A Stimuli‐Responsive, Photoluminescent, Anthracene‐Based Liquid Crystal: Emission Color Determined by Thermal and Mechanical Processes

Sagara, Yasuyuki; Yamane, Satoshi; Mutai, Toshiki; Araki, Koji; Kato, Takashi

doi:10.1002/adfm.200801726

Cited by 247 publications

(151 citation statements)

References 85 publications

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“…Recently, luminescent materials that are responsive to mechanical stimuli have attracted considerable attention because they have the unique ability to tune their molecular, physical or chemical properties via macroscopic stimulation [5][6][7][8] . Several mechanistic explanations for the mechanically stimulated changes in the colour of the luminescence have been proposed: a phase transformation of the solid structure [9][10][11][12][13][14][15][16] , excimer formation or dissolution [17][18][19] and mechanical stress-induced chemical changes 20,21 .…”

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confidence: 99%

Design amphiphilic dipolar π-systems for stimuli-responsive luminescent materials using metastable states

et al. 2014

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p-Conjugated compounds that exhibit tunable luminescence in the solid state under external mechanical stimuli have potential applications in sensors and imaging devices. However, no rational designs have been proposed that impart these mechano-responsive luminescent properties to p-conjugated compounds. Here we demonstrate a strategy for mechanoresponsive luminescent materials by imparting amphiphilic and dipolar characteristics to a luminescent p-conjugated system. The oligo(p-phenylenevinylene) luminophore with a didodecylamino group at one end and a tri(ethylene glycol) ester group at the other end yields segregated solid structures by separately aggregating its hydrophobic and hydrophilic moieties. The segregated structures force the molecules to align in the same direction, thereby generating a conflict between the side-chain aggregation and dipolar stabilization of the p-system. Consequently, these metastable solid structures can be transformed through mechanical stimulation to a more stable structure, from a p-p stacked aggregate to a liquid crystal and further to a crystalline phase with variable luminescence.

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confidence: 99%

Design amphiphilic dipolar π-systems for stimuli-responsive luminescent materials using metastable states

et al. 2014

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“…[2][3][4] The tuning of the luminescence of organic solids by mechanical forces has been realized through changing the chemical structures containing opened/closed cyclic forms [5] and double-bond E/Z configurations.[6] However, relatively high pressure is necessary to promote chemical reactions, [7] and poor reversibility has been considered as a drawback in such systems. In contrast, controlling the mode of molecular packing (aggregation states) is more attractive for both fundamental research and practical applications due to low pressure demand and good reversibility, but successful systems are quite limited.…”

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A Piezochromic Luminescent Complex: Mechanical Force Induced Patterning with a High Contrast Ratio

Luo

Song

et al. 2011

Chemistry A European J

100

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Piezochromic (mechanochromic) luminescent (PIEL) materials change their emission colors (bands) by applying appropriate pressure or other mechanical forces.[1] Their mechanical responsiveness provides fundamental basis for luminescence switches, information display/storage, and extremely significant pressure sensors in various fields. [2][3][4] The tuning of the luminescence of organic solids by mechanical forces has been realized through changing the chemical structures containing opened/closed cyclic forms [5] and double-bond E/Z configurations.[6] However, relatively high pressure is necessary to promote chemical reactions, [7] and poor reversibility has been considered as a drawback in such systems. In contrast, controlling the mode of molecular packing (aggregation states) is more attractive for both fundamental research and practical applications due to low pressure demand and good reversibility, but successful systems are quite limited. [8][9][10][11][12][13][14][15] A few reports mainly focused on transforming p-p aggregation modes of single conjugated materials under pressure, for example, (liquid) crystal to (liquid) crystal [8][9][10][11][12][13] or crystal to amorphous solid. [14][15] However, it is still difficult to predict and design materials with polymorphism. Herein, we utilize a binary complex to overcome the drawbacks from a single component system, and this strategy expands the range of PIEL materials to a large extent. In our approach, a fluorescent donor (D) and a nonemissive acceptor (A) are blent to form a binary complex to achieve piezochromic luminescence, in which the luminescence changes from quenching (black) to emitting (color) state once mechanical force is applied. We further confirmed the mechanism and realized mechanical force induced patterning. This strategy provides a new way to achieve piezochromic luminescence and special polymorphic materials are not necessary. In addition, unlike the transformation between two emission colors in traditional piezochromic luminescent materials, the contrast ratio is very high to favor observation by naked-eye due to very low fluorescence intensity in the quenching state.Many donor-acceptor systems reported have only fluorescence quenching process and no force-induced fluorescence recovery of donor. However, we propose that cocrystallized D-A systems have potential of the fluorescence recovery once force-induced phase separation occurs, which means that acceptors move away from adjacent fluorescent donors. 2,5-di(E)-distyrylfuran [16] 1 as an electron donor exhibited intensive greenish blue fluorescence both in solution and in crystal state, and planar p-conjugated structure leads to strong tendency to aggregate by p-p stacking. Meanwhile, we chose N-alkyl substituted maleimides as acceptors to quench fluorescence of donor via photo-induced electron transfer process (PET). [17][18] In fact, once the complex (1:1) of 1 and 2 a is deposited on the substrate, the fluorescence intensity of donor will be dramatically quenched. However, the fluore...

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“…In the case of a liquid-crystalline anthracene derivative with a similar molecular structure to 1, a peak due to free amide C=O groups was observed at around ñ = 1685 cm À1 . [13] Hydrogen bonds are retained after annealing (Figure 5 b). No peaks that correspond to amide NÀH stretching were observed because they were masked by the large and broad peaks ascribed to OÀH stretching of many hydroxy groups of 1.…”

Section: Resultsmentioning

confidence: 99%

Thermal or Mechanical Stimuli‐Induced Photoluminescence Color Change of a Molecular Assembly Composed of an Amphiphilic Anthracene Derivative in Water

Sagara¹,

Komatsu²,

Terai³

et al. 2014

Chemistry A European J

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Molecular assemblies that change photoluminescence color in response to thermal or mechanical stimulation without dissociation into the monomeric states in water are described herein. A dumbbell-shaped amphiphilic compound forms micellar molecular assemblies in water and exhibits yellow photoluminescence derived from excimer formation of the luminescent core, which contains a 2,6-diethynylanthracene moiety. Annealing of the aqueous solution induces a photoluminescence color change from yellow to green (λem, max =558→525 nm). The same photoluminescence color change is also achieved by rubbing the yellow-photoluminescence-emitting molecular assemblies adsorbed on glass substrates with cotton wool in water. The observed green photoluminescence is ascribed to micelles that are distinct from the yellow-photoluminescence-emitting micelles, on the basis of transmission electron microscopy observations, atomic force microscopy observations, and dynamic light scattering measurements. We examined the relationship between the structure of the molecular assemblies and the photophysical properties of the anthracene derivative in water before and after thermal or mechanical stimulation and concluded that thermal or mechanical stimuli-induced slight changes of the molecular-assembled structures in the micelles result in the change in the photoluminescence color from yellow to green in water.

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A Stimuli‐Responsive, Photoluminescent, Anthracene‐Based Liquid Crystal: Emission Color Determined by Thermal and Mechanical Processes

Cited by 247 publications

References 85 publications

Design amphiphilic dipolar π-systems for stimuli-responsive luminescent materials using metastable states

Design amphiphilic dipolar π-systems for stimuli-responsive luminescent materials using metastable states

A Piezochromic Luminescent Complex: Mechanical Force Induced Patterning with a High Contrast Ratio

Thermal or Mechanical Stimuli‐Induced Photoluminescence Color Change of a Molecular Assembly Composed of an Amphiphilic Anthracene Derivative in Water

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