More Like this

1. Quantitative morphological analysis of InP-based quantum dots reveals new insights into the complexity of shell growth

   https://doi.org/10.1063/5.0149097  

   Click, Sophia M.; Koziel, Alexandra C.; Torres, Ruben; Flores, Sebastian; McBride, James R.; Rosenthal, Sandra J. (June 2023, The Journal of Chemical Physics)

   The incorporation of quantum dots in display technology has fueled a renewed interest in InP-based quantum dots, but difficulty controlling the Zn chemistry during shelling has stymied thick, even ZnSe shell growth. The characteristic uneven, lobed morphology of Zn-based shells is difficult to assess qualitatively and measure through traditional methods. Here, we present a methodological study utilizing quantitative morphological analysis of InP/ZnSe quantum dots to analyze the impact of key shelling parameters on InP core passivation and shell epitaxy. We compare conventional hand-drawn measurements with an open-source semi-automated protocol to showcase the improved precision and speed of this method. Additionally, we find that quantitative morphological assessment can discern morphological trends in morphologies that qualitative methods cannot. In conjunction with ensemble fluorescence measurements, we find that changes to shelling parameters that promote even shell growth often do so at the cost of core homogeneity. These results indicate that the chemistry of passivating the core and promoting shell growth must be balanced carefully to maximize brightness while maintaining emission color-purity. 

   more » « less
2. Composite Structures with Emissive Quantum Dots for Light Enhancement

   https://doi.org/10.1002/adom.201801072  

   Smith, Marcus_J; Lin, Chun_Hao; Yu, Shengtao; Tsukruk, Vladimir_V (November 2018, Advanced Optical Materials)

   Abstract Since their inception, quantum dots have proven to be advantageous for light management applications due to their high brightness and well‐controlled 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 microstructures. The importance of surface chemistry and ligand engineering, host matrixes, wet processing, and unique patterning methodologies is presented by considering photostability, aggregation, and phase separation of quantum dots in corresponding composites. With regard to prospective optical applications of quantum dot materials, emphasis is placed on light emitting and guiding composite materials for lasing applications, specifically whispering gallery mode‐based photonic microsystems. These developments will enable novel flexible, portable, and miniaturized optoelectronic devices such as light‐emitting diodes, flexible pixelated displays, solar cells, large‐area microwaveguides, omnidirectional micromirrors, optical metasurfaces, and directional microlasers. 

   more » « less
3. Direct Optical Lithography of Colloidal InP-Based Quantum Dots with Ligand Pair Treatment

   https://doi.org/10.1021/acsenergylett.3c01019  

   Lee, Jaehwan; Ha, Jaeyeong; Lee, Hyungdoh; Cho, Hyunjin; Lee, Doh C.; Talapin, Dmitri V.; Cho, Himchan (October 2023, ACS Energy Letters)

   Direct optical lithography presents a promising patterning method for colloidal quantum dots (QDs). However, additional care needs to be taken to prevent deterioration of the optical properties of QDs upon patterning, especially for InP-based QDs. This study proposes an efficient method for high-resolution patterning of InP-based QDs using a photoacid generator while preserving their optical properties. Specifically, our solid-state ligand exchange strategy, replacing chloride ligands with long-chain amine/carboxylate pair ligands, successfully recovered the photoluminescence quantum yield (PLQY) of the patterned InP-based QD films to ∼67% of the original PLQY. Upon examination of the origins of the PLQY reduction during patterning, we concluded that the formation of deep traps caused by the exchanged chloride ligands was the primary cause. Finally, we fabricated high-resolution (feature size: 1 μm), multicolored patterns of InP-based QDs, thereby demonstrating the potential of the proposed patterning method for next-generation high-resolution displays and optoelectronic devices. 

   more » « less
4. High Optical Density Quantum Dot Pixel Color Conversion Films for Displays

   Etheridge, Forrest S.; Chamberlin, Danielle R.; Schaller, Richard. D.; Talapin, Dmitri V.; Kambe, Yu (May 2021, Proceedings of the Society for Information Display)

   Quantum Dot downconverters will enable high-resolution, bright, and wide color gamut displays for all display formats. We have developed a method to directly photopattern densely packed InP/ZnS Quantum Dots that achieve an optical density of 2 at sub 10 μm thicknesses while preserving the photoluminescent quantum yield. 

   more » « less
5. Colloidal semiconductor quantum shells for solution-processed laser applications

   https://doi.org/10.1039/D4NR04653F  

   Nazar, Divesh; Waters, Amelia Dawn; Kannen, Maxwell Marshal; Harankahage, Dulanjan; Huang, Jiamin; Zamkov, Mikhail (February 2025, Nanoscale)

   Laser diodes based on solution-processed semiconductor quantum dots (QDs) present an economical and color-tunable alternative to traditional epitaxial lasers. 

   more » « less