Mechanism of Ligand-Controlled Emission in Silicon Nanoparticles

So, Woong Young; Li, Qi; Legaspi, Christian M.; Redler, Brendan; Koe, Krystle M.; Jin, Rongchao; Peteanu, Linda A.

doi:10.1021/acsnano.8b03273

Cited by 27 publications

(21 citation statements)

References 51 publications

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“…At the same time, several recent studies have reported multimodal PL relaxation spanning a range of wavelengths and time scales, − where the faster modes have been attributed to both surface effects and quasi-direct recombination, − although the distinction between the two is becoming increasingly blurred. In studies directed at extending the range of visible SiNC luminescence to shorter wavelengths, recent focus has been on bright size-independent emission tuned through a variety of complex surface ligands, − with the primary role of the Si core being optical absorption, and where PL color is determined by the charge-transfer characteristics of the ligands as opposed to quantum confinement.…”

mentioning

confidence: 99%

Bright Silicon Nanocrystals from a Liquid Precursor: Quasi-Direct Recombination with High Quantum Yield

et al. 2020

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Silicon nanocrystals (SiNCs) with bright bandgap photoluminescence (PL) are of current interest for a range of potential applications, from solar windows to biomedical contrast agents. Here, we use the liquid precursor cyclohexasilane (Si6H12) for the plasma synthesis of colloidal SiNCs with exemplary core emission. Through size separation executed in an oxygen-shielded environment, we achieve PL quantum yields (QYs) approaching 70% while exposing intrinsic constraints on efficient core emission from smaller SiNCs. Time-resolved PL spectra of these fractions in response to femtosecond pulsed excitation reveal a zero-phonon radiative channel that anticorrelates with QY, which we model using advanced computational methods applied to a 2 nm SiNC. Our results offer additional insight into the photophysical interplay of the nanocrystal surface, quasi-direct recombination, and efficient SiNC core PL.

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confidence: 99%

Bright Silicon Nanocrystals from a Liquid Precursor: Quasi-Direct Recombination with High Quantum Yield

et al. 2020

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“…In particular, the unique hydrophilic and optical properties of ES-SiNPs were probably attributable to their massive naturally modifying proteins secreted from yeast. 34,44 Long-Term Cellular Imaging. As fluorescent probes, the cytotoxicity of ES-SiNPs is necessary to be evaluated.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

“…The FTIR results are consistent with those of XPS, and it is therefore reasonably deduced that the above-mentioned yeast-derived proteins played a crucial role as reductants and stabilizers in the biomimetic synthesis of ES-SiNPs. In particular, the unique hydrophilic and optical properties of ES-SiNPs were probably attributable to their massive naturally modifying proteins secreted from yeast. , …”

Section: Resultsmentioning

confidence: 99%

Cell-Tailored Silicon Nanoparticles with Ultrahigh Fluorescence and Photostability for Cellular Imaging

Cui

Chang

Liu

et al. 2020

ACS Sustainable Chem. Eng.

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Until now, the green and facile synthesis of highly fluorescent silicon nanoparticles (SiNPs) with robust luminescent stability and favorable biocompatibility for cellular imaging is still a challenge. Here, a novel biomimetic strategy is demonstrated for the preparation of cell-tailored fluorescent SiNPs by the effective reaction of the easily available and operable yeast secretion and silicon precursor, K2SiF6. The as-prepared SiNPs exhibit excellent water dispersibility, favorable biocompatibility, and high luminescence (photoluminescent quantum yield of 44.77%) with robust pH/photo-/storage stability, holding great promise for use as new-generation fluorescent probes for long-term cellular imaging. Notably, it is found that several yeast-derived proteins, as reductants and stabilizers, played constructive roles in the fabrication of SiNPs with such inherent unique properties. The abundant amino and carboxyl groups could not only stabilize the resultant SiNPs with excellent water dispersibility but also functionalize them for further biomedical and biological applications. The biomimetic route has broken through the bottleneck hit by current physical or chemical methods in the green synthesis of SiNPs and provided a prospective direction for future nanotechnology.

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“…Si NPs have been shown to have high quantum efficiency [539] . The mechanism for emission is a charge transfer state between the ligand and the Si NP surface [540] . This charge transfer emission has been shown to produce non-classical light, as photon antibunching measurements have shown g (2) (0) values as low as 0.05 with high dependence on the substrate and ligand [541] .…”

Section: Other Colloidal Emittersmentioning

confidence: 99%

Nanomaterials for Quantum Information Science and Engineering

et al. 2022

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Quantum information science and engineering (QISE) which entails generation, control and manipulation of individual quantum mechanical states together with nanotechnology have dominated condensed matter physics and materials science research in the 21st century. Solid state devices for QISE have, to this point, predominantly been designed with bulk material as their constituents. In this review, we consider how nanomaterials or low-dimensional materials i.e. materials with intrinsic quantum confinement -may offer inherent advantages over conventional materials for QISE. We identify the materials challenges for specific types of qubits, and we identify how emerging nanomaterials may overcome these challenges. Challenges for and progress towards nanomaterials-based quantum devices are identified. We aim to help close the gap between the nanotechnology and quantum information communities and inspire research that will lead to next-generation quantum devices for scalable and practical quantum applications.

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Mechanism of Ligand-Controlled Emission in Silicon Nanoparticles

Cited by 27 publications

References 51 publications

Bright Silicon Nanocrystals from a Liquid Precursor: Quasi-Direct Recombination with High Quantum Yield

Bright Silicon Nanocrystals from a Liquid Precursor: Quasi-Direct Recombination with High Quantum Yield

Cell-Tailored Silicon Nanoparticles with Ultrahigh Fluorescence and Photostability for Cellular Imaging

Nanomaterials for Quantum Information Science and Engineering

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