Rotaxanes and pseudorotaxanes with threads containing viologen units

Deska, Małgorzata; Kozłowska, Jolanta; Śliwa, Wanda

doi:10.3998/ark.5550190.0014.102

Cited by 4 publications

(2 citation statements)

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“…Viologen cations (V 2+ , N,N ′-disubstituted 4,4′-bipyridiniums) are electron-deficient species exhibiting excellent charge-transfer and redox properties with photoactivity . The availability of three oxidation states (V 2+ , V •+ , and V 0 ) has evoked much interest in the study of viologens as catalysts or electron relays in chemical or photochemical redox systems and as chemo-/electro-/photoresponsive materials for applications such as electrochromic display, smart windows, molecular machines, and switches .…”

Section: Introductionmentioning

confidence: 99%

Magnetic and Photochromic Properties of a Manganese(II) Metal-Zwitterionic Coordination Polymer

et al. 2015

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The solvothermal reaction of Mn(ClO4)2, NaN3, and a rigid viologen-tethered tetracarboxylic acid (1,1'-bis(3,5-dicarboxyphenyl)-4,4'-bipyridinium chloride, [H4L]Cl2) led to a coordination polymer of formula [Mn4(L)(N3)6(H2O)2]n. X-ray analysis revealed a 3D coordination structure. The Mn(II) ions are connected by mixed azide and carboxylate bridges to give 2D layers, which are pillared by the viologen tether of the zwitterionic ligand. Magnetic analyses suggested that the compound features antiferromagnetism and field-induced metamagnetism. The compound also shows photochromic and photomagnetic properties. The long-range magnetic ordering is owed to the spin-canting structure of the Mn(II)-azide-carboxylate layer; the photochromism involves the formation of viologen radicals via photoinduced electron transfer, and the photomagnetism is related to the interactions between the metal ion and the photogenerated radicals. The study demonstrates a strategy for the design of new multifunctional materials with photoresponsive properties.

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Section: Introductionmentioning

confidence: 99%

Magnetic and Photochromic Properties of a Manganese(II) Metal-Zwitterionic Coordination Polymer

et al. 2015

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“…Polyester 1 (Figure ) derived from bis( m- phenylene-32-crown-10 diacid and bisphenol-A was on hand from previous studies. , Viologen 2 (Figure ), also used previously, was fitted with two terminal NMP species in the form of TEMPO units. As noted above, viologens (N,N′-dialkyl-4,4′-dipyridinium salts) are known to form pseudorotaxanes with bis( m- phenylene)-32-crown-10 species and other crown ethers. − In these experiments, styrene was chosen as the brush monomer; it undergoes smooth NMP. − Polyester 1 and one-half molar equivalent (relative to the crown moieties) of viologen 2 were dissolved in styrene to form a yellow solution, indicative of pseudorotaxane formation as previously reported. ,,,,,,, In two different experiments, the present solutions were immersed in an oil bath held at 120 °C to initiate NMP. In the first experiment, the reaction was allowed to proceed for 16 h, and in the second experiment polymerization was limited to 4 h, leading to products containing high- and low-molecular-weight polystyrene brushes, 3a and 3b , respectively (Figure ).…”

Section: Resultsmentioning

confidence: 74%

Synthesis of Bottlebrush Copolymers Using a Polypseudorotaxane Intermediate

2022

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A new paradigm for the synthesis of bottlebrush copolymers is introduced. A polyester containing a crown ether moiety in each repeat unit efficiently forms a pseudorotaxane in styrene solution with a viologen (N,N′-dialkyl-4,4′-bipyridinium salt) fitted at each end with initiators for nitroxide-mediated polymerization. Heating brings about polymerization of the styrene, producing a bottlebrush polymer in which narrow polydispersity polystyrene macromolecules are attached to the viologen threaded through the macrocyclic units of the polyester. This protocol allows control of the average spacing of the brushes (via stoichiometry) and their nature (by monomer selection) and length (by kinetic control), thus providing the ability to produce bottlebrush polymers of the same or similar architectures and brush lengths, but different arm compositions on the same backbone polymer. The concept can be broadened to other backbones, other host−guest systems, and other chain growth polymerization methodologies.

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