent complex 1 using silver salts, particularly AgAl{OC(CF3)3}4, resulted in the formation of a silver mirror (AgI → Ag0) and strong red emission visible to the naked eye when excited under a 405 nm UV laser. At first glance, this result might suggest the successful oxidation of 1 to the trivalent oxidation state with the characteristic red emission of EuIII. While single crystals of the oxidized product could not be isolated, the excitation spectrum of the obtained crude oil was collected in C6H5F (Supplementary Fig. 5). The characteristic broad emission of the EuII 5d → 4f transitions was observed with the band red-shifted to 756 nm (13,227 cm−1). This drastic red shift indicates a significant change in the metal’s coordination environment, suggesting that a ligand-centred oxidation is taking place in the presence of AgI. As the EuII/III redox potential (−0.35 V vs. SCE) is the most positive of the lanthanides, the divalent oxidation state is particularly stable37. In fact, the reaction of K(THF)N(SiPh2Me)2 with AgAl{OC(CF3)3}4 in the absence of oxidizable EuII still resulted qualitatively in the formation of Ag0 and an intractable product whose structure could not be determined. This echoes several of the challenges observed in previous reports by Mills and co-workers when attempting to oxidize bis(silylamido) EuII complexes, where the bis(silylamide) ligands undergo non-reversible oxidation in place of the metal center38,39.
Computational studies
The electronic structure of 1 was studied by computational methods (see Methods section), confirming a ground electronic configuration of 4f7, which would be expected to give rise to an isotropic 8S7/2 multiplet40. However, linear coordination geometries have recently been shown to stabilize states with multiple open shell configurations in coordination complexes of divalent lanthanide ions18. Therefore, this possibility was also considered for 1. At the hybrid DFT level using the PBE0 exchange-correlation functional, all seven unpaired electrons are found to reside in orbitals with more than 88% 4f character. Furthermore, ab initio multireference calculations were performed41,42, demonstrating that the 8S7/2 ground spin multiplet is weakly split under second-order spin-orbit coupling (SOC) effects into four Kramers doublets spanning an energy range of 3–4 cm–1 (4–6 K). The calculated g tensor of the 8S7/2 multiplet is almost isotropic with principal values of 1.9975, which only differ in the fifth decimal. The second-order zero-field splitting (ZFS) parameters are calculated to be D/kB = –0.40 K and E/kB = +0.008 K, indicating the presence of axial anisotropy. The higher-order ZFS parameters are negligible. The principal axis of the ZFS tensor is oriented along the molecular N–Eu–N pseudo axis (Fig. 1b), implying that 1 possesses non-negligible magnetic axiality, owing to the quasi linear environment provided by the bis(silylamide) ligands. It can therefore be anticipated that the ZFS will result in slow relaxation of magnetization via an Orbach-like mechanism at low temperatures.
High-field EPR measurements
Due to the inferred magnetic anisotropy of 1, temperature-dependent continuous-wave (CW) high-field electron paramagnetic resonance (EPR) measurements were performed on an unconstrained polycrystalline sample, at frequencies of 128 and 256 GHz (Fig. 2)43,44. Seven dominant resonances are observed in the spectra recorded at each frequency, corresponding to the 2S allowed EPR (ΔmS = ±1) transitions within the eight (= 2S + 1) spin projection states associated with the S = 7/2 EuII ion (Fig. 2); note that weakly allowed ΔmS = ±2 transitions are also observed in the half-field region of the spectrum (Fig. 2, inset). Excellent spectral simulations are obtained with the following ZFS parameters: gz = 1.998(5), D/kB = −0.659(4) K (D/hc = −0.458(3) cm−1), in good agreement with the above calculations and the magnetization data discussed below. In order to reproduce the observed intensity patterns, D-strain, σD = 0.004 cm−1, and a peak-to-peak linewidth, σlw = 15 mT, were included in the 4.5 K simulations (σD = 0.001 cm−1 and Δlw = 45 mT at 50 K). These simulations assume alignment of the crystallites within the powder sample, which is to be expected due to the magnetic torque on the anisotropic EuII species. However, the glide plane in the unit cell of 1 gives rise to symmetry equivalent molecules that are not collinear (Supplementary Fig. 1a). Consequently, the field aligns along the average anisotropy direction of the bulk crystals, which intersects the principal magnetic axes of the two sites45. The most accurate simulations were achieved when the angle (θ) between the applied field and the principal axes of the ZFS (D) tensors of the molecules in the unit cell was set to 16.6(2)°. Because of this alignment, only the axial spin Hamiltonian parameters, gz and D, could reliably be determined from the simulations. Due to the reactivity of 1, several attempts to constrain the sample to prevent torquing proved unsuccessful. As such, the bulk crystals were left unconstrained in order to avoid potential decomposition.
The obtained D parameter gives a magnetization reversal barrier, ∆EPR/kB = (S2 – 1/4)∣D∣/kB = 7.9 K, which is in almost perfect agreement with the value determined from the ac susceptibility studies discussed below (∆ac/kB = 8.2 K, vide infra). Finally, we note that the simulated peak positions enable an unambiguous determination of the magnitude of D. However, in order to determine its sign, one must compare temperature-dependent spectra. As can be seen from the spectra in Fig. 2, spectral weight shifts from high- to low-field upon cooling, which is fully consistent with a negative D parameter46.
Magnetic measurements
To probe the magnetic properties, direct current (dc) magnetic susceptibility measurements were performed on 1. At room temperature, a χT product of 7.8 cm3 K mol−1 is observed (Supplementary Fig. 6), which is in good agreement with the S = 7/2 ground state expected for an isolated EuII ion with a 4f7 ground state configuration (7.875 cm3 K mol−1). The χT product remains constant down to 50 K, whereafter it decreases slightly to reach 6.3 cm3 K mol−1 at 1.85 K and 1000 Oe. This low-temperature behavior is likely the result of ZFS, as predicted by the computational results and confirmed by EPR (vide supra), and has been observed in related linear EuII complexes47. Magnetization as a function of applied magnetic field (between 0 and 70 kOe; Supplementary Fig. 7) in the temperature range of 1.85–8 K exhibits a high-field linear variation and non-complete saturation at 70 kOe, indicative of magnetic anisotropy. A near saturation close to 7.0 μB at 1.85 K and 70 kOe is in good agreement with the S = 7/2 ground state. Non-superposition of the isothermal lines of the reduced magnetization plot (Supplementary Fig. 7) further suggests the presence of non-negligible ZFS. An attempt was made to fit the experimental M vs. H/T and χT vs. T data to the simplest S = 7/2 model with the \(\widehat{H}=D \hat{S}_{T,z}^{2}\) Hamiltonian (Supplementary Fig. 8). The experimental data are qualitatively reproduced with D/kB = −0.58(5) K (D/hc = −0.40(7) cm−1), in agreement with EPR data and computational results.
Alternating current (ac) susceptibility measurements were performed on 1. In the absence of an applied magnetic field, the ac susceptibility does not exhibit any sign of slow relaxation of the magnetization down to 1.9 K and up to 10 kHz. Upon application of a static dc field, a clear signal in the out-of-phase component is observed, indicating the presence of slow paramagnetic relaxation. (Supplementary Fig. 9). The frequency dependence of the ac susceptibly data measured at different magnetic fields up to 10 kOe was fitted to the generalized Debye model (Supplementary Eqs. 1 and 2; Supplementary Figs. 9 and 10) from which the relaxation times (τ) were extracted (Supplementary Fig. 11)48. To elucidate the contribution of the individual relaxation mechanisms on the spin dynamics of 1, the relaxation times were fit to the sum of individual QTM (B1, B2), Direct (A), Raman (C, C1, C2), and Orbach-like (τ0, ∆) relaxation mechanisms. These pathways are the most frequently used in the phenomenological models used to describe the relaxation dynamics of SMMs, which is expressed by the rate equations (Eqs. 1 and 2)49,50,51:
At fields below 1 kOe, the relaxation time increases with an \({H}^{2}\) dependence (Supplementary Fig. 11), which is consistent with the field dependence of a QTM process described by the first term in Eq. (2). Fitting of the experimental τ between 0 and 800 Oe leads to the following parameters: B1 = 1.8(1) 104 s−1 and B2 = 22.8(2.3) kOe−2 (Supplementary Fig. 11). At higher fields, the variation does not follow an \({H}^{-4}\) dependence that would indicate a Direct process, nor an \({H}^{-2}\) field-dependence characteristic of Raman relaxation. Indeed, this field variation of the relaxation time is modest, suggesting the presence of a thermally activated (Orbach-like) relaxation process (last term in Eq. (2)). To elucidate the relaxation dynamics of 1, ac magnetic susceptibility as a function of temperature was measured under an applied dc field 800 Oe (Fig. 3 and Supplementary Fig. 12), for which the relaxation time is the longest and the effects of ground state QTM are minimized.
The obtained temperature dependence of τ can be modeled between 1.9 and 5 K considering a thermally activated (Orbach-like) relaxation process with an energy gap of 8.2(5) K (or 5.7(3) cm−1; τ0 = 3.1(6) 10−6 s; Supplementary Figs. 13–15) and a contribution from a QTM relaxation process (B1 and B2 being fixed to the values obtained from the fit of the field dependence). This result indicates unambiguously that the thermally activated relaxation is dominant in this temperature region, which agrees with the analysis of the field dependence of the relaxation. Nonetheless, two factors suggest the presence of additional relaxation mechanisms: (i) the obtained pre-exponential factor (τ0) of 3.1(6) 10−6 s is larger than expected for an Orbach-like relaxation regime; and (ii) the field dependence of the relaxation time above 1 kOe is complex and could not be reproduced by fitting to Eq. (2). Attempts to fit the experimental data with relaxation models including Raman and direct processes lead to overparameterization and did not improve the theory-experiment agreement above 0.1 T (Supplementary Fig. 15).
The EuII complex presented herein exhibits slow relaxation of the magnetization, expanding the elements of the 4f7 valence series capable of behaving as an SMM beyond GdIII. This divalent complex belongs to a rare and synthetically challenging class of low-coordinate SMMs that continues to attract interest. An Orbach-like mechanism dominates the relaxation dynamics of 1, with a relaxation barrier of 8.2 K. The highly axial coordination environment, combined with second order spin-orbit coupling, gives rise to a weak axial ZFS interaction that provides the origin of the paramagnetic relaxation. These results underscore the significance of crystal field effects in lanthanide ions, which allows us to harness the magnet-like behavior of the EuII ion.
Methods
General methods
All operations were performed in an M. Braun glovebox under an atmosphere of purified dinitrogen or using high vacuum standard Schlenk techniques. Solvents were dried using a J.C. Meyer solvent system, degassed with successive freeze-pump-thaw cycles, and stored over activated 4 Å molecular sieves prior to use. EuI2 was purchased from Sigma Aldrich in anhydrous form at ≥ 99.9% purity. Celite used for filtration was dried under vacuum while heating to 180 °C for 5 days. [K{N(SiMePh2)2}THF]n was prepared according to literature procedure52. [Eu{N(SiMePh2)2}2] (1) was prepared based on our previously published synthetic procedure36. A brief description of the synthesis is detailed below. FT-IR spectra were recorded on a Nicolet Nexus 550 FT-IR spectrometer using transmission mode in the 4000-600 cm−1 range; solid samples were prepared in an inert atmosphere and sandwiched between transparent NaCl plates. Elemental analyses were performed by Midwest Microlab.
Synthesis of [Eu{N(SiMePh2)2}2] (1)
A solution of [K{N(SiMePh2)2}THF]n (128 mg, 0.246 mmol) in THF (5 mL) was added to EuI2 (50 mg, 0.123 mmol) in 5 mL of THF. The mixture was allowed to stir for 16 h, followed by the removal of the solvent under reduced pressure. The crude solid was suspended in n-hexane, followed by filtration through Celite. The solvent was then removed under reduced pressure until incipient crystallization was observed. The product is obtained as crystalline orange blocks in 68% yield (81 mg, 0.083 mmol). CHN Anal. Calcd. for C52H52N2Si4Eu: C, 64.43; H, 5.41; N, 2.89. Found: C, 62.85; H, 5.43; N, 3.01. FT-IR (neat, cm−1): 487(w) 596(w), 627(w), 662(w), 703(s), 729(s), 775(s), 799(s), 852(w), 870(w), 967(m), 1031(w), 1060(w), 1110(m), 1153(w), 1183(w), 1251(w), 1298(w), 1330(w), 1423(w), 1477(w), 1561(w), 1581(w).
Crystal growth and single-crystal X-ray diffraction analysis
Crystal growth of [Eu{N(SiMePh2)2}2] was accomplished by concentration of a solution of 1 in n-hexane, from which bright orange blocks suitable for X-ray crystallographic study were obtained. X-ray diffraction data represents the most reliable datasets obtained from multiple trials. The crystal was submerged in Parabar 10312 (Paratone N) oil and mounted on a MiTeGen Microloop. The X-ray diffraction data for 1 was collected on a Bruker KAPPA APEX II single crystal diffractometer equipped with a sealed Mo tube source (λ = 0.71073 Å) APEX II CCD detector at a temperature of 200 K. The structure was solved by direct method with SHELXT53 and refined based on F2 with SHELLXL54. Hydrogen atom positions were calculated based on the geometry of related non-hydrogen atoms and treated as idealized contributions during the refinement.
Luminescence measurements
The photoluminescence data was obtained using a QuantaMaster 8075-21 spectrofluorometer (Horiba). An ozone-free PowerArc energy 75 W xenon lamp was used as the radiation source. The excitation spectra were corrected in real-time according to the lamp intensity and the optical system of the excitation monochromator using a silicon diode as a reference. The emission spectra were corrected according to the optical system of the emission monochromator and the photomultiplier response (Hamamatsu R13456 red extended PMT). Low-temperature measurements were performed with the samples mounted inside a CS202*E-DMX-1AL closed-cycle helium cryostat system (Advanced Research Systems) controlled via a LakeShore 335 temperature controller. For the emission decay curve, we excited the sample with a 275 nm LED (Thorlabs M275L4) controlled with a LED driver (Thorlabs DC2200 Driver) and collected the emission with an Andor iStar 334 ICCD camera installed in a Shamrock SR750 spectrograph. The LED was pulsed with a 20 kHz frequency (one pulse every 50 µs) and a pulse width of 2.5 µs.
CW EPR spectrometry
The sample was ground to a fine powder under inert atmosphere using a mortar and pestle. It was then placed in a polyethylene cup with a Teflon stopper, then shipped to the NHMFL in an ampoule which was sealed under inert atmosphere. Just prior to measurement, the ampoule was opened, and the sample quickly mounted in the spectrometer and cooled under a helium atmosphere. The transmission type spectrometer43 employs a 17 T sweepable superconducting magnet. Microwave frequencies in the range 128–256 GHz were generated using a tunable phase-locked source followed by a series of frequency multipliers (Virginia Diodes Inc., Charlottesville, VA). The field-modulated EPR signal was generated using a wound copper coil and the signal detected using an InSb hot-electron bolometer (QMC Ltd., Cardiff UK). The final derivative-mode (dI/dH, where I is the microwave intensity transmitted through the sample and H is the applied magnetic field) EPR signal was demodulated using a lock-in amplifier at 50 kHz (Stanford Research Systems, Sunnyvale, CA). The temperature was regulated via a continuous flow helium cryostat in combination with an ITC 503 controller (Oxford Instruments, Oxford UK).
Magnetometry
Magnetic susceptibility measurements were performed on a Quantum Design SQUID MPMS-XL magnetometer and PPMS-9 susceptometer housed at the Centre de Recherche Paul Pascal at temperatures between 1.85 and 300 K and dc magnetic fields ranging from −7 to +7 T. The ac magnetic susceptibility measurements were performed in an oscillating ac field of 1 to 6 Oe with frequencies between 0.1 Hz and 10 kHz and various dc fields (including zero). The measurements were carried out on polycrystalline samples of [Eu{N(SiMePh2)2}2] (1) (16.9 and 9.8 mg) suspended in mineral oil (typically 10-12 mg) and introduced in a sealed double layered polyethylene/polypropylene bag (3 × 0.5 × 0.02 cm; 25.5 and 20.1 mg). The consistent and reproducible dc and ac measurements on these samples were combined into a single extended set. Prior to the experiments, the field-dependent magnetization was measured at 100 K to exclude the presence of bulk ferromagnetic impurities. In fact, common paramagnetic or diamagnetic materials should exhibit a perfectly linear dependence of the magnetization at 100 K that extrapolates to zero at zero dc field; the samples appeared to be free of any ferromagnetic impurities. The magnetic susceptibilities were corrected for the sample holder, the mineral oil, and the intrinsic diamagnetic contributions.
Computational details
The geometry of 1 was extracted from the crystal structure. The positions of hydrogen atoms were optimized using density functional theory (DFT), while the positions of heavier atoms were kept frozen to their crystal-structure coordinates. The optimization was carried out using the Amsterdam Modeling Suite (AMS) version 2020.10155,56,57,58. The pure GGA exchange-correlation functional PBE59,60 was used along with Grimme’s DFT-D3 dispersion correction61 with the Becke–Johnson damping function62. Scalar relativistic effects were treated using the zeroth-order regular approximation (ZORA)63,64,65. The default Slater-type basis sets designed for ZORA calculations were used in all DFT calculations66. A valence-polarized triple-ζ quality basis (TZP) was used for the Eu ion with all orbitals up to 5p treated as a frozen core. Valence-polarized double-ζ quality basis sets were used for the remaining atoms. The 1s electrons in C and N atoms and all electrons up to 2p in Si were treated as frozen cores. In order to study the electron configuration, a final single-point DFT calculation was carried out on 1 using the hybrid PBE0 exchange-correlation functional and all-electron triple-ζ quality basis sets with two sets of polarization functions (TZ2P) for all atoms67,68.
The electronic structure of 1 was further studied by multireference ab initio calculations. These were conducted using the OpenMolcas code version 21.0269,70. Two state-averaged complete active space self-consistent field (SA-CASSCF) calculations were carried out71,72,73,74,75. The active space consisted of the seven 4f orbitals and seven 4f electrons. In the first calculation, the high spin octet state was solved and, in the second calculation, all 48 sextet states were solved for. These were then mixed under the effect of spin-orbit coupling (SOC) using the well-established spin-orbit restricted active space state interaction (SO-RASSI) approach76. The zero-field splitting (ZFS) parameters and the g tensors were extracted from the ab initio results using the SINGLE_ANISO module77,78.
Relativistically contracted atomic natural orbital basis sets (ANO-RCC) were used in the multireference calculations79,80,81. A valence-polarized quadruple-ζ basis (VQZP) was used for the Eu ion, valence-polarized triple-ζ basis sets (VTZP) were used for the N and Si atoms while valence-polarized double-ζ basis sets (VDZP) were used for the remaining atoms. Cholesky decomposition with a threshold of 10–8 atomic units was used in the integral storage. Scalar relativistic effects were introduced using the scalar exact two-component (X2C) approach82,83,84. The atomic mean-field integral (AMFI) formalism was used in the construction of the SOC operator used in the SO-RASSI procedure85,86.
Data availability
The crystallographic data generated in this study have been deposited in the Cambridge Structural Database under deposition number 2284168. Copies of the data can be obtained free of charge via https://www.ccdc.cam.ac.uk/structures/. The EPR data and ac magnetic susceptibility generated in this study are provided in as Source Data files. Source data for the Supplementary Figs. can be provided upon request. Source data are provided with this paper.
References
Leuenberger, M. N. & Loss, D. Quantum computing in molecular magnets. Nature 410, 789–793 (2001).
Ardavan, A. et al. Will spin-relaxation times in molecular magnets permit quantum information processing? Phys. Rev. Lett. 98, 057201 (2007).
Bogani, L. & Wernsdorfer, W. Molecular spintronics using single-molecule magnets. Nat. Mater. 7, 179–186 (2008).
Gaita-Ariño, A., Luis, F., Hill, S. & Coronado, E. Molecular spins for quantum computation. Nat. Chem. 11, 301–309 (2019).
Klein, M. J. On a degeneracy theorem of kramers. Am. J. Phys. 20, 65–71 (1952).
Guo, F.-S. et al. A dysprosium metallocene single-molecule magnet functioning at the axial limit. Angew. Chem. Int. Ed. 56, 11445–11449 (2017).
Goodwin, C. A. P., Ortu, F., Reta, D., Chilton, N. F. & Mills, D. P. Molecular magnetic hysteresis at 60 kelvin in dysprosocenium. Nature 548, 439–442 (2017).
Guo, F.-S. et al. Magnetic hysteresis up to 80 kelvin in a dysprosium metallocene single-molecule magnet. Science 362, 1400–1403 (2018).
Gould, C. A. et al. Ultrahard magnetism from mixed-valence dilanthanide complexes with metal-metal bonding. Science 375, 198–202 (2022).
Goodwin, C. A. P. Blocking like it’s hot: a synthetic chemists’ path to high-temperature lanthanide single molecule magnets. Dalton Trans. 49, 14320–14337 (2020).
Tejada, J., Hernandez, J. M. & del Barco, E. Macroscopic quantum tunneling of the magnetic moment. J. Magn. Magn. Mater. 196–197, 552–557 (1999).
Gatteschi, D. & Sessoli, R. Quantum tunneling of magnetization and related phenomena in molecular materials. Angew. Chem. Int. Ed. 42, 268–297 (2003).
Nief, F. Non-classical divalent lanthanide complexes. Dalton Trans. 39, 6589–6598 (2010).
Sorace, L. & Gatteschi, D. Electronic structure and magnetic properties of lanthanide molecular complexes. in Lanthanides and Actinides in Molecular Magnetism 1–26 (John Wiley & Sons, Ltd, 2015) https://doi.org/10.1002/9783527673476.ch1.
MacDonald, M. R., Bates, J. E., Ziller, J. W., Furche, F. & Evans, W. J. Completing the series of +2 ions for the lanthanide elements: synthesis of molecular complexes of Pr2+, Gd2+, Tb2+, and Lu2+. J. Am. Chem. Soc. 135, 9857–9868 (2013).
Meihaus, K. R., Fieser, M. E., Corbey, J. F., Evans, W. J. & Long, J. R. Record high single-ion magnetic moments through 4fn5d1 electron configurations in the divalent lanthanide complexes [(C5H4SiMe3)3Ln]−. J. Am. Chem. Soc. 137, 9855–9860 (2015).
Zhang, W., Muhtadi, A., Iwahara, N., Ungur, L. & Chibotaru, L. F. Magnetic anisotropy in divalent lanthanide compounds. Angew. Chem. Int. Ed. 59, 12720–12724 (2020).
Gould, C. A. et al. Synthesis and magnetism of neutral, linear metallocene complexes of terbium(II) and dysprosium(II). J. Am. Chem. Soc. 141, 12967–12973 (2019).
Fieser, M. E. et al. Structural, spectroscopic, and theoretical comparison of traditional vs recently discovered Ln2+ ions in the [K(2.2.2-cryptand)][(C5H4SiMe3)3Ln] complexes: the variable nature of Dy2+ and Nd2+. J. Am. Chem. Soc. 137, 369–382 (2015).
Gompa, T. P. et al. High-frequency and -field electron paramagnetic resonance spectroscopic analysis of metal–ligand covalency in a 4f7 valence series (Eu2+, Gd3+, and Tb4+). Inorg. Chem. 60, 9064–9073 (2021).
Martínez-Pérez, M. J. et al. Gd-based single-ion magnets with tunable magnetic anisotropy: molecular design of spin qubits. Phys. Rev. Lett. 108, 247213 (2012).
Orendáč, M. et al. Spin relaxation and resonant phonon trapping in [Gd2(fum)3(H2O)4]⋅3H2O. Phys. Rev. B 81, 214410 (2010).
Tkáč, V. et al. Multiple-timescale relaxation dynamics in CsGd(MoO4)2—a dipolar magnet with a highly anisotropic layered crystal structure. J. Phys.: Condens. Matter 25, 506001 (2013).
Girginova, P. I., Pereira, L. C. J., Coutinho, J. T., Santos, I. C. & Almeida, M. Slow magnetic relaxation in lanthanide ladder type coordination polymers. Dalton Trans. 43, 1897–1905 (2013).
Arauzo, A. et al. Structural and magnetic properties of some lanthanide (Ln = Eu(III), Gd(III) and Nd(III)) cyanoacetate polymers: field-induced slow magnetic relaxation in the Gd and Nd substitutions. Dalton Trans. 43, 12342–12356 (2014).
Holmberg, R. J. et al. Observation of unusual slow-relaxation of the magnetisation in a Gd-EDTA chelate. Dalton Trans. 44, 20321–20325 (2015).
Yoshida, T. et al. Field-induced slow magnetic relaxation of GdIII complex with a Pt−Gd heterometallic bond. Chem. Eur. J. 23, 4551–4556 (2017).
Izuogu, D. C. et al. Slow magnetic relaxation in a palladium–gadolinium complex induced by electron density donation from the palladium ion. Chem. Eur. J. 24, 9285–9294 (2018).
Vráblová, A. et al. Slow magnetic relaxation in Ni–Ln (Ln = Ce, Gd, Dy) dinuclear complexes. Dalton Trans. 48, 13943–13952 (2019).
Dolai, M., Ali, M., Rajnák, C., Titiš, J. & Boča, R. Slow magnetic relaxation in Cu(II)–Eu(III) and Cu(II)–La(III) complexes. N. J. Chem. 43, 12698–12701 (2019).
Horii, Y. et al. Coexistence of spin–lattice relaxation and phonon-bottleneck processes in GdIII–phthlocyaninato triple-decker complexes under highly diluted conditions. Chem. Eur. J. 26, 8076–8082 (2020).
Orts-Arroyo, M. et al. One-dimensional gadolinium (III) complexes based on alpha- and beta-amino acids exhibiting field-induced slow relaxation of magnetization. Inorganics 10, 32 (2022).
Oyeka, E. E. & Tran, T. T. Single-ion behavior in new 2-D and 3-D gadolinium 4f7 materials: CsGd(SO4)2 and Cs[Gd(H2O)3(SO4)2]·H2O. ACS Org. Inorg. Au. 2, 502–510 (2022).
Magott, M. & Wegner, W. Approaching the free-ion limit in magnetically isotropic gadolinium(III) via borohydride ligands. Phys. Chem. Chem. Phys. 25, 10689–10696 (2023).
Petersen, J. B. et al. Electron paramagnetic resonance spectra of pentagonal bipyramidal gadolinium complexes. Inorg. Chem. 62, 8435–8441 (2023).
Errulat, D. et al. A trivalent 4f complex with two bis-silylamide ligands displaying slow magnetic relaxation. Nat. Chem. 15, 1100–1107 (2023).
Morss, L. R. & Haug, H. O. Enthalpy of formation of europium dichloride and thermodynamic properties of the +2 and +3 aqueous ions of europium. J. Chem. Thermodyn. 5, 513–524 (1973).
Nicholas, H. M. et al. Electronic structures of bent lanthanide(III) complexes with two N-donor ligands. Chem. Sci. 10, 10493–10502 (2019).
Goodwin, C. A. P. et al. Physicochemical properties of near-linear lanthanide(II) bis(silylamide) complexes (Ln = Sm, Eu, Tm, Yb). Inorg. Chem. 55, 10057–10067 (2016).
Mulak, J. & Mulak, M. Capability of the free-ion eigenstates for crystal-field splitting. J. Mod. Phys. 2, 1373–1389 (2011).
Ungur, L. & Chibotaru, L. F. Computational modelling of the magnetic properties of lanthanide compounds. in Lanthanides and Actinides in Molecular Magnetism (eds. Layfield, R. A. & Murugesu, M.) 153–184 (Wiley-VCH Verlag GmbH & Co. KGaA, 2015).
Roos, B. O., Lindh, R., Malmqvist, P. Å., Veryazov, V. & Widmark, P.-O. Multiconfigurational Quantum Chemistry (Wiley, 2016).
Hassan, A. K. et al. Ultrawide band multifrequency high-field EMR technique: a methodology for increasing spectroscopic information. J. Magn. Reson. 142, 300–312 (2000).
Craig, G. A. et al. Field-induced slow relaxation in a monometallic manganese(III) single-molecule magnet. Inorg. Chem. 54, 13–15 (2015).
Martínez-Lillo, J. et al. Highly anisotropic rhenium(IV) complexes: new examples of mononuclear single-molecule magnets. J. Am. Chem. Soc. 135, 13737–13748 (2013).
Baker, M. L., Blundell, S. J., Domingo, N. & Hill, S. Spectroscopy Methods for Molecular Nanomagnets. in Molecular Nanomagnets and Related Phenomena (ed. Gao, S.) 231–291 (Springer, 2015).
Goodwin, C. A. P. et al. Investigation into the effects of a trigonal-planar ligand field on the electronic properties of lanthanide(II) tris(silylamide) complexes (Ln = Sm, Eu, Tm, Yb). Inorg. Chem. 56, 5959–5970 (2017).
Cole, K. S. & Cole, R. H. Dispersion and absorption in dielectrics I. alternating current characteristics. J. Chem. Phys. 9, 341–351 (1941).
Harriman, K. L. M., Errulat, D. & Murugesu, M. Magnetic axiality: design principles from molecules to materials. Trends Chem. 1, 425–439 (2019).
Castro-Alvarez, A., Gil, Y., Llanos, L. & Aravena, D. High performance single-molecule magnets, Orbach or Raman relaxation suppression? Inorg. Chem. Front. 7, 2478–2486 (2020).
Aravena, D. & Ruiz, E. Spin dynamics in single-molecule magnets and molecular qubits. Dalton Trans. 49, 9916–9928 (2020).
Bartlett, R. A. & Power, P. P. Two-Coordinate, Nonlinear, Crystalline d6 and d7 Complexes:Syntheses and Structures of M{N(SiMePh2)2}2, M = Fe or Co. J. Am. Chem. Soc. 109, 7563–7564 (1987).
Sheldrick, G. M. SHELXT – Integrated space-group and crystal-structuredetermination. Acta Crystallogr. A Found. Adv. 71, 3–8 (2015).
Sheldrick, G. M. Crystal structure refinement with SHELXL.Acta Crystallogr. C. Struct. Chem. 71, 3–8 (2015).
Rüger, E. et al. AMS 2021.1, SCM, Theoretical Chemistry, Vrije Universiteit, Amsterdam, The Netherlands, http://www.scm.com.
Baerends, E. J. et al. ADF 2021.1, SCM, Theoretical Chemistry, Vrije Universiteit, Amsterdam, The Netherlands, http://www.scm.com.
te Velde, G. et al. Chemistry with ADF. J. Comp. Chem. 22, 931–967 (2001).
Fonseca Guerra, C., Snijders, J. G., te Velde, G. & Baerends, E. J. Towards an order-N DFT method. Theor. Chem. Acc. 99, 391–403 (1998).
Perdew, J. P., Burke, K. & Ernzerhof, M. Generalized Gradient Approximation Made Simple. Phys. Rev. Lett. 77, 3865–3868 (1996).
Perdew, J. P., Burke, K. & Ernzerhof, M. Generalized Gradient Approximation Made Simple [Phys. Rev. Lett. 77, 3865 (1996)]. Phys. Rev. Lett. 78, 1396 (1996).
Grimme, S., Antony, J., Ehrlich, S. & Krieg, H. A consistent and accurate ab initio parametrization of density functional dispersion correction (DFT-D) for the 94 elements H–Pu. J. Chem. Phys. 132, 154104 (2010).
Grimme, S., Ehrlich, S. & Goerigk, L. Effect of the damping function in dispersion corrected density functional theory. J. Comp. Chem. 2011, 1456–1465 (2011).
van Lenthe, E., Baerends, E. J. & Snijders, J. G. Relativistic regular two-component Hamiltonians. J. Chem. Phys. 99, 4597–4610 (1993).
van Lenthe, E., Baerends, E. J. & Snijders, J. G. Relativistic total energy using regular approximations. J. Chem. Phys. 101, 9783–9792 (1994).
van Lenthe, E., van Leeuwen, R., Baerends, E. J. & Snijders, J. G. The zero-order regular approximation for relativistic effects: The effect of spin-orbit coupling in closed shell molecules. Int. J. Quantum Chem. 57, 281–293 (1996).
van Lenthe, E. & Baerends, E. J. Optimized Slater-type basis sets for the elements 1–118. J. Comp. Chem. 24, 1142–1156 (2003).
Ernzerhof, M. & Scuseria, G. E. Assessment of the Perdew–Burke–Ernzerhof exchange-correlation functional. J. Chem. Phys. 19, 5029–5036 (1999).
Adamo, C. & Barone, V. Toward reliable density functional methods without adjustable parameters: The PBE0 model. J. Chem. Phys. 110, 6158–6170 (1999).
Galván, I. F. et al. OpenMolcas: From Source Code to Insight. J. Chem. Theory Comput. 15, 5925–5964 (2019).
Aquilante, F. et al. Modern quantum chemistry with [Open]Molcas. J. Chem. Phys. 152, 214117 (2020).
Roos, B. O. in Advances in Chemical Physics, Ab Initio Methods in Quantum Chemistry II, Vol. 69, 399–455 (ed Lawley, K. P.) (Wiley, New York, 1987).
Siegbahn, P., Heiberg, A., Roos, B. & Levy, B. A Comparison of the Super-CI and the Newton-Raphson Scheme in the Complete Active Space SCF Method. Phys. Scr. 21, 323–327 (1980).
Roos, B. O., Taylor, P. R. & Siegbahn, P. E. M. A complete active space SCF method (CASSCF) using a density matrix formulated super-CI approach. Chem. Phys. 48, 157–173 (1980).
Siegbahn, P. E. M., Almlöf, J., Heiberg, A. & Roos, B. The complete active space SCF (CASSCF) method in a Newton–Raphson formulation with application to the HNO molecule. J. Chem. Phys. 74, 2384–2396 (1981).
Roos, B. O., Lindh, R., Malmqvist, P. Å., Veryazov, V. & Widmark, P.-O. Multiconfigurational Quantum Chemistry (Wiley, Hoboken, NJ, 2016).
Malmqvist, P. Å., Roos, B. O. & Schimmelpfenning, B. The restricted active space (RAS) state interaction approach with spin–orbit coupling. Chem. Phys. Lett. 357, 230–240 (2002).
Chibotaru, L. F. & Ungur, L. Ab initio calculation of anisotropic magnetic properties of complexes. I. Unique definition of pseudospin Hamiltonians and their derivation. J. Chem. Phys. 137, 064112 (2012).
Ungur, L. & Chibotaru, L. F. Computational Modelling of Magnetic Properties of Lanthanide Compounds in Lanthanide and Actinides in Molecular Magnetism. (eds Layfield, R. A. & Murugesu, M.) 153–184 (Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim, Germany, 2015).
Widmark, P.-O., Malmqvist, P.-Å. & Roos, B. O. Density matrix averaged atomic natural orbital (ANO) basis sets for correlated molecular wave functions. Theor. Chim. Acta. 77, 1432–2234 (1990).
Roos, B. O., Lindh, R., Malmqvist, P.-Å., Veryazov, V. & Widmark, P.-O. Main Group Atoms and Dimers Studied with a New Relativistic ANO Basis Set. J. Phys. Chem. A. 108, 2851–2858 (2004).
Roos, B. O. et al. New Relativistic Atomic Natural Orbital Basis Sets for Lanthanide Atoms with Applications to the Ce Diatom and LuF3. J. Phys. Chem. A. 112, 11431–11435 (2008).
Kutzelnigg, W. & Liu, W. Quasirelativistic theory equivalent to fully relativistic theory. J. Chem. Phys. 123, 241102 (2005).
Filatov, M. Comment on "Quasirelativistic theory equivalent to fully relativistic theory" [J. Chem. Phys.123, 241102 (2005)]. J. Chem. Phys 125, 107101 (2006).
Peng, D. & Reiher, M. Quasirelativistic theory equivalent to fully relativistic theory. Theor. Chem. Acc. 131, 241102 (2012).
Heß, B. A., Marian, C. M., Wahlgren, U. & Gropen, O. A mean-field spin-orbit method applicable to correlated wavefunctions. Chem. Phys. Lett. 251, 365–371 (1996).
Christiansen,O., Gauss, J. & Schimmelpfennig, B. Spin-orbit coupling constants from coupled-cluster response theory. Phys. Chem. Chem. Phys. 2, 965–971 (2000).
Reta, D. & Chilton, N. F. Uncertainty estimates for magnetic relaxation times and magnetic relaxation parameters. Phys. Chem. Chem. Phys. 21, 23567–23575 (2019).
Acknowledgements
D.E., K.L.M.H. and M.M. thank the University of Ottawa, the CFI, and NSERC for financial support of this work. A.M. acknowledges the funding provided by the Academy of Finland (grant no. 332294) and the University of Oulu (Kvantum Institute). Computational resources were provided by CSC-IT Center for Science in Finland and the Finnish Grid and Cloud Infrastructure (persistent identifier urn:nbn:fi:research-infras-2016072533). R.C. and M.R. thank the University of Bordeaux, the Centre National de la Recherche Scientifique (CNRS), the Région Nouvelle Aquitaine, Quantum Matter Bordeaux (QMBx), and the Association Française de Magnétisme Moléculaire. E.V.S. and S.H. acknowledge support from the US Department of Energy, Basic Energy Sciences (DE-SC0020260). Work performed at the National High Magnetic Field Laboratory is supported by the US National Science Foundation (DMR-2128556) and the State of Florida.
Author information
Authors and Affiliations
Contributions
D.E., K.L.M.H. and M.M. conceived the study. D.E. and K.L.M.H. synthesized and characterized the compounds. D.E. and K.L.M.H. collected X-ray diffraction data on 1, and D.E. performed structure determination and refinement. M.R. and R.C. collected and interpreted the magnetic data. A.M. performed the ab initio calculations and analysis. D.A.G. collected and interpreted the luminescence data. E.V.S, J.v.T. and S.H. collected and interpreted the EPR data. M.M. supervised all aspects of the project. The manuscript was written with contributions from all authors.
Corresponding authors
Ethics declarations
Competing interests
The authors declare no competing interests.
Peer review
Peer review information
Nature Communications thanks Ana Arauzo and the other, anonymous, reviewer(s) for their contribution to the peer review of this work. A peer review file is available.
Additional information
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary information
Source data
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Errulat, D., Harriman, K.L.M., Gálico, D.A. et al. Slow magnetic relaxation in a europium(II) complex. Nat Commun 15, 3010 (2024). https://doi.org/10.1038/s41467-024-46196-w
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41467-024-46196-w
Comments
By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.