The origin of emissive states of carbon nanoparticles derived from ensemble-averaged and single-molecular studies

Demchenko, Alexander P.; Dekaliuk, Mariia

doi:10.1039/c6nr02669a

Cited by 107 publications

(120 citation statements)

References 130 publications

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“…[10,13,14] The emission tunability has been most prominently ascribed to selective excitation of subsets of CDs within the CD ensemble. [15][16][17]32] Indeed, multiple studies have shown that it is possible to tune the emission by using different types of CDs that are themselves excitation independent. [18][19][20] On the other hand, Pan et al [11] and Fu et al [21] have suggested that different emission sites within individual CDs are responsible for excitation-dependent emission.…”

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confidence: 99%

Excitation‐Dependent Photoluminescence from Single‐Carbon Dots

Dam

Nie

et al. 2017

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Carbon dots (CDs) are carbon-based fluorescent nanoparticles that can exhibit excitation-dependent photoluminescence (PL) "tunable" throughout the entire visible range, interesting for optoelectronic and imaging applications. The mechanism underlying this tunable emission remains largely debated, most prominently being ascribed to dot-to-dot variations that ultimately lead to excitation-dependent ensemble properties. Here, single-dot spectroscopy is used to elucidate the origin of the excitation-dependent PL of CDs. It is demonstrated that already single CDs exhibit excitation-dependent PL spectra, similar to those of the CD ensemble. The single dots, produced by a facile one-step synthesis from chloroform and diethylamine, exhibit emission spectra with several characteristic peaks differing in emission peak position and spectral width and shape, indicating the presence of distinct emission sites on the CDs. Based on previous work, these emission sites are related to the sp subregions in the carbon core, as well as the functional groups on the surface. These results confirm that it is possible to integrate and engineer different types of electronic transitions at the nanoscale on a single CD, making these CDs even more versatile than organic dyes or inorganic quantum dots and opening up new routes toward light-emission engineering.

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confidence: 99%

Excitation‐Dependent Photoluminescence from Single‐Carbon Dots

Dam

Nie

et al. 2017

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“…In Figure 4, the decay kinetics of C-dots emission bands are reported, along with their best fitting curves. The function used to fit the kinetics is a stretched exponential f (t) = A·e −((t/τ) b ) where is the fluorescence lifetime and b is the stretching parameter, which quantifies the degree of inhomogeneity of the emissive ensemble, due to the large dot-to-dot fluctuations observed for C-dots [26,29]. Excluding the case of C-dots in the presence of 100 mM iodide, the data in Figure 4 show that all the measured kinetics are identical within experimental uncertainty.…”

Section: Resultsmentioning

confidence: 99%

Effect of Halogen Ions on the Photocycle of Fluorescent Carbon Nanodots

Sciortino

Pecorella

Cannas

et al. 2019

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Carbon dots (C-dots) are well-known for their strong sensitivity to the environment, which reflects on intensity and shape changes of their fluorescence, induced by various interacting ions and molecules in solution. Although these interactions have been extensively studied in the last few years, especially in view of their possible sensing applications, the existing works have mostly focused on the quenching of C-dot fluorescence induced by metal cations. In fact, these latter easily bind to C-dots surfaces, which are negatively charged in most cases, promoting an electron transfer from the surface to them. Much less is known from the literature on the effect induced on C-dots by prototypical negative species in solutions, motivating more systematic studies on this different class of interactions. Here, we analyzed the effect of halogen ions on the fluorescence of C-dots, by combining steady-state optical absorption and photoluminescence, time-resolved fluorescence and femtosecond pump/probe spectroscopy. We demonstrate a quenching effect of C-dots fluorescence in the presence of halogen ions, which becomes more and more pronounced with increasing atomic number of the halogens, being negligible for chloride, appreciable for bromide and stronger for iodide. We find that quenching is mostly static, due to the binding of halogen ions on suitable surface sites at C-dots surfaces, while collisional quenching becomes obvious only at very high iodide concentrations. Finally, nanosecond and femtosecond time-resolved spectroscopies provide information on the quenching mechanism and time scales. Based on these data, we propose that the fluorescent state is deactivated by intersystem crossing to a dark triplet state, induced by close-range interactions with the heaviest halogen ions.

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“…The essence of this phenomenon has been the most obscure of the CND features to date, and numerous efforts have been made to truly understand the physical basis and factors that may be involved and effect the optical properties of CNDs. However, there are several factors that hamper achieving a unified theory for the origin of CNDs emission: (i) inherent heterogeneity of CNDs due to the use of numerous precursors and approaches; (ii) uncertainty and complexity of functional and molecular groups on the surface induced during the synthesis process through different reaction pathways; and (iii) difficulties in the assessment of influence of size and surface chemicals on the optical properties due to lack of means for independent control of size and surface chemistry …”

Section: Introductionmentioning

confidence: 99%

“…These mentioned instances suggested that PL from CNDs should not be attributed to the particle as a whole (as for QDs), but to individual emitters within, and to communication between them . A single or a number of different emitters within an individual particle could exist, and there may be several excitation traps that could emit in parallel . The properties of such integrated systems are not always additive, or equal to the sum of the properties of their components .…”

Section: Introductionmentioning

confidence: 99%

“…A single or a number of different emitters within an individual particle could exist, and there may be several excitation traps that could emit in parallel . The properties of such integrated systems are not always additive, or equal to the sum of the properties of their components . Based on these considerations, it is quite reasonable to suggest the presence of multiple luminescence sites within each nanoparticle.…”

Section: Introductionmentioning

confidence: 99%

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