The Impact of Aggregation of Quaterthiophenes on the Excited State Dynamics

Ghosh, Srijon; Jana, Bikash; Ghosh, Arnab; Guldi, Dirk M.; Patra, Amitava

doi:10.1021/acs.jpclett.1c00440

Cited by 9 publications

(31 citation statements)

References 60 publications

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“…However, sometimes red-shifted emission can also be seen from H-aggregates (especially for aggregates with slightly disordered arrangement of herringbone-like structures). [25,26] In case of J-aggregates, it is known that they form excitonic state due to delocalization of excitonic state between definite number of dye molecules. [6] These nanohybrid systems are fabricated such that colloidal QDs can act as donors of excitation energy and/or electrons to J-aggregates, which subsequently fluoresce and participates in different photophysical processes.…”

Section: Introductionmentioning

confidence: 99%

“…Due to this, there occurs bathochromic (red) or hypsochromic (blue) shift in the absorption and emission spectra of J‐ or H‐aggregate, respectively. However, sometimes red‐shifted emission can also be seen from H‐aggregates (especially for aggregates with slightly disordered arrangement of herringbone‐like structures) [25,26] . In case of J‐aggregates, it is known that they form excitonic state due to delocalization of excitonic state between definite number of dye molecules [6] .…”

Section: Introductionmentioning

confidence: 99%

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Understanding the Interaction between Inorganic and Organic Excitonic Components of an Inorganic‐Organic Nanohybrid Associate

et al. 2022

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The present study deals with the design, formation, and photophysical studies on light‐harvesting inorganic‐organic nanohybrid associates comprising a less‐toxic, inorganic core‐shell QD (Cu−In−S/ZnS) and an organic S0041 dye aggregate. One of the main objectives of this study is to understand the interaction between the inorganic and organic excitonic components of the hybrid system and its implication on the photophysical response of the system. The nanohybrid associate have been obtained through the self‐assembly of S0041 dye molecules (organic exciton) onto Cu−In−S/ZnS QD (inorganic exciton). The characterization of as‐synthesized QD have been done by conventional microscopic and spectroscopic measurements. The exciton domain length for the organic dye aggregates is estimated to be 24 nm. Steady‐state absorption, emission, and time‐resolved photoluminescence (PL) intensity decay measurements have been carried out to understand the interaction mechanism between inorganic and organic excitonic components and the overall photophysical behaviour of the hybrid system. The studies have revealed that the formation of hybrid associate is electrostatically driven and thermodynamically feasible. Interestingly, steady‐state and time‐resolved PL decay measurements and their analysis have revealed that the interaction between inorganic QD and organic aggregate is mediated through dipole‐dipole Förster energy transfer (ET) mechanism and the ET efficiency is found to be as high as 95%. The present system is expected to be used in fabrication of less‐toxic nanoscale light‐harvesting system.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Understanding the Interaction between Inorganic and Organic Excitonic Components of an Inorganic‐Organic Nanohybrid Associate

et al. 2022

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“…(3) In the achiral system, the spin orientations of triplet and singlet excitons are equal between spin-up (yellow cloud) and spin-down (green cloud) after TTET and TTA processes. (Panels a–f are reprinted from refs , , , , , and , respectively. Copyright American Chemical Society.…”

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confidence: 99%

“…The suppression of the conformational mobility of quaterthiophene (QTH) in tetrahydrofuran solution with more than 70% water results in excitonically coupled H-aggregates. ISC was not observed [τ ISC = 330 ps (0% water), τ ISC = 2.3 ns (70% water)], and an unusual H-aggregate centered emission occurs from lower excitonic state of the QTH-aggregates when the water content goes to 100% (Figure e) . Incorporation of nonfullerene acceptors provided a sufficiently large energy difference and small electronic coupling between the CT and triplet excitonic states.…”

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confidence: 99%

Virtual Issue on Triplet Excitons

Hariharan

Scholes

2022

J. Phys. Chem. Lett.

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“…Reisner and co-workers have realized as many as 398 μmol of photocatalytic H 2 production per gram of C-dots per hour in the presence of a nickel co-catalyst . Significant efforts have been devoted to the synthesis and applications of C-dots; however, the study of the excited-state relaxation of C-dots using ultrafast spectroscopy and global and target analysis is less explored, which is essential for the development of efficient light-harvesting systems. − Wang et al have proposed an intrinsic dark state and a surface-related emissive state, which relaxes independently in the case of a carbon nanodot . On the contrary, previous works report the excitation transfer from the core to surface with various time scales ranging from 400 fs to 10 ps. , Yang and co-workers have demonstrated a detailed interplay between the core and surface in the excited state. , Wen et al have identified the time scale for various processes for the excited state of C-dots such as surface trapping (400 fs), optical phonon scattering (<5 ps), acoustic phonon scattering (50 ps), and excitonic recombination (1.5 ns) .…”

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confidence: 99%

Deciphering the Relaxation Mechanism of Red-Emitting Carbon Dots Using Ultrafast Spectroscopy and Global Target Analysis

Ghosh

et al. 2021

J. Phys. Chem. Lett.

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Red-emitting carbon dots (C-dots) have tremendous potential for bioimaging and optoelectronic applications. Here, we investigated the structural modification of red-emitting C-dots due to boron doping and their ultrafast relaxation dynamics. It is evident from the X-ray photoelectron spectroscopy study that the relative percentage of pyrridinic nitrogen is increased at the expense of amino nitrogen and graphitic nitrogen in B-doped C-dots. Transient absorption spectroscopy and global target analysis reveal the formation of an additional excited-state level that takes away a significant amount of the excited-state population after boron doping. This new excited state slows the initial relaxation process toward the emissive state from 317 to 750 fs and increases the overall lifetime from 1.03 to 1.45 ns in B-doped C-dots.

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The Impact of Aggregation of Quaterthiophenes on the Excited State Dynamics

Cited by 9 publications

References 60 publications

Understanding the Interaction between Inorganic and Organic Excitonic Components of an Inorganic‐Organic Nanohybrid Associate

Understanding the Interaction between Inorganic and Organic Excitonic Components of an Inorganic‐Organic Nanohybrid Associate

Virtual Issue on Triplet Excitons

Deciphering the Relaxation Mechanism of Red-Emitting Carbon Dots Using Ultrafast Spectroscopy and Global Target Analysis

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