Efficient CdSe Nanocrystal Diffraction Gratings Prepared by Microcontact Molding

Shallcross, R. Clayton; Chawla, Gulraj S.; Marikkar, F. Saneeha; Tolbert, Stephanie H.; Pyun, Jeffrey; Armstrong, Neal R.

doi:10.1021/nn900735y

Cited by 20 publications

(29 citation statements)

References 32 publications

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“…Even though the identical stamp is used for all gratings, we find that the reproducibility of the stamping is not perfect, leading to slightly different grating periods ( Λ = 416.4 … 433.2 nm) and modulation depths defined as peak‐to‐valley distance ( M = 95.3 … 127.5 nm) between stampings. The observed concentration‐dependent morphology of the 1D truncated half‐sine‐like nanocrystal structures is consistent with those seen in the original report by Armstrong et al when sinusoidal PDMS replicas (produced from holographic master gratings) are used . The gratings in type B devices exhibit a sinusoidal profile with peak‐to‐valley modulation depth of M ≈ 60 nm (see Figure S7).…”

Section: Device and Lasing Properties Of Type A With Y‐nc Gratings Ansupporting

confidence: 88%

“…Incorporation of NCs into such devices relies on the ability to precisely control their morphology, either as pure materials or hybrid blends with organic polymers, on nanometer length scales to facilitate photoinduced (e.g., solar fuel and photovoltaic applications) and dark (e.g., field effect transistors and light‐emitting diodes) charge transfer. Directed lithographic self‐assembly of NCs on the nanoscale has also been employed to fabricate patterned features that can act as photonic structures (e.g., gratings or lasers), nanoelectronic circuits and sensors . All the aforementioned applications rely on controlling the interaction of the ligand‐capped NCs with a variety of materials and substrates to afford the desired nanoscale morphology (i.e., nanoscale phase separation, crack‐free film formation and high‐fidelity nanoscale pattern replication for hybrid photovoltaics, nanocrystal solar cells/transistors and photonic structures/sensors, respectively).…”

Section: Device and Lasing Properties Of Type A With Y‐nc Gratings Anmentioning

confidence: 99%

“…Previously, Armstrong et al have published on the formation of high‐fidelity CdSe NC diffraction gratings that demonstrated impressive transmission diffraction efficiency . These nanoscale diffraction gratings are produced via a room temperature microcontact molding procedure utilizing poly(dimethylsiloxane) (PDMS) replicas of commercially‐available masters.…”

Section: Device and Lasing Properties Of Type A With Y‐nc Gratings Anmentioning

confidence: 99%

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Simple Fabrication of an Organic Laser by Microcontact Molding of a Distributed Feedback Grating

2014

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Lasing from an organic polymer is demonstrated in a device utilizing a distributed feedback (DFB) grating, manufactured by microcontact molding of CdSe nanocrystals (NCs) directly on top of the emitter layer. Besides the simpler fabrication in comparison with a reference device based on a photolithographically prepared DFB grating in a bottom dielectric layer, a much higher DFB strength for NC-gratings is observed, resulting in reduced lasing threshold and a fourfold differential lasing efficiency.

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Section: Device and Lasing Properties Of Type A With Y‐nc Gratings Ansupporting

confidence: 88%

Section: Device and Lasing Properties Of Type A With Y‐nc Gratings Anmentioning

confidence: 99%

Section: Device and Lasing Properties Of Type A With Y‐nc Gratings Anmentioning

confidence: 99%

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Simple Fabrication of an Organic Laser by Microcontact Molding of a Distributed Feedback Grating

2014

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“…These fundamental approaches can be easily combined to attain multi-color patterns from only one batch of QDs. The methods presented here are also compatible with other micro-fabrication technologies of QDs embossed emission patterns, such as stamp mold [19,20], e-beam lithography [21,22] and flow coating [23]. The combination of PA, LSPR and annealing undoubtedly provides an effective way of precisely tuning the colors of light-emitting materials and devices that use colloidal CdSe QDs.…”

Section: Discussionmentioning

confidence: 84%

Physical approaches to tuning the luminescence color patterns of colloidal quantum dots

Zhang

et al. 2012

New J. Phys.

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Localized surface plasmon resonance (LSPR) and photoactivation (PA) effects are combined for the tuning of fluorescent colors of colloidal CdSe quantum dots (QDs). It is found that LSPR with QD emitters intensely enhances surface state emission, accompanied by a remarkable red-shift of fluorescent colors, while PA treatment with colloidal QDs leads to a distinct enhancement of band-edge emission, accompanied by a peak blue-shift. Furthermore, the LSPR effect on QD emitters can be continuously tuned by the PA process. The combination of the post-synthetic approaches allows feasible realization of multi-color patterns from one batch of QDs and the approaches can also be compatible with other micro-fabrication technologies of QD embossed fluorescent patterns, which undoubtedly provides a way of precisely tuning the colors of light-emitting materials and devices that use colloidal QDs.

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“…Thomas et al first demonstrated this technique with a nanocrystal–titania prepolymer solution . Shallcross and co‐workers, have developed micromolding patterned gratings with both CdSe ink and a mixture of CdSe and a red‐emitting polymer . Though this method can be applied in mild conditions, generally the quality is not as good as nanoimprint, as the uniformity across large areas could not be easily obtained (Figure e).…”

Section: Molding Approachesmentioning

confidence: 99%

Composite Structures with Emissive Quantum Dots for Light Enhancement

Smith

Lin

et al. 2018

Advanced Optical Materials

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The optical properties of these nanostructures can be controlled via precise control of the synthetic parameters resulting in a wide range of chemical compositions, shapes, and dimensions. QDs are quite advantageous in comparison to traditional organic dye counterparts, offering size, and composition dependent energy band gaps (i.e., tunable absorption and photoluminescence), prospective excellent photostability, and solution and aqueous processability based on choice of surface chemistries. [2] Intense research in this field in the past two decades has focused on precisely engineering core-shell composition of QD nanostructures resulting in an appreciable impact on the field of photonic materials and structures to develop composite nanomaterials with precise control of refractive index, permittivity, and permeability.QDs are the promising candidate to control interactions in photonic systems in many respects due to their enhanced photostability, near 100% quantum yield, and versatile surface chemistry. More recently, facile synthetic techniques for large-scale high-quality production have been introduced that involve wet chemical processes to expand applicability of these components in light-managements devices. [5][6][7] However, the overall processability and scalability of these components into robust large-area structures are still a critical concern limiting real-life implementation in robust designs. While there are many techniques to produce QDs, common limitations for this class of nanomaterials are low quantity, large dispersibility in size, compositional nonuniformity, and the presence of excess passive components resulting from wet chemistry synthetic procedures (e.g., ligands).Providing a convenient host matrix not only overcomes some of these common limitations but allows for QDs to be used in more technologically exploitable forms such as robust, flexible, mechanically and chemically stable fibers, coatings, films, and patterns. [8] For such composite systems, inclusion of nanoparticles into sophisticated matrices typically results in the significant improvements of thermal, mechanical, electrical, and optical stabilities making them more applicable in device environment than other traditional organic materials.While the concept of embedding various nanostructures into different surrounding materials is not new, synthetic techniques required to combine these can be rather complex. Most Since their inception, quantum dots have proven to be advantageous for light management applications due to their high brightness and wellcontrolled absorption, scattering, and emission properties. As quantum dots become commercially available at large scale, the need for robust, stable, and flexible optical components continues to drive the development of robust and flexible quantum dot composite materials. In this review, after a thorough introduction to quantum dots, discussion delves into methods for fabricating quantum dot loaded composite optical elements such as thin films, microfabricated patterns, and micros...

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Efficient CdSe Nanocrystal Diffraction Gratings Prepared by Microcontact Molding

Cited by 20 publications

References 32 publications

Simple Fabrication of an Organic Laser by Microcontact Molding of a Distributed Feedback Grating

Simple Fabrication of an Organic Laser by Microcontact Molding of a Distributed Feedback Grating

Physical approaches to tuning the luminescence color patterns of colloidal quantum dots

Composite Structures with Emissive Quantum Dots for Light Enhancement

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