Cation Recognition by Self-Assembled Layers of Novel Crown-Annelated Tetrathiafulvalenes

Moore, Adrian J.; Goldenberg, Leonid M.; Petty, Michael C.; Monkman, Andrew P.; Marenco, Claudia; Yarwood, J.; Joyce, Malcolm J.; Port, Simon N.

doi:10.1002/(sici)1521-4095(199803)10:5<395::aid-adma395>3.3.co;2-9

Cited by 34 publications

(64 citation statements)

References 7 publications

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“…Relatively recently, Reinhoudt et al (19)(20)(21)(22) and Bryce et al (23,24) reported, almost simultaneously, the incorporation of crownether groups into SAMs and their use as potential metal ion sensors. The Reinhoudt group used electrochemical impedance spectroscopy (EIS) for SAM characterization and to study the ion recognition processes (19)(20)(21)(22).…”

supporting

confidence: 57%

“…25 and 26). The report by Bryce et al (23,24) described SAMs of crown-annelated tetrathiafulvalene (TTF) derivatives, which showed, by cyclic voltammetry (CV), a redox potential shift of the electroactive, surface-confined, crown-TTF group on ion complexation (23,24). The first TTF-crown SAMs reported by this group were apparently unstable after several electrochemical scans (23).…”

mentioning

confidence: 99%

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Metal ion recognition and molecular templating in self-assembled monolayers of cyclic and acyclic polyethers

Herranz

Colonna

Echegoyen

2002

Proc. Natl. Acad. Sci. U.S.A.

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Our recent work with cyclic and acyclic polyether self-assembled monolayers (SAMs) on gold is presented. A series of dithia-crowntetrathiafulvalene derivatives with one or two disulfide groups has been prepared, and their SAMs on gold have been characterized by electrochemistry and by reflection-absorption infrared spectroscopy. These SAMs are extremely stable on repeated electrochemical potential scans and can selectively recognize alkali metal ions. Acyclic polyether derivatives can also self-assemble on gold to yield selective metal ion recognition domains. Impedance spectroscopy data for these SAMs fit the Langmuir isotherm and allow the determination of ion association constants. Some of the SAMs prepared with new acyclic polyether derivatives are able to detect potassium cations selectively when templated in their presence. These structures are believed to be a consequence of ion ''imprinting'' during the process of SAM formation.T he easy preparation, stability, and versatility of self-assembled monolayers (SAMs) has resulted in considerable activity in this field since the first publication by Nuzzo and Allara (1). Molecular recognition is especially relevant on surfaces because it allows the control of the exchange of signals, structures, and energy through the interfaces (2-4). SAMs allow the introduction of functional groups in the adsorbates, thus offering a powerful way to develop systems that have applications as sensors, devices, and switches (5). Some recent articles have reported surface structures with hydrophobic and hydrophilic properties arranged in nano-strips and honeycomb or homogeneous structures (6), whereas others have detected photo and electrochemical conversion of cis to trans forms within the SAM (7). Other examples have shown the formation of chiral imprinted sites (8). SAM structures have also been prepared for the recognition and sensing of metal ions (9), some of which are electrochemically active (10-18).Relatively recently, and Bryce et al. (23,24) reported, almost simultaneously, the incorporation of crownether groups into SAMs and their use as potential metal ion sensors. The Reinhoudt group used electrochemical impedance spectroscopy (EIS) for SAM characterization and to study the ion recognition processes (19)(20)(21)(22). This technique enables the detection of interfacial ion recognition phenomena when both guest ion and host monolayer are electrochemically inactive, by detecting changes of the charge-transfer resistance induced by metal ion binding (see Fig. 1a; refs. 25 and 26). The report by Bryce et al. (23,24) described SAMs of crown-annelated tetrathiafulvalene (TTF) derivatives, which showed, by cyclic voltammetry (CV), a redox potential shift of the electroactive, surface-confined, crown-TTF group on ion complexation (23, 24). The first TTF-crown SAMs reported by this group were apparently unstable after several electrochemical scans (23). However, in a subsequent report they demonstrated that the stability and electrochemical behavior of the SAMs can be improv...

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supporting

confidence: 57%

mentioning

confidence: 99%

Metal ion recognition and molecular templating in self-assembled monolayers of cyclic and acyclic polyethers

Herranz

Colonna

Echegoyen

2002

Proc. Natl. Acad. Sci. U.S.A.

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“…This proposed organisation within the monolayer is not only a function of the behaviour of, and interaction between the molecules themselves, but also the interaction between the molecules and the surface [26]. Stable redox chemistry in self-assembled monolayers of TTF derivatives have been reported by several groups including those of Bryce, Ward, Cooke, Sallé, Echegoyen and Stoddart, where the core TTF moiety is anchored to the surface using a surface active functional group such as an alkyl chain with a thiol end group on Au [13,14,[27][28][29][30], thioctic acid disulfide linkers on Au [31][32][33] and oxide-free hydrogen-terminated Si(1 0 0) surfaces [34]. Non-covalent binding of TTF derivatives on graphite has also been reported where the molecule's core TTF unit has a strong interaction with the -system of the graphite surface; this allows the molecule to orientate parallel to the graphite surface through -interactions [35,36].…”

Section: Introductionsupporting

confidence: 65%

“…The non-aromatic 14 -electron system undergoes aromatisation when going from the neutral species to the dithiolium form in the singly and doubly oxidised states. TTF and its derivatives have featured in a wide variety of applications from crown-ether annelated electrochemical sensors [13][14][15][16], to molecular electronics [17][18][19][20][21] including organic field-effect transistors [22] and other advanced molecular assemblies [23][24][25].…”

Section: Introductionmentioning

confidence: 99%

Electrochemistry and time dependent DFT study of a (vinylenedithio)-TTF derivative in different oxidation states

Halpin

Schulz

Brooks

et al. 2013

Electrochimica Acta

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a b s t r a c tThe electrochemical and spectroelectrochemical properties of a bis-pyrid-4-yl functionalised vinylenedithio-TTF derivative, 1, in solution are reported. The compound was immobilised on a Pt electrode and the resulting layers formed were investigated using electrochemical techniques. Two oxidation processes were observed for 1, typical of TTF derivatives. A solvent dependence study revealed that the stabilisation of the radical cation intermediate, 1• + , towards further oxidation is achieved in solvents with a low Gutmann donor number such as dichloromethane. Analysis of 1 2+ in solution under aerobic and anaerobic conditions reveal that its stability is compromised in the presence of oxygen and therefore the stability of monolayers of 1 is greatly enhanced under anaerobic conditions. Time dependent DFT calculations of the compound in several oxidation states are discussed to obtain information on the location of the various redox processes.

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“…9,10 We recently prepared TEG (triethylene glycol monomethyl ether)-and PEG (polyethylene glycol monomethyl ether)-end-grafted carbosiloxane and carbosilane dendrimers and studied their ability to detect alkali metal-ion binding. 11 The general idea was to use the glycols to form ion binding domains at the periphery (similar to crown ethers) via self assembly.…”

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confidence: 99%

Triethylene Glycol Ether End-grafted Carbosilane Dendrimer: A Potential Ionophore for Potassium Ion Recognition

2006

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Ion-selective electrodes have many advantages in the ion activity determining process, i.e., direct and real-time monitoring of samples is possible. The key ingredient of plasticized PVC membranes is the incorporated ionophore, which defines the selectivity of the electrodes via selective complex formation with the cation of interest. The design and synthesis of neutral carriers/ionophores have become important in the field of host-guest chemistry. The most widely used ionselective electrode (ISE) for determining potassium is based on antibiotic valinomycin.1 Other carriers including crown ethers 2-5 substituted ethers of tetraethyleneglycol, 6 organo-phosphine ligands 7 and polymer supported liquid crystal membranes 8 have also been successfully applied as carriers for constructing potassium ISEs.The incorporation of crown ether groups into self-assembled monolayers (SAMs) and their potential use as metal-ion sensors was reported. 9,10 We recently prepared TEG (triethylene glycol monomethyl ether)-and PEG (polyethylene glycol monomethyl ether)-end-grafted carbosiloxane and carbosilane dendrimers and studied their ability to detect alkali metal-ion binding. 11 The general idea was to use the glycols to form ion binding domains at the periphery (similar to crown ethers) via self assembly. Apart from the ionophore topology, other membrane constituents, such as additive and plasticizers, also play a vital role in the performance of an ion sensor.Brodbelt et al. first described the use of electrospray ionization mass spectrometry (ESI-MS) as an easy way to obtain, in general, information about binding selectivities in host-guest compounds, such as crown ether or cryptand metal complexes.12,13 The minimal sample consumption and the rapid feedback are the advantages of this method. The obtained results could provide essential information regarding the use of compounds as potential ionophore in ion-selective electrodes (ISEs).In this publication, we describe the use of ESI-TOF mass spectrometry for preliminary screening a triethylene glycolfunctionalized carbosilane for the selective complexation of alkali metal ions.Based on information from mass spectrometric studies, we decided to use Si[CH2CH2CH2-Si(Me)2CH2CH2CH2(OCH2CH2)3Me]4 (1) as an ionophore in the fabrication of a PVC-based membrane electrode. We already reported on the synthesis and characterization of 1 in an earlier publication.11 Carbosilane dendrimers are expected to have high selectivity probably due to the fact that they are very stable towards hydrolysis, which makes them more suitable to be used as ionophores. The number of alkaline metal cations that can be coordinated depends on the number of peripheric TEG groups attached to the carbosilane. This paper reports on the cation selective properties and potentiometric response characteristics of 1 with various membrane components. The results indicate that the electrode offers a wide linear response range, and high selectivity and sensitivity to potassium. ExperimentalReagents and equipment ESI-TOF exp...

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Cation Recognition by Self-Assembled Layers of Novel Crown-Annelated Tetrathiafulvalenes

Cited by 34 publications

References 7 publications

Metal ion recognition and molecular templating in self-assembled monolayers of cyclic and acyclic polyethers

Metal ion recognition and molecular templating in self-assembled monolayers of cyclic and acyclic polyethers

Electrochemistry and time dependent DFT study of a (vinylenedithio)-TTF derivative in different oxidation states

Triethylene Glycol Ether End-grafted Carbosilane Dendrimer: A Potential Ionophore for Potassium Ion Recognition

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