Quantum optics with single molecules in a three-dimensional polymeric platform

Colautti, Maja; Lombardi, Pietro E.; Trapuzzano, Marco; Piccioli, Francesco S.; Pazzagli, Sofia; Tiribilli, Bruno; Nocentini, Sara; Cataliotti, Francesco S.; Wiersma, Diederik; Toninelli, Costanza

doi:10.48550/arxiv.1909.07334

Cited by 3 publications

(4 citation statements)

References 53 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Indeed, the effect is directly activated on the emitting sample with no need for additional fabrication and, being confined to the beam volit enables spatial resolution at the micron level. On the other side, once doped with single-molecule concentration, homogeneously deposited on the substrate via dropcasting and dessication [28], or even integrated in nanophotonic structures [15], DBT:Ac nanocrystals al- The demonstated results clearly show together several advantages of the proposed tuning approach: scalability, flexibility in the choice of substrate, high spectral and spatial resolution. We believe such characteristics will be crucial for the coupling of multiple emitters together in linear optical computing or simulation experiments and for the integration of molecules into resonant photonic structures.…”

Section: Characterization Of the Light-induced Frequency Shiftmentioning

confidence: 81%

“…Therefore, they can be operated as single-photon sources [6], combining high count rate and Fourier-limited linewidths [7][8][9], or as nano-probes with exquisite sensitivity to electric fields, pressure, and strain [10,11]. PAHbased quantum devices can also be readily integrated in photonic chips [12][13][14][15]. A major advantage of PAH systems resides in the possibility to mass-produce nominally identical fluorescent molecules at low costs, and still obtain outstanding optical and opto-electronic properties.…”

mentioning

confidence: 99%

See 1 more Smart Citation

Laser-Induced Frequency Tuning of Fourier-Limited Single-Molecule Emitters

Colautti¹,

Piccioli²,

Ristanović

et al. 2020

ACS Nano

Self Cite

View full text Add to dashboard Cite

The local interaction of charges and light in organic solids is the basis of distinct and fundamental effects. We here observe, at the single-molecule scale, how a focused laser beam can locally shift by hundreds of times their natural line width and, in a persistent way, the transition frequency of organic chromophores cooled at liquid helium temperature in different host matrices. Supported by quantum chemistry calculations, the results can be interpreted as effects of a photoionization cascade, leading to a stable electric field, which Stark-shifts the molecular electronic levels. The experimental observation is then applied to a common challenge in quantum photonics, i.e., the independent tuning and synchronization of close-by quantum emitters, which is desirable for multiphoton experiments. Five molecules that are spatially separated by about 50 μm and originally 20 GHz apart are brought into resonance within twice their line width. This tuning method, which does not require additional fabrication steps, is here independently applied to multiple emitters, with an emission line width that is only limited by the spontaneous decay and an inhomogeneous broadening limited to 1 nm. The system hence shows promise for photonic quantum technologies.

show abstract

Section: Characterization Of the Light-induced Frequency Shiftmentioning

confidence: 81%

mentioning

confidence: 99%

Laser-Induced Frequency Tuning of Fourier-Limited Single-Molecule Emitters

Colautti¹,

Piccioli²,

Ristanović

et al. 2020

ACS Nano

Self Cite

View full text Add to dashboard Cite

show abstract

“…Deterministic integration of micro optical components and individual quantum emitters can be achieved either by pre-or post-fabrication alignment, combined with lithographic fabrication. By lithographic techniques, various compact optical systems have been fabricated to control and manipulate light at the nanoscale, as for example waveguides [17,18], polarisation rotators [19], microdisc resonators [20], solid immersion lenses [21,22], objectives [23,24], parabolic antennas [25,26], dielectric pillar antennas [27], pillar microcavities [28].…”

Section: Introductionmentioning

confidence: 99%

Objective-free excitation of quantum emitters with a laser-written micro parabolic mirror

Morozov,

Vezzoli,

Khan

et al. 2020

Preprint

View full text Add to dashboard Cite

The efficient excitation of quantum sources such as quantum dots or single molecules requires high NA optics which is often a challenge in cryogenics, or in ultrafast optics. Here we propose a 3.2 µm wide parabolic mirror, with a 0.8 µm focal length, fabricated by direct laser writing on CdSe/CdS colloidal quantum dots, capable of focusing the excitation light to a sub-wavelength spot and to extract the generated emission by collimating it into a narrow beam. This mirror is fabricated via in-situ volumetric optical lithography, which can be aligned to individual emitters, and it can be easily adapted to other geometries beyond the paraboloid. This compact solid-state transducer from far-field to the emitter has important applications in objective-free quantum technologies.

show abstract

“…For instance, epitaxial InAs/GaAs quantum dots in GaAs nanowires 10−12 or strain-mediated quantum dots in single layers 13,14 of WSe 2 are recent examples of SPSs that can be deterministically positioned, but the observation of narrow optical resonances from such emitters remains challenging. Polymers offer an interesting platform for structuring the environment of SPSs at the nanoscale in order to couple them to photonic structures 15,17,16 on chip. While lithographic techniques have already shown impressive results for on-chip integration of nitrogen-vacancy centers 18 and quantum dots, 19 the outstanding properties of organic single molecules as quantum emitters and their compatibility with polymers motivate the quest for novel approaches based on electron-beam lithography to achieve nanophotonic integration while preserving their emission properties.…”

mentioning

confidence: 99%

Narrow Line Width Quantum Emitters in an Electron-Beam-Shaped Polymer

et al. 2019

Self Cite

View full text Add to dashboard Cite

Solid-state single photon sources (SPSs) with narrow linewidth play an important role in many leading quantum technologies. Within the wide range of SPSs studied to date, single fluorescent molecules hosted in organic crystals stand out as bright, photostable SPSs with lifetime-limited optical resonance at cryogenic temperatures. Furthermore, recent results have demonstrated that photostability and narrow linewidths are still observed from single molecules hosted in a nanocrystalline environment, which paves the way for their integration with photonic circuitry. Polymers offer a compatible matrix for embedding nanocrystals and provide a versatile yet low-cost approach for making nanophotonic structures on chip that guide light and enhance coupling to nanoscale emitters. Here, we present a deterministic nanostructuring technique based on electron-beam lithography for shaping polymers with embedded single molecules. Our approach provides a direct mean of structuring the nanoscale environment of narrow linewidth emitters while preserving their emission properties.Ideal SPSs are isolated quantum systems displaying stable emission within a narrow linewidth 1 , which is fundamental for quantum technology applications such as entanglement and single photon

show abstract

Quantum optics with single molecules in a three-dimensional polymeric platform

Cited by 3 publications

References 53 publications

Laser-Induced Frequency Tuning of Fourier-Limited Single-Molecule Emitters

Laser-Induced Frequency Tuning of Fourier-Limited Single-Molecule Emitters

Objective-free excitation of quantum emitters with a laser-written micro parabolic mirror

Narrow Line Width Quantum Emitters in an Electron-Beam-Shaped Polymer

Contact Info

Product

Resources

About