Organic fluorine compounds: a great opportunity for enhanced materials properties

Berger, Ricarda; Resnati, Giuseppe; Metrangolo, Pierangelo; Weber, Edwin; Hulliger, Jürg

doi:10.1039/c0cs00221f

Cited by 1,268 publications

(776 citation statements)

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“…The effects of fluorination on molecular properties are well established, and their use in compound property optimisation in many fields like material 1, 2 and medicinal chemistry, [3][4][5][6] as well as crystal engineering 7,8 and agrochemistry 9,10 benefit from this strong influence. After the debate about the effective ability of fluorine to act as a hydrogen-bond (H-bond, HB) acceptor, [11][12][13][14][15] the occurrence of intermolecular OHF H-bonding is now clearly established through experimental and theoretical evidences.…”

Section: Introductionmentioning

confidence: 99%

α‐Fluoro‐o‐cresols: The Key Role of Intramolecular Hydrogen Bonding in Conformational Preference and Hydrogen‐Bond Acidity

et al. 2016

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The conformational preferences of o-cresols driven by fluorination have been thoroughly investigated from a theoretical point of view with quantum chemical methods and compared to those recently reported for benzyl alcohols. Key conformers of both families exhibit a 6-membered intramolecular hydrogen-bond (IMHB) interaction. A significant enhancement of IMHB strength is observed in -fluoro-o-cresols, owing to the simultaneous increase of the aliphatic fluorine hydrogen-bond (HB) basicity and of the aromatic hydroxyl HB acidity, compared to o-fluorobenzyl alcohols, which are characterized by aromatic fluorine atoms and aliphatic hydroxyl groups. In the case of di-and trifluorinated derivatives, the occurrence of a three-centre hydrogen-bond is emphasised and its features discussed. The impact of these structural predilections on ocresol HB properties has been characterised from the estimation of the HB acidity parameter, pKAHY, weighted according to their conformational populations. We find that -fluorination leads to an HB acidity decrease of the hydroxyl group (in contrast with o-fluorination of benzyl alcohols), whereas ,-difluorination results in no significant variation of pKAHY. Finally, an increase of HB acidity is predicted upon methyl perfluorination, which has been confirmed experimentally. Theoretical descriptors based on AIM, NCI and NBO analyses allows rationalizing the predicted trends, and reveal a relationship with the strength of the established OHF IMHB.

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Section: Introductionmentioning

confidence: 99%

α‐Fluoro‐o‐cresols: The Key Role of Intramolecular Hydrogen Bonding in Conformational Preference and Hydrogen‐Bond Acidity

et al. 2016

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“…It is known that fluorinated compounds are often only miscible in each other; this is often referred to as the fluorous effect. 12 While the fluorous effect is usually used to describe the mixing of neutral species, there is evidence of similar effects in mixtures of fluorinated ionic compounds and fluorinated polymers. 13 Our work is a departure from the traditional approach of exploiting interactions between the solvent and the cation.…”

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confidence: 99%

Effect of Anion Size on Conductivity and Transference Number of Perfluoroether Electrolytes with Lithium Salts

Shah

Olson

Karny

et al. 2017

J. Electrochem. Soc.

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Mixtures of perfluoropolyethers (PFPE) and lithium salts with fluorinated anions are a new class of electrolytes for lithium batteries. Unlike conventional electrolytes wherein electron-donating oxygen groups interact primarily with the lithium cations, the properties of PFPE-based electrolytes appear to be dependent on interactions between the fluorinated anions and the fluorinated backbones. We study these interactions by examining a family of lithium salts wherein the size of the fluorinated anion is systematically increased: lithium bis(fluorosulfonyl)imide (LiFSI), bis(trifluoromethanesulfonyl)imide (LiTFSI) salts and lithium bis(pentafluoroethanesulfonyl)imide (LiBETI). Two short chain perfluoroethers (PFE), one with three repeat units, C6-DMC, and another with four repeat units, C8-DMC were studied; both systems have dimethyl carbonate end groups. We find that LiFSI provides the highest conductivity in both C6-DMC and C8-DMC. These systems also present the lowest interfacial resistance against lithium metal electrodes. The steady-state transference number (t + ss ) was above 0.6 for all of the electrolytes and was an increasing function of anion size. The product of conductivity and the steady-state transference number, a convenient measure of the efficacy of the electrolytes for lithium battery applications, exhibited a maximum at about 20 wt% salt in all electrolytes. Amongst the systems studied, LiFSI/PFE mixtures were the most efficacious electrolytes.

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“…In this respect, uorination of A groups offers the possibility of modulating optical and electrical properties of push-pull organic chromophores, lowering their HOMO and LUMO energy levels and facilitating the charge transfer process, 3 thus enhancing the 2 nd order NLO response. 4 Fluorination also affects crystal packing of conjugated organic materials, 5 which is a key issue in determining their electronic and optical properties, 6 and therefore their potential use in electronic and optoelectronic devices. On the other hand, linear p-conjugated materials tend to strongly aggregate in the solid state and in concentrated solutions, yielding p-stacked structures, which oen suppress luminescence and NLO properties.…”

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confidence: 99%

Fluorine-induced J-aggregation enhances emissive properties of a new NLO push–pull chromophore

et al. 2014

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A new fluorinated push-pull chromophore with good second-order NLO properties even in concentrated solution shows solid state intermolecular aryl-fluoroaryl interactions leading to J-aggregates with intense solid state luminescence.Over the last few decades, organic-based optoelectronic materials displaying good 2 nd order nonlinear optical (NLO) and emission properties have received great scientic attention. 1Among all possible substrates, linear p-conjugated organic molecules, and notably p-phenylene vinylene (PPV) derivatives, are of particular interest due to their broad absorption bands, high luminescence quantum yields, and large Stokes shis. 2Moreover, PPV structures have been used as convenient pbridges between strong electron donor (D) and acceptor (A) groups, whose electronic properties can be nely tuned by the insertion of suitable electron-withdrawing or donating substituents. In this respect, uorination of A groups offers the possibility of modulating optical and electrical properties of push-pull organic chromophores, lowering their HOMO and LUMO energy levels and facilitating the charge transfer process, 3 thus enhancing the 2 nd order NLO response. 4 Fluorination also affects crystal packing of conjugated organic materials, 5 which is a key issue in determining their electronic and optical properties, 6 and therefore their potential use in electronic and optoelectronic devices. On the other hand, linear p-conjugated materials tend to strongly aggregate in the solid state and in concentrated solutions, yielding p-stacked structures, which oen suppress luminescence and NLO properties. A good strategy to optimize both properties is to design molecules characterized by a low tendency to aggregate when dispersed or dissolved, but selfassemble into J-type aggregates in the solid state. J-aggregates are characterized by a narrow and intense absorption band, bathochromically shied with respect to the isolated molecule, and are known to enhance both the emissive 8 and the NLO properties. 9Aryl-uoroaryl interactions, 10 among others, 11 have been exploited to dictate self-assembly of large aromatic chromophores into J-aggregates. 12,13We have recently reported the synthesis, structural, and optical characterization of a new NLO chromophore consisting of a push-pull system where a PPV moiety spaces an electrondonor end, working as the halogen-bond-acceptor terminus, and a p-iodotetrauorophenyl end, working as the halogenbond-donor terminus (1a in Scheme 1).14 This chromophore, while being effective from the point of view of NLO properties, did not show any emission in the solid state and a very low one in solution (Quantum Yield, QY ¼ 0.14 in toluene), as a likely consequence of the presence of iodine. Here our attention focuses on the de-iodinated derivative 1b (Scheme 1), which being devoid of the I atom, should not only be preserved from the heavy atom effect on luminescence, but also favor the aryluoroaryl interactions with respect to self-complementary halogen bonded arrangements. This, in fac...

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Organic fluorine compounds: a great opportunity for enhanced materials properties

Cited by 1,268 publications

References 69 publications

α‐Fluoro‐o‐cresols: The Key Role of Intramolecular Hydrogen Bonding in Conformational Preference and Hydrogen‐Bond Acidity

α‐Fluoro‐o‐cresols: The Key Role of Intramolecular Hydrogen Bonding in Conformational Preference and Hydrogen‐Bond Acidity

Effect of Anion Size on Conductivity and Transference Number of Perfluoroether Electrolytes with Lithium Salts

Fluorine-induced J-aggregation enhances emissive properties of a new NLO push–pull chromophore

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