Conformational flexibility of xanthene‐based covalently linked dimers

Abstract: The conformational flexibility of three covalently linked dimers consisting of two xanthene‐based moieties connected by a diphenyl ether linker was studied using NMR spectroscopy, X‐ray crystallography, and density functional theory (DFT) calculations. The three dimers interconvert as a function of pH: the doubly cationic dimer (Xan+)2 exists in acidic solutions (pH < 0.5), the mono‐alcohol monocation Xan+–Xan‐OH at intermediate pH values (pH = 1–3), and the neutral diol at the highest pH‐values (pH > 3). Each… Show more

“…The instability of the C form of BP(OH) 2 was not investigated further. It might involve an intramolecular Friedel‐Crafts reactivity as was observed previously for the DPE(OH) 2 dication …”

“…As pH is decreased, the PB form of XAN(OH) 2 is formed and can be identified by its absorption bands at 363 and 460 nm. The PB pK a values were determined from photometric titration data and were found to correlate with the electronic factors that affect the stability of the cationic forms: pK a = 1.3 for MONO(OH), pK a1 = 0.2 and pK a2 = 2.6 for DPE(OH) 2 , pK a1 = 1.3 and pK a2 = 3.5 for XAN(OH) 2 (Figure B). It was found that the cationic forms of MONO(OH) and DPE(OH) 2 react readily with water to form PB derivatives, while the equivalent conversion of XAN(OH) 2 required several hours and elevated temperatures.…”

“…Comparison of relative energies of the In‐In , In‐Out , and Out‐Out conformers indicates that the most stable conformation of DPE(OH) 2 is the In‐Out structure, while XAN(OH) 2 and BP(OH) 2 adopt the desirable In‐In structure as their most stable form. The stabilization of the In‐In structure relative to the other conformers is most pronounced for BP(OH) 2 .…”

“…Three types of linkers were investigated, namely, diphenyl ether, xanthene, and biphenyl. The conformational analysis of DPE(OH) 2 has been reported previously, and it was found that the diphenyl linker is flexible, enabling the relatively fast rotation of two alcohol units . In this work, we extend the conformational analysis to additional model dimers, XAN(OH) 2 and BP(OH) 2 , and investigate the relative orientation of two alcohol moieties using X‐ray crystallography, NMR spectroscopy, and density functional theory (DFT) calculations.…”

“…The compound was synthesized according to a previously published procedure . 1 H NMR (500 MHz, DMSO‐ d6 ) δ H 5.66 (d, J = 8.8 Hz, 2 H, H12), 6.02 (s, 2 H, OH), 6.87‐7.06 (m, 14 H, H2, H2′, H11, H10, H5, H4, and H4′), 7.13‐7.18 (m, 4 H, H3′, and H5′), 7.26 (m, 2 H, H3), 7.53 (d, J = 7.3 Hz, 2 H, H9) 13 C NMR (125 MHz, DMSO‐ d6 ) δ C 68.23 (C7), 116.07 (C2′), 116.64 (C2), 118.54 (C6′), 120.93 (C12), 122.90 (C11), 123.08 (C10), 127.52 (C9), 128.02 (C3′), 128.60 (C5′, C5), 128.64 (C4′), 128.77 (C3), 128.80 (C6), 128.87 (C4), 138.40 (C8), 149.52 (C1), 149.74 (C1′), 155.10 (C13).…”

Conformational analysis of diols: Role of the linker on the relative orientation of hydroxyl groups

“…The instability of the C form of BP(OH) 2 was not investigated further. It might involve an intramolecular Friedel‐Crafts reactivity as was observed previously for the DPE(OH) 2 dication …”

“…As pH is decreased, the PB form of XAN(OH) 2 is formed and can be identified by its absorption bands at 363 and 460 nm. The PB pK a values were determined from photometric titration data and were found to correlate with the electronic factors that affect the stability of the cationic forms: pK a = 1.3 for MONO(OH), pK a1 = 0.2 and pK a2 = 2.6 for DPE(OH) 2 , pK a1 = 1.3 and pK a2 = 3.5 for XAN(OH) 2 (Figure B). It was found that the cationic forms of MONO(OH) and DPE(OH) 2 react readily with water to form PB derivatives, while the equivalent conversion of XAN(OH) 2 required several hours and elevated temperatures.…”

“…Comparison of relative energies of the In‐In , In‐Out , and Out‐Out conformers indicates that the most stable conformation of DPE(OH) 2 is the In‐Out structure, while XAN(OH) 2 and BP(OH) 2 adopt the desirable In‐In structure as their most stable form. The stabilization of the In‐In structure relative to the other conformers is most pronounced for BP(OH) 2 .…”

“…Three types of linkers were investigated, namely, diphenyl ether, xanthene, and biphenyl. The conformational analysis of DPE(OH) 2 has been reported previously, and it was found that the diphenyl linker is flexible, enabling the relatively fast rotation of two alcohol units . In this work, we extend the conformational analysis to additional model dimers, XAN(OH) 2 and BP(OH) 2 , and investigate the relative orientation of two alcohol moieties using X‐ray crystallography, NMR spectroscopy, and density functional theory (DFT) calculations.…”

“…The compound was synthesized according to a previously published procedure . 1 H NMR (500 MHz, DMSO‐ d6 ) δ H 5.66 (d, J = 8.8 Hz, 2 H, H12), 6.02 (s, 2 H, OH), 6.87‐7.06 (m, 14 H, H2, H2′, H11, H10, H5, H4, and H4′), 7.13‐7.18 (m, 4 H, H3′, and H5′), 7.26 (m, 2 H, H3), 7.53 (d, J = 7.3 Hz, 2 H, H9) 13 C NMR (125 MHz, DMSO‐ d6 ) δ C 68.23 (C7), 116.07 (C2′), 116.64 (C2), 118.54 (C6′), 120.93 (C12), 122.90 (C11), 123.08 (C10), 127.52 (C9), 128.02 (C3′), 128.60 (C5′, C5), 128.64 (C4′), 128.77 (C3), 128.80 (C6), 128.87 (C4), 138.40 (C8), 149.52 (C1), 149.74 (C1′), 155.10 (C13).…”

Conformational analysis of diols: Role of the linker on the relative orientation of hydroxyl groups

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