Highly Reflective and Transparent Shell-Index-Matched Colloidal Crystals of Core–Shell Particles for Stacked RGB Films

Welling, Tom A.J.; Kurioka, Keisuke; Namigata, Hikaru; Suga, Keishi; Nagao, Daisuke; Watanabe, Kanako

doi:10.1021/acsanm.3c03940

Cited by 3 publications

(1 citation statement)

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“…This suggests that making the core size smaller is more effective in enlarging the cores’ motion range than increasing the electrolyte concentration, at least for the parameter range studied here. Smaller core particles come with the downside of a significantly smaller scattering cross section, as well as the scattering strength of the cores decreases roughly with the square of the volume of the particles (see also Figure S9); however, our recent work has shown that core particle sizes of around 100 nm can still facilitate highly reflective colloidal crystals. , It should be noted that the motion range of cores was measured in the DMSO/water mixture instead of deionized water. Although the zeta potentials of core particles in DMSO/water were different from those in water, the zeta potentials decreased with increasing the electrolyte concentration as in water (Table S1).…”

Section: Resultsmentioning

confidence: 99%

Switchable Bragg Reflections via Controllable Inner Particle Motion in Yolk–Shell Colloidal Crystals

Namigata,

Welling,

Watanabe

et al. 2023

ACS Appl. Opt. Mater.

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Yolk−shell particles consist of a hollow shell enclosing a mobile inner particle. Colloidal crystals made from yolk−shell particles are a unique structure, in which the disorder of highly scattering inner particles can be controlled, which allows for optical switching. In this work, yolk−shell particles were synthesized and assembled into an ordered structure. External alternating current (AC) electric fields were used to control the inner particle motion, as observed by confocal microscopy and optical reflection measurements. The colloidal crystal of yolk−shell particles showed long-range order due to the assembled shells but decreased short-range order due to the Brownian motion of inner particles. Using an AC electric field (25 V/mm), all inner particles moved electrophoretically, resulting in ordered inner-particle arrangements. This enabled the fast, reversible switching of the Bragg reflection intensities. Next, we investigated how a decreased short-range order when the field is off influenced the switchability. The largest optical intensity change was achieved with a high ionic strength (10 mM) and a small coreto-shell size ratio (∼0.3). Our proof-of-concept results show promise that with further optimization, even more strongly switchable photonic crystals can be achieved in this way.

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Section: Resultsmentioning

confidence: 99%