Relating Conformation and Photophysics in Single MEH-PPV Chains

Ebihara, Yohei; Vácha, Martin

doi:10.1021/jp806963u

Cited by 98 publications

(115 citation statements)

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“…Th is has been demonstrated using a combination of polarization-modulated epi-fl uorescence and total internal refl ection illumination with a widefi eld microscope [20]. It has thus been found that irrespective of conformation, MEH-PPV chains tend to orient parallel with the sample substrate during the spin-coating sample preparation process [15].…”

Section: Optical Measurement Of Conformation and Orientation Of A Sinmentioning

confidence: 97%

“…In addition to the projection onto the sample plane, this method uses polarization-modulated total internal refl ection illumination to measure the projection of the ellipsoid in a plane perpendicular to the sample (Figure 3(b)). Th is method has been used to measure the absorption ellipsoids of MEH-PPV in various polymer matrices [15]. Th e conformation of individual chains must still be reconstructed by molecular dynamics simulations, but the conformation is now available for each polymer chain individually, thus making it possible to study the conformation and properties on a truly single-molecule level.…”

Section: Optical Measurement Of Conformation and Orientation Of A Sinmentioning

confidence: 99%

“…It was assumed that the observation of fl uorescence blinking must indicate that the chain is collapsed. Recently, a method for 3D determination of absorption ellipsoids was used to examine the relationship between the directly measured conformation and fl uorescence blinking [15]. Th e most important fi nding was that MEH-PPV in low-molecular-weight PS can adopt two diff erent conformations: an extended defect coil and a compact defect coil.…”

Section: Review Articlementioning

confidence: 99%

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Conformation and physics of polymer chains: a single-molecule perspective

Vácha

Habuchi

2010

NPG Asia Mater

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N anotechnology has been one of the driving forces of science and technology over the past 20 years. Scaling down the size of an object to nanometer dimensions can result in dramatic changes to its physical properties. With recent progress in the nanoscience and nanotechnology of polymeric materials, new methods are now required for the characterization of polymer structures and properties. Despite the great success of electron microscopy and scanning probe microscope techniques, there remains a need for a non-invasive method that could provide information not only on the structure but also on the physical phenomena occurring on the nanoscale level. One method that has recently emerged as an excellent tool for nanoscale characterization is single-molecule optical detection and spectroscopy. Single-molecule spectroscopy relies on the detection and measurement of the fl uorescence signal and spectra from single isolated molecules or polymer chains (Figure 1). Th ese can either be immobilized in a solid matrix or be diff using in a solution or melt. In all cases, the concentration of the emitting molecules must be suffi ciently low to ensure that the spatial separation between individual molecules is larger than the optical resolution of the setup, typically on the order of micrometers. As the fl uorescence signal from a molecule is strongly infl uenced by the nanoscale environment, measuring many molecules one by one provides the distribution of physical properties of the respective nano-environments. Moreover, monitoring a molecule over a period of time reveals dynamic changes in its environment. Th ese static and dynamic heterogeneities of nanoscale properties are averaged and hidden in the usual ensemble experiments. Th e strength of fl uorescence detection is in its sensitivity and low background level -emissions of just a few hundred photons per second can be readily detected. Th e technique also off ers remarkable dynamic range, from sub-nanosecond timescales to seconds and longer, and is non-invasive, making it possible to detect emissions from molecules buried deep in a sample.Single-molecule spectroscopy has evolved since the beginning of the 1990s from low-temperature, high-resolution optical spectroscopic

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Section: Optical Measurement Of Conformation and Orientation Of A Sinmentioning

confidence: 97%

Section: Optical Measurement Of Conformation and Orientation Of A Sinmentioning

confidence: 99%

Section: Review Articlementioning

confidence: 99%

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Conformation and physics of polymer chains: a single-molecule perspective

Vácha

Habuchi

2010

NPG Asia Mater

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“…5 Recently, we reported a novel fluorescence polarization microscopic method 6 and used it together with molecular dynamics simulations to reveal the conformation of individual polymer chains on a truly single-molecule level. 7 This enabled us to study photophysical properties of MEH-PPV on the same single chains and to show that the conformational state is the determining factor for the photophysical processes. Here, we use the previously determined conformations of MEH-PPV in different host matrices and correlate the structural information with single chain emission spectra.…”

Section: 4mentioning

confidence: 99%

Conformation-dependent Room-temperature Emission Spectra of Single MEH-PPV Chains in Different Polymer Matrices

2009

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Emission spectra of single molecules of the conjugated polymer MEH-PPV in host matrices of ZEONEX Ò and polystyrene are reported. Depending on the matrix, the polymer chains attain different conformations, from compact defect cylinders to extended defect coils. The conformations are correlated with photophysical properties, such as emission intensity fluctuations, and with shapes and peaks of emission spectra. The observed bimodal distribution of the spectral peaks is related to distribution in conjugated segment lengths.Conjugated polymers are the subject of intense research as active materials for optical and electronic devices.1,2 Photophysical processes play crucial roles in the device function. However, photophysics of conjugated polymers depends strongly on the unique conformation of individual polymer chains. As a result, many questions on the relationship between structure and optical properties remain open. 3,4 The complexity of the study of conjugated polymer photophysics can be partially overcome by the use of single molecule spectroscopy. 5 Recently, we reported a novel fluorescence polarization microscopic method 6 and used it together with molecular dynamics simulations to reveal the conformation of individual polymer chains on a truly single-molecule level.7 This enabled us to study photophysical properties of MEH-PPV on the same single chains and to show that the conformational state is the determining factor for the photophysical processes. Here, we use the previously determined conformations of MEH-PPV in different host matrices and correlate the structural information with single chain emission spectra.Poly[2-methyloxy-5-(2-ethylhexyl)oxy-1,4-phenylenevinylene] (MEH-PPV, Aldrich, M w 200000, PDI 5) was dispersed by spin-coating in thin-film matrices of ZEONEX and of low-molecular weight polystyrene (PS). The film thickness was on the order of 120 nm. The experiments were carried out on an inverted fluorescence microscope 7 using the 488-nm line of Ar þ ion laser for excitation. Time evolving emission spectra were taken with an EM-CCD camera and an imaging spectrograph as a series of tens of images.Single MEH-PPV chains attain compact defect cylinder conformations in the poor-solvent matrix of ZEONEX (Figure 1). The resulting interchain interactions lead to localization of the exciton and to blinking in the emission time-traces (Figure 1a). Single-chain emission spectra measured for several tens of molecules were analyzed and their maxima were plotted in a histogram in Figure 1c. The histogram shows a single-mode Gaussian-like distribution with a center near 550 nm.In the good-solvent matrix of polystyrene, the MEH-PPV is present in two conformations, 7 a compact oblong defect coil (type 1) and an extended disc-like defect coil (type 2), as seen in Figure 2. The two conformations lead to different photophysical behavior. The compact defect coil causes partial localization of the exciton in domains on the chain, 8 resulting in blinking of the emission (Figure 2a). In contrast, the extended coil ...

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“…Previous studies have revealed that there are two main fluorescence time transients in MEH-PPV single molecules, corresponding to collapsed and extended chain conformations. 14,15 A collapsed chain displays discrete fluorescence blinking due to a disruption of the energy transfer pathway to the emitting chromophore by the formation of a long-lived absorbing state or by transient bleaching of the emitting chromophore through said long-lived state. 10 In contrast, an extended chain exhibits continuous photobleaching as one chromophore after another photo-oxidises.…”

mentioning

confidence: 99%

Connection between the conformation and emission properties of poly[2-methoxy-5-(2′-ethyl-hexyloxy)-1,4-phenylene vinylene] single molecules during thermal annealing

Yang

Lin

et al. 2015

Applied Physics Letters

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We investigated the transitions of conformations and their effects on emission properties of poly[2-methoxy-5-(2′-ethyl-hexyloxy)-1,4-phenylene vinylene] (MEH-PPV) single molecules in PMMA matrix during thermal annealing process. Total internal reflection fluorescence microscopy measurements reveal the transformation from collapsed conformations to extended, highly ordered rod-like structures of MEH-PPV single molecules during thermal annealing. The blue shifts in the ensemble single molecule PL spectra support our hypnosis. The transition occurs as the annealing temperature exceeds 100 °C, implying that an annealing temperature near the glass transition temperature Tg of matrix is ideal for the control and optimization of blend polymer films.

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Relating Conformation and Photophysics in Single MEH-PPV Chains

Cited by 98 publications

References 27 publications

Conformation and physics of polymer chains: a single-molecule perspective

Conformation and physics of polymer chains: a single-molecule perspective

Conformation-dependent Room-temperature Emission Spectra of Single MEH-PPV Chains in Different Polymer Matrices

Connection between the conformation and emission properties of poly[2-methoxy-5-(2′-ethyl-hexyloxy)-1,4-phenylene vinylene] single molecules during thermal annealing

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