Development of Rotaxanes as E-Field-Sensitive Superstructures in Plasmonic Nano-Antennas

• Introduction
• Results and Discussion
• Conclusions
• Experimental Section
• Funding Information
• References

Abstract

We present the concept of electrostatic field-driven supramolecular translation within electrically connected plasmonic nano-antennas. The antenna serves as an anchoring point for the mechanically interlocked molecules, as an electrode for the electrostatic field, and as an amplifier of the antenna-enhanced fluorescence. The synthesis of a push–pull donor–π–acceptor chromophore with optical properties aligned to the antenna resonance is described and its immobilization on the surface is demonstrated. Photoluminescence experiments of the chromophore on a gold nano-antenna are shown, highlighting the molecule–antenna coupling and resulting emission intensity increase. The successful synthesis of an electrostatic field-sensitive [2]rotaxane in water is described and the tightrope walk between functionality and water solubility is illustrated by unsuccessful designs. In solution, an enhanced fluorescence quantum yield is observed for the chromophore comprising the mechanically interlocked [2]rotaxane in water and DMSO compared to the reference rod, ideal for future experiments in plasmonic nano-antennas.

Introduction

The inherently independent motion of the individual parts of mechanically interlocked molecules has led to their use as both molecular switches and machines.[1] Rotaxanes in particular are ideal for controlled translational motion of the macrocyclic component (frequently called “shuttling”) along an axis with clear boundaries – the stoppers at either end of the rod.[2],[3] This movement is typically induced by external stimuli; common examples include light,[4] acid/base, and redox-driven[5] switching.[1],[6]

In solution, the rotaxanes perform the motion along their axis, but due to their random orientation, the movement of the ensemble is isotropic. To achieve anisotropy, rotaxanes and other molecular switches and machines have been immobilized on surfaces and successfully triggered to perform controlled motion.[1],[7],[8] The immobilization on electrodes provides an ideal platform for electrochemical or electrostatic field-driven switching. While translational motion is frequently achieved on redox-driven rotaxanes, to the best of our knowledge electrostatic fields have mainly been used to study circumrotation of the macrocycle around the rod.[9],[10] Solution-based translational motion of DNA- or protein-based strands threaded through nanopores has been achieved with transmembrane electric potentials[11],[12] which can be used for sensing DNA polymerase activity[13],[14] or protein folding.[15] As demonstrated by these systems, the alignment of the axis along the electric field is an important prerequisite for the electrostatic field-induced translational switching.

Here we propose to profit from the electrostatic field inside the gap of an electrically connected plasmonic nano-antenna to manipulate the translation in a tailor-made rotaxane. While we are currently developing the intended experiment, we report here the optimization of the rotaxane structure together with initial studies in a plasmonic nano-antenna set-up demonstrating the suitability of the structure for the purpose. [Figure 1] shows the intended switching experiment and indicates the first prerequisite for meaningful switching inside the antenna gap: site-selectively functionalized electrodes. The boundary conditions of the experiment are manifold, ranging from experimental physical challenges over the physical chemistry of the immobilization to aspects that have to be considered in the design of the rotaxane. The most fundamental requirements for the rotaxane are: (1) it must consist of charged subunits to be able to react on the applied electrostatic field. (2) As the translation of the macrocycle along the axis shall be observed optically, one of the stations should be an emitting chromophore, with emission features depending on the presence/absence of the macrocycle. (3) The emission features of the chromophore have to be above 550 nm to avoid the intense inherent emission and interband absorption of gold – the plasmonic nano-antenna material. Furthermore, the chromophore must be sufficiently photostable to allow for the detection of a small ensemble of molecules for a reasonable amount of time. (4) The rotaxane structure must expose anchor groups enabling their immobilization on the gold structure of the optical antenna.

We chose plasmonic nano-antennas as they provide the ideal platform for controlled supramolecular translation and simultaneous readout of the macrocycleʼs position via antenna-enhanced fluorescence. Their benefits include the following:[16]–[19] (1) the monocrystalline Au(111) surface is readily functionalized with thiol-functionalized molecules. (2) The nanometer-sized gap allows for strong electrostatic fields at relatively low voltages and hence enables the supramolecular movement of rotaxanes immobilized in the gap region without electrochemical degradation. (3) The geometry of the antenna can be adjusted precisely, thus allowing tuning of the antenna resonance to the chromophoreʼs emission wavelength. (4) Once the resonances are aligned, the feed gap exhibits strong near-field enhancement, which leads to a significant increase in the emission intensity of chromophores close to the antenna gap under saturation conditions. Importantly, the near-field enhancement (and the electrostatic field) decreases outside of the gap, thus the emission signal is dominated by rotaxanes in the gap region.[20],[21]

Herein, the synthesis of a push–pull donor–π–acceptor chromophore primed for rotaxane assembly and its coupling to optical nano-antennas are described. Furthermore, the design and synthesis of [2]rotaxanes optimized for electrostatic field-driven switching are reported. As a particular challenge, the merger of the desired functionalities in a compact design with sufficient water solubility enabling rotaxane formation driven by the hydrophobic effect is discussed.

Results and Discussion

The elaborate molecular design of 1a⊂M ([Scheme 1]) was devised to comprise all the components required for supramolecular switching in an electrostatic field and its optical observation. The donor–π–acceptor chromophore serves as both a hydrophobic station for the cyclophane and as a fluorescent readout for the macrocycleʼs position on the rod. The oligo(ethyleneglycol) (OEG) chain on the rod ensures sufficient space for the cyclophaneʼs translation along the rod axis, while the OEG chains on the stoppers are terminated by masked thiols to anchor the molecule on the gold surface. Both OEG chains further serve to separate the chromophore from the surface to avoid quenching of the chromophoreʼs excited states.[22],[23] Stoppers at the ends of the rod mechanically interlock the dicationic macrocycle M. We chose the Diederich-type cyclophane M [24],[25] due to its permanently charged piperidinium groups, the high association constants it exhibits in water, its ability to change emission properties of guests, as well as the ease of analysis by NMR due to its high symmetry and significant changes in chemical shifts upon complexation.[26]–[30] As additional water-solubilizing groups, anionic sulfonates were considered, pulling the rod towards the cathode and thereby supporting an upright arrangement of the rotaxane immobilized on the anode.

To take advantage of the antennaʼs near-field enhancement, it is essential for the chromophore to match the antenna resonance, i.e. emitting light in the red spectral region. Simultaneously, the chromophore needs to be sufficiently narrow to fit into the cyclophaneʼs cavity. Accordingly, chromophore 3 was designed to have both a strongly electron-withdrawing group and an electron-donating group bridged by a biphenyl system. Knoevenagel condensation allowed us to combine a terminal alkyne-functionalized benzothiazole and a versatile aldehyde precursor previously synthesized in our group (Scheme S3).[26] The synthesis is described in the Supporting Information. The electron-donating amine on 3 is decorated with two triazol-propylsulfonate groups, which can act as a mechanical stopper and a water-solubilizing group simultaneously. As a result, the chromophore is water soluble and thus suited for rotaxane assembly driven by the hydrophobic effect.[24] This compact design yielded emission maxima above 700 nm in aqueous solution (Figure S8), paving the way for incorporation in plasmonic nano-antennas.

We decided to test the applicability of this chromophore for the purpose of Au(111) surface immobilization and molecule–antenna coupling in the gap of the optical antenna setup. To this end, we attached a thioacetyl-terminated OEG chain (for the synthesis, see Scheme S2) in a copper(I)-catalyzed azide-alkyne 1,3-cycloaddition (CuAAC) “click” reaction to give the extended chromophore 5 ([Scheme 1]). The OEG chain was envisioned as spacer to the surface and chosen due to its more hydrophilic character compared to typically employed alkyl chains in self-assembled monolayers (SAMs). This allows us to better anticipate potential difficulties in the rotaxane assembly, which will contain OEG chains as linkers as well. The additional 1,2,3-triazol has a small impact on the optical properties, shifting absorption bathochromically and emission hypsochromically, but the emission in the red spectral range is preserved (Figure S8). To deprotect the masked thiol anchoring group and immobilize the molecule on Au(111), 5 is dissolved in methanol and a solution of sodium methoxide (5.4 M in methanol) is added. The gold sample is then immersed in this solution for 20 min, washed with water and dried in a stream of nitrogen gas. We could not observe SAM formation by photoluminescence (PL) when 5 was immobilized without prior deprotection.[31]

The PL measurements of 5 irradiated on the plasmonic nano-antenna demonstrated that the resulting emission is enhanced, polarized, and spectrally shaped by the presence of the optical antenna ([Figures 2] and S2).[17],[32]–[34] After chemisorption of 5 on an exemplary antenna ([Figure 2]a), a hyperspectral PL map is recorded by scanning the region of interest with the excitation laser ([Figure 2]b). Hardly any emission is detected on glass confirming the surface-selective immobilization of 5 on the Au(111) surface. Furthermore, the local density of states is increased in the vicinity of the optical antenna (i.e., mostly inside the gap and towards the antenna ends), resulting in an increased rate of radiative decay of the molecules compared to the non-radiative decay. Hence, a significantly enhanced emission is observed for molecules on the antenna when compared to the flat Au(111) surface under saturation conditions. The high rate of molecule excitation in the antenna gap causes significant photobleaching within seconds (t _1/2 = 4.1 s) of irradiation with 50 µW 532 nm light under a stream of nitrogen gas (Figure S1). Nonetheless, the chromophore is sufficiently stable to observe its emission after 30 s of irradiation and is therefore suited for the intended switching experiments.

Due to the shape of the antenna, the enhancement is polarization-dependent and most photons are polarized along the long axis of the antenna (see Supporting Information). The resulting emission peak is closer to the strong resonance of the antenna at 650 nm than the emission polarized along the short axis.

We have repeated these experiments with different antenna lengths to observe the impact of a change in resonance energy ([Figure 2]c). As expected, the emission enhancement mainly affects transitions in the chromophore close to the resonance energies of the antenna. The maximum of PL emission is shifted bathochromically when the antenna scattering maximum is shifted to lower energies. Moreover, the PL intensity decreases as the resonances of the chromophore and antenna are further detuned.

These experiments not only show the molecule–antenna coupling and associated emission enhancement, polarization, and frequency shift, but also that the chromophore fulfils the stability requirement of the experiment. This axle design thus seems to be ideal for our intent to immobilize rotaxanes on the antenna and observe the translational motion of the macrocycle along the molecular axis optically.

Encouraged by these results, we developed the stopper 2 based on previous designs[29],[35] and incorporated an OEG chain with an azide handle for mild rotaxane stoppering via aqueous CuAAC. Furthermore, in analogy to 5, it comprises masked thiol anchoring groups for its immobilization on a gold surface. The synthesis of 2 is described in the Supporting Information (Scheme S6) and depicted in [Scheme 4].

The assembly of mechanically interlocked superstructures like 1a⊂M based on the precursor 3 turned out to be challenging. While 3 is soluble in water, mixing it with M·2Cl leads to immediate precipitation of both components out of D₂O already at concentrations below 0.5 mM. After unsuccessful screening of the complexation conditions and a variety of ineffective derivatization attempts to increase the water solubility of 3, the assembly strategy was revised fundamentally ([Scheme 2]a). The new approach is based on the biphenyl derivative 6, with a twofold functionality acting as a terminal stopper and as a guest for the cyclophane host M. The plan was to first assemble the pseudorotaxane 6⊂M, which can subsequently be stoppered with 3 in a CuAAC to form 1b⊂M. The design of 6 thus comprises a biphenyl hydrophobic station and a doubly substituted amine as stopper, similar to 3. The synthesis of 6 is described in the Supporting Information (Scheme S4). Despite the OEG chains, the extended stopper 6 was not readily soluble in water. However, to our delight, when heated to 60 °C in the presence of a 2 mM solution of M·2Cl in D₂O, the pseudorotaxane 6⊂M was observed by ¹H-NMR spectroscopy after cooling back to room temperature (Scheme S1). Encapsulation of aromatic guests by M·2Cl in D₂O is typically associated with strong upfield shifts of the aromatic ¹H signals, induced by the aromatic ring current of the cyclophaneʼs walls.[25],[36] The observed shielding of the biphenyl protons (up to 2 ppm) confirms the encircling by M and the formation of the pseudorotaxane 6⊂M.

We set out to synthesize 1b⊂M following this new strategy. First, the pseudorotaxane 6⊂M was formed by heating 6 in water in the presence of excess M·2Cl. Next, CuSO₄ and sodium ascorbate were added, followed by chromophore 3 to stopper the pseudorotaxane via CuAAC. While HRMS (Figure S5) and impure ¹H-NMR spectra suggested the formation of 1b⊂M as an interlocked species, purification attempts revealed that the [2]rotaxane was not a stable mechanically interlocked species in organic solvents like DMSO at room temperature (Figures S6 and S7). Instead an equilibrium between the [2]rotaxane 1b⊂M and its components 1b and M was observed, resulting in the steady degradation of the isolated [2]rotaxane 1b⊂M. Intriguingly, we had previously confirmed that the bulk of the triazol-propylsulfonate groups on the chromophore suffice to mechanically interlock a rotaxane.[26] We anticipated 6 to be of similar size but probably underestimated the role of the ionic subunits in the mechanical fixation in solution. However, it appears that the macrocycle can pass the stopper subunit of 6 already at room temperature. We are currently investigating simplified model compounds to rationalize and quantify this observation.

The structure comprising the station for the cyclophane was thus redesigned with a stopper with sufficient steric bulk inspired by 2. Biphenyl 6b was supposed to act as a hydrophobic guest for the cyclophane with a pair of attached triazoles exposing OEG chains with terminal anchor groups as stoppers. Its synthesis is presented in the Supporting Information (Scheme S5). In spite of the OEG chains, the compound 6b turned out to be too insoluble in water to enable the pseudorotaxane formation. Its assembly and properties thus rather display the challenge to find the subtle balance between water solubility and self-assembling features driven by the hydrophobic effect.

Our previously synthesized [2]rotaxane based on chromophore 7 showed increased quantum yields upon encapsulation in both water and DMSO, making it another potential candidate for our endeavor.[26] As a result of the less electron-withdrawing substituent, its absorption and emission are hypsochromically shifted compared to derivatives of 3. Its optical properties are thus closer to the gold interband absorption, which might increase the challenges faced in the intended experiment. However, with emission signals clearly above 550 nm, it should still be observable individually, and compared to 3, 7 showed increased water solubility and was shown to have a high association constant with M·2Cl in water.[26]

Foregoing the need for a stopper acting as a hydrophobic station, we decided to use our original stopper 2 for our target [2]rotaxane 8⊂M ([Scheme 3]). The mechanically interlocked molecule was assembled from M·2Cl, 2, and 7 using classical CuAAC “click” reaction conditions with CuSO₄ and sodium ascorbate. All reactants were soluble in water, which allowed us to take full advantage of the hydrophobic effect – the main driving force for the host–guest complexation with M.[24] Interestingly, within 2 h at room temperature, the solution had lost nearly all its orange color, and an orange precipitate had formed. This already suggested a significantly decreased water solubility of 8⊂M and 8 compared to the individual reactants. Purification of the precipitate by reversed-phase HPLC on C-18 functionalized silica enabled the separation of [2]rotaxane 8⊂M from unthreaded rod 8, and after further purification of 8, the two products were isolated in 21% and 28% yield, respectively. 8⊂M and 8 were fully characterized by ¹H-, ¹³C-, and 2D-NMR spectroscopy, along with HRMS. Both the [2]rotaxane and rod showed low solubility in water, but good solubility in DMSO and mixtures of ACN and water. Unlike 1b⊂M, 8⊂M was found to be a room-temperature-stable mechanically interlocked superstructure, showing neither dissociation in DMSO over time nor during purification by HPLC.

The mechanically interlocked nature of 8⊂M is made apparent by NOE signals between the rod and the cyclophane (see Supporting Information). Intriguingly, NOEs between the alkyl protons of the triazolpropylsulfonate groups of the stopper and the protons in proximity to the piperidinium of M are observed (Figure S11). These signals potentially suggest the attraction of the two oppositely charged water-solubilizing groups. This phenomenon could explain the stability of 8⊂M compared to 1b⊂M, where one of the stoppers lacks the anionic moiety. The implication of this attraction on the shuttling behavior in an electrostatic field will be interesting to investigate.

Comparison of the ¹H-NMR spectrum of 8⊂M to that of 8 reveals distinct shielding of the encapsulated protons in the isolated 8⊂M ([Scheme 3]). The central protons of the biphenyl system are shifted most significantly compared to 8 with Δδ of 1.8 and 2.3 ppm, indicating their role as the preferred position of the cyclophane. Interestingly, the olefinic and neighboring aromatic protons are shifted more (0.5 and 1.2 ppm, respectively) than the outer biphenyl proton next to the amine (~0.3 ppm). We interpret this as the macrocycle being prevalent on the more electron-deficient part of the chromophore due to its electron-rich aromatic walls. The ¹H signal of the amide is only weakly influenced by the cyclophane and the signals belonging to either stopper show negligible changes in chemical shift.

For our intended purpose of electrostatic field-driven switching, we require a significant difference in optical properties of the two states. Thus, the optical properties of the chromophore in the free rod 8 were compared with the ones of the complexed [2]rotaxane 8⊂M. The absorption maximum of 8⊂M is only slightly bathochromically shifted compared to 8, with 422 versus 415 nm in H₂O (Figure S9), and 426 versus 417 nm in DMSO, respectively ([Figure 3]). On the other hand, the emission is shifted hypsochromically in 8⊂M, with maxima at 654 and 635 nm in water and DMSO, respectively, compared to 671 and 652 nm for 8. While the position of the absorption and emission maxima only slightly varied by encapsulating the chromophore in the rotaxane, a significant difference in the emission intensity was observed. Quantification was performed by absolute fluorescence quantum yield measurement in an integrating sphere, corrected for indirect excitation (see Supporting Information). While the encapsulated chromophore in 8⊂M emitted with an efficiency of 6.5% in water (65.7% in DMSO), the bare chromophore in 8 showed a quantum yield of only 2.2% in water (20.5% in DMSO). We have previously observed similar fluorescence enhancements with mechanically interlocked structures bearing the same chromophore core.[26] These changes in intensity are crucial to observe the electrostatic field-induced switching in an optical antenna gap.

We are delighted to report 8⊂M as a [2]rotaxane fulfilling the boundary conditions for the intended E-field-driven and optically monitored translational switching experiment. Currently we are optimizing the immobilization conditions on Au(111) surfaces with both 8⊂M and 8.

Conclusions

The concept of translational motion in a [2]rotaxane within an optical antenna gap by application of an electrostatic field is presented. Initial experiments using a donor–π–acceptor chromophore have proven, besides the robustness of the chromophore, the emission in the vicinity of the antenna to be enhanced, polarized, and influenced in its spectral shape, thereby demonstrating the coupling of the chromophore to the plasmonic nano-antenna. Furthermore, the challenges associated with the aqueous assembly of these complex mechanically interlocked molecules are exemplified by the synthesis of a first [2]rotaxane, which could not be isolated due to spontaneous decomposition of the superstructure in organic solvents. The successful synthesis of a [2]rotaxane as a model compound for the electrostatic field switching inside the gap of a plasmonic nano-antenna is described and its optical properties are discussed. The fluorescence quantum yield of the mechanically interlocked structure exceeds those of the rod component by about three times – an ideal property to observe positional changes of the cyclophaneʼs position on the axis triggered by the electrostatic field. The site-selective immobilization of these promising model compounds on monocrystalline Au(111) optical antennas is now under investigation and their behavior in electrostatic fields will be studied.

Experimental Section

Experimental procedures and analytical data for building blocks are provided in the Supporting Information. Spectra and NMR assignments are given in the Supporting Information. Macrocycle M was synthesized according to the literature-known procedure.[25] Chromophore 7 was previously described by our group.[26] Fabrication of the gold nano-antenna is briefly described in the Supporting Information.

Reagents and solvents were used as received from commercial suppliers (Sigma-Aldrich, Acros, Apollo Scientific, Alfa Aesar, Combi-Blocks, Fluorochem, and TCI Chemicals). Reactions were performed under an argon atmosphere. For column chromatography, Siliaflash P60 (40 – 63 µm) from Silicycle was used with technical-grade solvents (Biosolve). TLC was performed on silica gel 60 F254 aluminium sheets from Merck. ¹H NMR, ¹³C{¹H} NMR, and 2D NMR spectra were recorded at 298 K on Bruker Avance III NMR spectrometers equipped with either BBFO, BBI, or BBO probeheads operating at 400 or 500 MHz proton frequencies. For the rotaxane 8⊂M, NMR spectra were recorded at 298 K on a Bruker Avance III HD NMR spectrometer operating at 600 MHz proton frequency equipped with a QCI-F probehead. The chemical shifts are reported in ppm and referenced to the residual solvent peaks, with coupling constants (J) given in Hz. High-resolution electron spray ionization mass spectrometry (HR-ESI-MS) spectra were recorded on a maXis 4 G instrument from Bruker. UV-Vis absorption spectra were recorded on a Jasco V-770 spectrophotometer equipped with a Peltier-thermostatted cell holder (ETCR-762) set to 25 °C. Emission spectra in solution were recorded on a Jasco FP-8600 spectrofluorometer equipped with a Peltier-thermostatted cell holder (ETC-815) set to 25 °C. Quantum yields were determined on the same spectrofluorometer equipped with a nitrogen-flushed integrating sphere (ILFC-847S). Each measurement for quantum yield determination (blank solvent, direct excitation, indirect excitation) was repeated three times and the average of the three calculated quantum yields was taken.

Synthesis of 5: 3 (97.2 mg, 119 µmol, 1.0 equiv.) and 4 (74.9 mg, 119 µmol, 1.0 equiv.) were dissolved in a mixture of DMF/H₂O (1 : 1, 4 mL) and the resulting solution was degassed with argon for 15 min. TBTA (3.3 mg, 6 µmol, 5 mol%), Cu(CH₃CN)₄PF₆ (2.2 mg, 6 µmol, 5 mol%), and sodium ascorbate (1.2 mg, 6 µmol, 5 mol%) were added and the reaction mixture was stirred under argon overnight. The reaction mixture was directly subjected to reverse-phase column chromatography (C18-functionalized silica, 7 : 3 H₂O/ACN buffered with 20 mM NH₄OAc and 0.05% AcOH). The obtained red-orange solid contained acetamide, which was removed by two cycles of sonication in EtOH (20 mL) and subsequent centrifugation. The pure product 5 was obtained as an orange-red solid (60 mg, 35%) after drying in high vacuum.

¹H NMR (500 MHz, DMSO-d ₆): δ = 8.68 – 8.65 (m, 2 H), 8.39 (s, 1 H), 8.16 – 8.12 (m, 3 H), 8.06 (dd, J = 8.5, 1.7 Hz, 1 H), 8.03 (s, 2 H), 7.87 (d, J = 8.6 Hz, 2 H), 7.68 (d, J = 8.6 Hz, 2 H), 7.05 – 6.92 (m, 8 H) 4.72 (s, 4 H), 4.61 (t, J = 5.1 Hz, 2 H), 4.43 (t, J = 7.1 Hz, 4 H), 3.89 (t, J = 5.2 Hz, 2 H), 3.58 – 3.55 (m, 2 H), 3.53 – 3.43 (m, 46 H), 3.00 (t, J = 6.5 Hz, 2 H), 2.39 (dd, J = 8.2, 6.6 Hz, 4 H), 2.32 (s, 3 H), 2.11 – 2.04 (m, 4 H).

¹³C NMR (126 MHz, DMSO-d ₆): δ = 195.1, 163.8, 152.5, 148.3, 147.7, 145.6, 144.1, 144.0, 135.2, 131.1, 129.7, 128.9, 127.6, 125.9, 125.7, 124.6, 123.4, 123.1, 122.4, 118.5, 116.5, 113.0, 103.3, 69.8, 69.8, 69.7, 69.7, 69.7, 69.6, 69.6, 69.5, 68.9, 68.6, 68.6, 49.8, 48.5, 48.1, 45.6, 37.9, 30.5, 28.3, 26.5.

HRMS-ESI: m/z [M-2NH₄ + 5H]³⁺ calcd for (C₆₂H₉₀ N₁₄O₁₈S₄): 471.8378; found: 471.8378; m/z [M-2NH₄ + 4H]²⁺ calcd for (C₆₂H₉₀ N₁₄O₁₈S₄): 707.2527; found: 707.2541; m/z [2 M-4NH₄ + 7H]³⁺ calcd for (C₆₂H₉₀ N₁₄O₁₈S₄): 942.6679; found: 942.6689; m/z [M-2NH₄ + 3H]⁺ calcd for (C₆₂H₉₀ N₁₄O₁₈S₄): 1413.4982; found: 1413.4986.

UV/Vis (H₂O): λ_max = 271, 445 nm.

Fluorescence (H₂O): λ_max = 729 nm; Φ_fl = 0.6% (H₂O), 16.7% (DMSO).

Synthesis of 3,5-bis((triisopropylsilyl)ethynyl)phenol (S24): Reaction conditions were adapted from the literature.[37] 3,5-Dibromophenol (CAS Reg. No. 626 – 41 – 5, 1.26 g, 5.00 mmol, 1.0 equiv.), copper iodide (19 mg, 0.10 mmol, 2 mol%), Pd(PhCN)₂Cl₂ (77 mg, 0.20 mmol, 4 mol%), and HPtBu₃BF₄ (117 mg, 0.40 mmol, 8 mol%) were dissolved in anhydrous dioxane (15 mL) under an argon atmosphere and stirred at r. t. for 30 min. TIPS-acetylene (2.8 mL, 12.50 mmol, 2.5 equiv.) and (iPr)₂NH (3.5 mL, 25.0 mmol, 5.0 equiv.) in anhydrous dioxane (10 mL) were added to the reaction mixture and the resulting mixture was stirred at r. t. overnight. A solution of HCl (2 M) was added, the product extracted with EtOAc (3×) and the combined organic layers dried with Na₂SO₄, filtered, and the solvent evaporated. The crude product was purified by flash chromatography (gradient cyclohexane to cyclohexane/DCM 70 : 30). The pure product S24 was obtained as a colorless solid (1.96 g, 86%).

¹H NMR (400 MHz, CDCl₃): δ = 7.15 (t, J = 1.4 Hz, 1 H), 6.90 (d, J = 1.3 Hz, 2 H), 4.78 (s, 1 H), 1.12 (s, 47 H).

¹³C NMR (101 MHz, CDCl₃): δ = 155.0, 128.3, 125.0, 119.2, 105.8, 91.6, 18.8, 11.4.

HRMS-ESI: m/z [M + H]⁺ calcd for (C₂₈H₄₄OSi₂): 453.3014; found: 453.3024.

Synthesis of 3,5-diethynylphenol (S25): S24 (1.96 g, 4.31 mmol, 1.0 equiv.) in an argon-flushed flask was dissolved in TBAF solution (1 M in THF, 17.2 mL, 17.2 mmol, 4.0 equiv.) under argon and stirred overnight at room temperature. The solvent was evaporated, the residue was dissolved in TBME and sat. NH₄Cl solution, extracted with TBME (3×) and the extracts washed with sat. NH₄Cl solution, water, and brine. The organic layer was dried with Na₂SO₄, filtered, and the solvent evaporated. Purification by flash chromatography (gradient cyclohexane to DCM) and subsequent trituration of the solid with n-pentane gave the pure product S25 (406 mg, 66%) as a colorless fluffy solid after filtration and drying in high vacuum. The analytical data match the previously reported results.[38]

¹H NMR (400 MHz, CDCl₃): δ = 7.21 (t, J = 1.4 Hz, 1 H), 6.95 (d, J = 1.4 Hz, 2 H), 4.91 (s, 1 H), 3.07 (s, 2 H).

¹³C NMR (101 MHz, CDCl₃): δ = 155.2, 128.7, 123.8, 119.7, 82.4, 78.1.

HRMS-ESI: m/z [M – H]⁻ calcd for (C₁₀H₆O): 141.0346; found: 141.0348.

Synthesis of S26: S25 (131.9 mg, 0.928 mmol, 1.0 equiv.) and S13 (540.9 mg, 1.86 mmol, 2.0 equiv.) were dissolved in H₂O/acetone (1 : 4, 2.5 mL). CuSO₄ · 5 H₂O (23.2 mg, 0.093 mmol, 0.1 equiv.) and sodium ascorbate (37.5 mg, 0.186 mmol, 0.2 equiv.) were added under argon. The reaction mixture was stirred at r. t. for 3.5 h. The mixture was extracted with EtOAc (3×), the extracts washed with brine, dried with Na₂SO₄, filtered, and the solvent evaporated. The crude product was purified by flash chromatography (cyclohexane/acetone 1 : 1) to give the product S26 as a clear pale-yellow oil (575 mg, 86%).

¹H NMR (400 MHz, CDCl₃): δ = 8.07 (s, 2 H), 7.86 (t, J = 1.4 Hz, 1 H), 7.72 (s, 1 H), 7.45 (d, J = 1.5 Hz, 2 H), 4.59 (t, J = 4.9 Hz, 4 H), 3.94 – 3.87 (m, 4 H), 3.67 – 3.56 (m, 20 H), 2.71 (dd, J = 7.7, 7.0 Hz, 4 H), 1.28 (s, 18 H).

¹³C NMR (101 MHz, CDCl₃): δ = 157.6, 147.5, 132.7, 121.8, 114.9, 112.7, 71.1, 70.7, 70.7, 70.6, 70.3, 69.6, 50.5, 42.3, 31.1, 28.0.

HRMS-ESI: m/z [M + H]⁺ calcd for (C₃₄H₅₆ N₆O₇S₂): 725.3725; found: 725.3722; m/z [M + Na]⁺ calcd for (C₃₄H₅₆ N₆O₇S₂): 747.3544; found: 747.3546.

Synthesis of S27: To S26 (105 mg, 145 µmol, 1.0 equiv.), S12 (54 mg, 145 µmol, 1.0 equiv.), and K₂CO₃ (40 mg, 290 µmol, 2.0 equiv.) in a round-bottom flask was added DMF (2 mL) under an argon atmosphere. The reaction mixture was heated to 80 °C for 3 d, then allowed to cool to room temperature and extracted with EtOAc (3×). The extracts were dried with Na₂SO₄, filtered, and concentrated under reduced pressure. The crude product was purified by flash chromatography (gradient cyclohexane to cyclohexane/acetone 55 : 45) to give the pure product S27 as a clear pale-yellow oil (95 mg, 71%).

¹H NMR (400 MHz, CDCl₃): δ = 8.04 (s, 2 H), 7.87 (t, J = 1.4 Hz, 1 H), 7.42 (d, J = 1.4 Hz, 2 H), 4.60 (t, J = 5.0 Hz, 4 H), 4.27 (t, J = 4.8 Hz, 2 H), 3.96 – 3.87 (m, 6 H), 3.77 – 3.53 (m, 30 H), 3.37 (t, J = 5.1 Hz, 2 H), 2.69 (t, J = 7.3 Hz, 4 H), 1.28 (s, 18 H).

¹³C NMR (101 MHz, CDCl₃): δ = 159.7, 147.4, 132.7, 121.5, 115.7, 111.6, 71.2, 71.0, 70.9, 70.8, 70.8, 70.8, 70.7, 70.7, 70.4, 70.2, 69.9, 69.7, 67.8, 50.8, 50.6, 42.2, 31.1, 28.0.

HRMS-ESI: m/z [M + H]⁺ calcd for (C₄₂H₇₁ N₉O₁₀S₂): 926.4838; found: 926.4831; m/z [M + Na]⁺ calcd for (C₄₂H₇₁ N₉O₁₀S₂): 948.4658; found: 948.4653.

Synthesis of stopper 2: To a solution of S27 (83 mg, 89.6 µmol, 1.0 equiv.) in anhydrous ACN (1 mL) under argon was added acetyl chloride (0.68 mL, 9.4 mmol, 105 equiv.), followed by Bi(OTf)₃ (60 mg, 89.6 µmol, 1.0 equiv.). The reaction was stirred at r. t. for 5 min, then water was added, and the mixture was extracted with EtOAc (3 µ). The extracts were dried with Na₂SO₄, filtered, and concentrated under reduced pressure. The crude product was purified by reverse-phase HPLC (C-18, ACN/H₂O 65 : 35 + 0.1% HCO₂H) to give the product 2 as a clear colorless oil (40 mg, 50%). A side product was separated by HPLC and its analytical data and presumed structure are given in the Supporting Information.

¹H NMR (400 MHz, CDCl₃): δ = 8.04 (s, 2 H), 7.85 (t, J = 1.5 Hz, 1 H), 7.40 (d, J = 1.4 Hz, 2 H), 4.58 (t, J = 5.0 Hz, 4 H), 4.28 – 4.21 (m, 2 H), 3.93 – 3.86 (m, 6 H), 3.74 – 3.49 (m, 30 H), 3.35 (t, J = 5.1 Hz, 2 H), 3.01 (t, J = 6.5 Hz, 4 H), 2.28 (s, 6 H).

¹³C NMR (101 MHz, CDCl₃): δ = 195.6, 159.7, 147.2, 132.5, 121.5, 115.7, 111.5, 70.9, 70.8, 70.7, 70.7, 70.7, 70.6, 70.6, 70.3, 70.1, 69.8, 69.7, 69.5, 67.7, 50.7, 50.5, 30.6, 28.8.

HRMS-ESI: m/z [M + H]⁺ calcd for (C₃₈H₅₉ N₉O₁₂S₂): 838.3797; found: 898.3790; m/z [M + Na]⁺ calcd for (C₃₈H₅₉ N₉O₁₂S₂): 920.3617; found: 920.3620; m/z [M + K]⁺ calcd for (C₃₈H₅₉ N₉O₁₂S₂): 936.3356; found: 936.3352.

Synthesis of 8⊂M and 8: 7 [26] (8.0 mg, 10.8 µmol, 1.0 equiv.), M·2 Cl[25] (12.7 mg, 11.9 µmol, 1.1 equiv.), and 2 (12.0 mg, 13.4 µmol, 1.2 equiv.) were placed in a 25 mL round-bottom flask and flushed with argon. Degassed H₂O (10 mL) was added, the mixture was stirred for 5 min and CuSO₄ · 5 H₂O (4.5 mg, 18.0 µmol, 1.7 equiv.) and sodium ascorbate (10.0 mg, 49.5 µmol, 4.6 equiv.) were added. The mixture immediately turned turbid and showed formation of an orange precipitate. After stirring at room temperature for 2 h, the precipitate was collected by centrifugation. The crude product was purified by reverse-phase HPLC on C-18 functionalized silica (ACN/H₂O 40 : 60 + 0.5% HCO₂H), allowing the isolation of the pure rotaxane 8⊂M as an orange-red solid (6.0 mg, 21%). The product proved to be poorly soluble in H₂O or ACN, but well soluble in H₂O/ACN mixtures. The rod 8 eluted with the macrocycle M and further purification was necessary. Separation on Sephadex LH-20 (DMF/H₂O 1 : 1, 100 mM NH₄OAc) was unsuccessful. Cyclophane M was removed by trituration of the solid with saturated NH₄OAc solution in ACN. The solids were triturated with EtOH to remove excess NH₄OA c. The pure side product 8 was obtained as an orange-red solid (4.9 mg, 28%) after drying in high vacuum.

Analytical data for 8⊂M:

¹H NMR (600 MHz, DMSO-d6): δ = 8.88 (t, J = 5.7 Hz, 1 H), 8.63 (s, 2 H), 8.06 (s, 2 H), 7.98 (s, 1 H), 7.96 (t, J = 1.5 Hz, 1 H), 7.69 (s, 1 H), 7.38 (d, J = 1.4 Hz, 2 H), 6.85 – 6.74 (m, 10 H), 6.67 (d, J = 8.4 Hz, 2 H), 5.86 (d, J = 8.1 Hz, 2 H), 5.51 (d, J = 7.2 Hz, 2 H), 4.67 (s, 4 H), 4.58 (t, J = 5.2 Hz, 4 H), 4.54 – 4.48 (m, 8 H), 4.22 (t, J = 4.5 Hz, 2 H), 3.88 (t, J = 5.2 Hz, 4 H), 3.83 (t, J = 5.3 Hz, 2 H), 3.80 (t, J = 4.6 Hz, 2 H), 3.72 – 3.19 (m, 92 H, expected: 40 H, overlaps with H₂O, H4), 3.04 – 2.97 (m, 8 H), 2.94 (t, J = 6.5 Hz, 4 H), 2.44 (t, J = 7.2 Hz, 4 H), 2.29 (s, 6 H), 2.16 – 2.10 (m, 4 H), 1.25 – 1.12 (m, 24 H).

¹³C NMR (151 MHz, DMSO-d6): δ = 195.1, 161.1, 159.4, 152.9, 150.7, 147.8, 145.9, 144.4, 144.3, 143.4, 134.9, 132.8, 130.1, 127.5, 126.8, 125.3, 124.5, 123.5, 123.2, 122.3, 116.9, 114.4, 112.3, 110.4, 103.1, 101.9, 71.0, 70.0, 69.8, 69.7, 69.7, 69.6, 69.6, 69.5, 69.0, 68.8, 68.8, 68.6, 67.3, 55.6, 55.2, 55.0, 49.7, 49.3, 48.5, 47.9, 45.7, 42.9, 35.4, 30.5, 28.2, 27.7, 26.6, 25.2, 7.0.

HRMS-ESI: m/z [M + 3H]³⁺ calcd for (C₁₂₇H₁₇₄ N₂₀O₃₁S₄): 868.7252; found: 868.7268; m/z [M + Na]⁺ calcd for (C₁₂₇H₁₇₄ N₂₀O₃₁S₄): 1302.5841; found: 1302.5861.

UV/Vis: λ_max = 422 nm (H₂O), 426 nm (DMSO).

Fluorescence: λ_max = 654 nm (H₂O), 635 nm (DMSO); Φ_fl = 6.5% (H₂O), 65.7% (DMSO).

Analytical data for 8:

¹H NMR (500 MHz, DMSO-d6) δ 8.97 (t, J = 5.7 Hz, 1 H), 8.62 (s, 2 H), 8.16 (s, 1 H), 8.01 (s, 2 H), 7.98 – 7.93 (m, 4 H), 7.79 (d, J = 8.2 Hz, 2 H), 7.61 (d, J = 8.5 Hz, 2 H), 7.37 (d, J = 1.5 Hz, 2 H), 7.18 (s, 1 H, NH₄ ⁺), 7.00 (d, J = 8.5 Hz, 2 H), 4.70 (s, 4 H), 4.57 (t, J = 5.2 Hz, 4 H), 4.49 (t, J = 5.3 Hz, 2 H), 4.47 – 4.40 (m, 6 H), 4.20 (t, J = 4.6 Hz, 2 H), 3.88 (t, J = 5.2 Hz, 4 H), 3.82 – 3.75 (m, 4 H), 3.61 – 3.43 (m, 22 H), 3.41 (t, J = 6.5 Hz, 4 H), 2.94 (t, J = 6.4 Hz, 4 H), 2.40 (dd, J = 8.3, 6.5 Hz, 4 H), 2.29 (s, 6 H), 2.12 – 2.03 (m, 4 H).

¹³C NMR (101 MHz, DMSO-d6) δ 195.1, 161.4, 159.3, 150.2, 148.2, 145.9, 144.3, 144.1, 137.7, 134.3, 132.7, 130.9, 129.1, 127.5, 126.0, 125.7, 123.5, 123.1, 122.3, 116.7, 114.3, 113.0, 110.5, 104.0, 70.0, 69.8, 69.6, 69.6, 69.5, 69.5, 68.9, 68.8, 68.7, 68.6, 67.3, 49.7, 49.3, 48.5, 48.0, 45.6, 35.3, 30.5, 28.2, 26.5.

HRMS-ESI: m/z [M + 2H + 2Na-2NH₄]²⁺ calcd for (C₆₉H₉₈ N₂₀O₁₉S₄): 825.2727; found: 825.2735; m/z [M + 1H + 3Na-2NH₄]²⁺ calcd for (C₆₉H₉₈ N₂₀O₁₉S₄): 836.2636; found: 836.2651; m/z [M + 4Na-2NH₄]²⁺ calcd for (C₆₉H₉₈ N₂₀O₁₉S₄): 847.2546; found: 847.2563; m/z [M + 2H + 1Na-2NH₄]⁺ calcd for (C₆₉H₉₈ N₂₀O₁₉S₄): 1627.5561; found: 1627.5535; m/z [M + H + 2Na-2NH₄]⁺ calcd for (C₆₉H₉₈ N₂₀O₁₉S₄): 1649.5381; found: 1649.5352; m/z [M + 3Na-2NH₄]⁺ calcd for (C₆₉H₉₈ N₂₀O₁₉S₄): 1671.5200; found: 1671.5183.

UV/Vis: λ_max = 412 nm (H₂O, ε = 18 645 M⁻¹ · cm⁻¹), 417 nm (DMSO).

Fluorescence: λ_max = 671 nm (H₂O), 652 nm (DMSO); Φ_fl = 2.2% (H₂O), 20.5% (DMSO).

Funding Information

This project was generously funded by the Volkswagen Foundation (Az. 93 438).

Conflict of Interest

The authors declare no conflict of interest.

Acknowledgment

We thank Monika Emmerling for preparing gold flakes and substrates.

• References

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• 34 Ming T, Zhao L, Yang Z, Chen H, Sun L, Wang J, Yan C. Nano Lett. 2009; 9: 3896
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• 35 Aeschi Y, Drayss-Orth S, Valášek M, Häussinge D, Mayor M. Chem. Eur. J. 2019; 25: 285
  CrossrefPubMed
• 36 Ferguson SB, Sanford EM, Seward EM, Diederich F. J. Am. Chem. Soc. 1991; 113: 5410
  CrossrefPubMed
• 37 Zhang Y, Zhao C, Yang J, Kapiamba M, Haze O, Rothberg LJ, Ng M-K. J. Org. Chem. 2006; 71: 9475
  CrossrefPubMed
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Correspondence

Publication History

Received: 01 July 2022

Accepted after revision: 14 August 2022

Accepted Manuscript online:
22 August 2022

Article published online:
20 September 2022

© 2022. The authors. This is an open access article published by Thieme under the terms of the Creative Commons Attribution-NonDerivative-NonCommercial License, permitting copying and reproduction so long as the original work is given appropriate credit. Contents may not be used for commercial purposes, or adapted, remixed, transformed or built upon. (https://creativecommons.org/licenses/by-nc-nd/4.0/)

Georg Thieme Verlag KG
Rüdigerstraße 14, 70469 Stuttgart, Germany

• References

• 1 Bruns CJ, Stoddart JF. The Nature of the Mechanical Bond: From Molecules to Machines. Hoboken, New Jersey: Wiley; 2017
  Google Scholar
• 2 Kay ER, Leigh DA, Zerbetto F. Angew. Chem. Int. Ed. 2007; 46: 72
  CrossrefPubMed
• 3 Xue M, Yang Y, Chi X, Yan X, Huang F. Chem. Rev. 2015; 115: 7398
  CrossrefPubMed
• 4 Yao B, Sun H, Yang L, Wang S, Liu X. Front. Chem. 2022; 9. DOI: 10.3389/fchem.2021.832735.
  CrossrefPubMed
• 5 Schröder HV, Schalley CA. Chem. Sci. 2019; 10: 9626
  CrossrefPubMed
• 6 Tian H, Wang Q-C. Chem. Soc. Rev. 2006; 35: 361
  CrossrefPubMed
• 7 Aprahamian I. ACS Cent. Sci. 2020; 6: 347
  CrossrefPubMed
• 8 Coronado E, Gaviña P, Tatay S. Chem. Soc. Rev. 2009; 38: 1674
  CrossrefPubMed
• 9 Bermudez V, Capron N, Gase T, Gatti FG, Kajzar F, Leigh DA, Zerbetto F, Zhang S. Proc. SPIE 2000; 4106: 194
  CrossrefPubMed
• 10 Bermudez V, Capron N, Gase T, Gatti FG, Kajzar F, Leigh DA, Zerbetto F, Zhang S. Nature 2000; 406: 608
  CrossrefPubMed
• 11 Sánchez-Quesada J, Saghatelian A, Cheley S, Bayley H, Ghadiri MR. Angew. Chem. Int. Ed. 2004; 43: 3063
  CrossrefPubMed
• 12 Biesemans A, Soskine M, Maglia G. Nano Lett. 2015; 15: 6076
  CrossrefPubMed
• 13 Chu J, González-López M, Cockroft SL, Amorin M, Ghadiri MR. Angew. Chem. Int. Ed. 2010; 49: 10106
  CrossrefPubMed
• 14 Cockroft SL, Chu J, Amorin M, Ghadiri MR. J. Am. Chem. Soc. 2008; 130: 818
  CrossrefPubMed
• 15 Feng J, Martin-Baniandres P, Booth MJ, Veggiani G, Howarth M, Bayley H, Rodriguez-Larrea D. Commun. Biol. 2020; 3: 1
  CrossrefPubMed
• 16 Prangsma JC, Kern J, Knapp AG, Grossmann S, Emmerling M, Kamp M, Hecht B. Nano Lett. 2012; 12: 3915
  CrossrefPubMed
• 17 Biagioni P, Huang J-S, Hecht B. Rep. Prog. Phys. 2012; 75: 024402
  CrossrefPubMed
• 18 Kern J, Kullock R, Prangsma J, Emmerling M, Kamp M, Hecht B. Nat. Photonics 2015; 9: 582
  CrossrefPubMed
• 19 Kullock R, Ochs M, Grimm P, Emmerling M, Hecht B. Nat. Commun. 2020; 11: 115
  CrossrefPubMed
• 20 Francisco AP, Botequim D, Prazeres DMF, Serra VV, Costa SMB, Laia CAT, Paulo PMR. J. Phys. Chem. Lett. 2019; 10: 1542
  CrossrefPubMed
• 21 Bardhan R, Grady NK, Cole JR, Joshi A, Halas NJ. ACS Nano 2009; 3: 744
  CrossrefPubMed
• 22 Anger P, Bharadwaj P, Novotny L. Phys. Rev. Lett. 2006; 96: 113002
  CrossrefPubMed
• 23 Chi YS, Byon HR, Lee BS, Kong B, Choi HC, Choi IS. Adv. Funct. Mater. 2008; 18: 3395
  CrossrefPubMed
• 24 Ferguson SB, Seward EM, Diederich F, Sanford EM, Chou A, Inocencio-Szweda P, Knobler CB. J. Org. Chem. 1988; 53: 5593
  CrossrefPubMed
• 25 Anderson S, Aplin RT, Claridge TDW, Goodson III T, Maciel AC, Rumbles G, Ryan JF, Anderson HL. J. Chem. Soc., Perkin Trans. 1 1998; 2383
  CrossrefPubMed
• 26 Jucker L, Aeschi Y, Mayor M. Org. Chem. Front. 2021; 8: 4399
  CrossrefPubMed
• 27 Taylor PN, Hagan AJ, Anderson HL. Org. Biomol. Chem. 2003; 1: 3851
  CrossrefPubMed
• 28 Anderson S, Anderson HL. Angew. Chem. Int. Ed. Engl. 1996; 35: 1956
  CrossrefPubMed
• 29 Aeschi Y, Drayss-Orth S, Valášek M, Raps F, Häussinger D, Mayor M. Eur. J. Org. Chem. 2017; 2017: 4091
  CrossrefPubMed
• 30 Aeschi Y, Jucker L, Häussinger D, Mayor M. Eur. J. Org. Chem. 2019; 2019: 3384
  CrossrefPubMed
• 31 Béthencourt MI, Srisombat L, Chinwangso P, Lee TR. Langmuir 2009; 25: 1265
  CrossrefPubMed
• 32 Zhao L, Ming T, Chen H, Liang Y, Wang J. Nanoscale 2011; 3: 3849
  CrossrefPubMed
• 33 Ringler M, Schwemer A, Wunderlich M, Nichtl A, Kürzinger K, Klar TA, Feldmann J. Phys. Rev. Lett. 2008; 100: 203002
  CrossrefPubMed
• 34 Ming T, Zhao L, Yang Z, Chen H, Sun L, Wang J, Yan C. Nano Lett. 2009; 9: 3896
  CrossrefPubMed
• 35 Aeschi Y, Drayss-Orth S, Valášek M, Häussinge D, Mayor M. Chem. Eur. J. 2019; 25: 285
  CrossrefPubMed
• 36 Ferguson SB, Sanford EM, Seward EM, Diederich F. J. Am. Chem. Soc. 1991; 113: 5410
  CrossrefPubMed
• 37 Zhang Y, Zhao C, Yang J, Kapiamba M, Haze O, Rothberg LJ, Ng M-K. J. Org. Chem. 2006; 71: 9475
  CrossrefPubMed
• 38 Ghosh K, Yang H-B, Northrop BH, Lyndon MM, Zheng Y-R, Muddiman DC, Stang PJ. J. Am. Chem. Soc. 2008; 130: 5320
  CrossrefPubMed

• Supplementary Material