Sticky Multicolor Mechanochromic Labels

de Castro, Lucas D. C.; Engels, Tom A. P.; Oliveira, Osvaldo N.; Schenning, Albert P. H. J.

doi:10.1021/acsami.3c19420

ACS Appl. Mater. Interfaces

2024

DOI: 10.1021/acsami.3c19420

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Sticky Multicolor Mechanochromic Labels

Lucas D. C. de Castro,

Tom A. P. Engels,

Osvaldo N. Oliveira

et al.

Abstract: Sticky-colored labels are an efficient way to communicate visual information. However, most labels are static.Here, we propose a new category of dynamic sticky labels that change structural colors when stretched. The sticky mechanochromic labels can be pasted on flexible surfaces such as fabric and rubber or even on brittle materials. To enhance their applicability, we demonstrate a simple method for imprinting structural color patterns that are either always visible or reversibly revealed or concealed upon me… Show more

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2024

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Cited by 6 publications

References 39 publications

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Bio‐Inspired Cellulose Composites With Multicolor Separation via Electro‐Thermal and Magneto‐Thermal Techniques for Multifunctional Applications

Wen,

Yue,

Wang

et al. 2024

Adv Funct Materials

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Biomimetic optical devices based on cellulose nanocrystals with tunable structural colors have received significant attention recently. However, the limited ability to control multicolor separation beyond simple single‐color modulation restricts its practical applications. Here, a diversified multicolor separation strategy for the cholesteric phase cellulose composite (CPCC) is presented. The CPCC is prepared by integrating a high‐concentration self‐assembled hydroxypropyl cellulose with a cross‐linked poly(acrylic acid‐acrylamide) (P(AA‐AM)) network. By adjusting the cross‐linking degree of P(AA‐AM) in CPCC, Thermally induced multicolor separation is achieved from a homochromatic state at room temperature to multicolor patterned display at elevated temperatures. Furthermore, by utilizing the electric heating effect of conductive carbon oil, the multicolor separation under low voltage is achieved, and based on this, pixelated electro‐thermochromic displays are developed. Additionally, magneto‐thermal multicolor separation induced by introducing FeNi3 nanoparticles is investigated with efficient magnetic induction heating ability into CPCC. The multicolor separation effect is further improved by pixelated distribution of FeNi3 nanoparticles and adjusting the concentration of FeNi3 in each pixel. Finally, thermochromism, electro‐thermochromic, and magneto‐thermochromic functionalities are integrated into the CPCC, achieving advanced multilevel information encryption. This multilevel approach of controlling multicolor separation significantly enhances the functionality of nanocellulose in various potential photonic applications.

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Bio‐Inspired Cellulose Composites With Multicolor Separation via Electro‐Thermal and Magneto‐Thermal Techniques for Multifunctional Applications

Wen,

Yue,

Wang

et al. 2024

Adv Funct Materials

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show abstract

Programmable Mechanochromic Time Integrators

van Niekerk,

Martens,

Flapper

et al. 2024

Adv Funct Materials

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Mechanochromic polymers are receiving much attention for monitoring the structural performance of materials. Current mechanochromic polymers however do not offer simultaneous detection of the duration and degree of strain while retaining memory of the strain history. Here a structurally colored polymer coating is reported that can indicate, quantify, and memorize strain over time. The mechanochromic polymers are fabricated by a simple and scalable bar coating process. The coating consists of chemically and optically distinct cholesteric liquid crystal droplets. Upon strain, the droplets deform causing an eye‐discernible reflective color change through a diffusion‐based compositional ripening process. The response depends on both the degree and duration of strain and can be easily adjusted by the concentration of droplets in the coating. The programmable mechanochromic time integrator offers simultaneous and sensitive detection of strain over a wide range while exhibiting memorability. The user‐interactive interface allows people to visually perceive the strain history of materials and introduces a novel mechanochromic material for monitoring the structural performance of materials ultimately enhancing both safety and performance.

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Mechanochromic Displays Based on Photoswitchable Cholesteric Liquid Crystal Elastomers

de Castro,

Lub,

Oliveira

et al. 2024

Angewandte Chemie

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Stimuli responsive optical materials are attractive for many areas, from healthcare to art design. However, creating intricate color‐changing patterns for visual information is still a challenge. This work describes the preparation of mechanochromic structural colored intricate pictures imprinted in cholesteric liquid crystal elastomers by using a chiral isosorbide molecular photo‐switch. The photo‐switch contains a photoisomerizable cinnamate moiety and was incorporated in a main chain liquid crystal oligomer with photopolymerizable acrylate end groups. After coating, the structural colored film was irradiated with ultraviolet (UV) light in air causing E/Z isomerization of the cinnamate units leading to a redshift of the structural color of the film. A grayscale photomask was used to spatially control the photoisomerization reaction and imprint colorful pictures such as portraits and landscapes, in the cholesteric liquid crystal films with high resolution. Photopolymerization in a nitrogen atmosphere led to a mechanochromic cholesteric liquid crystal elastomer with striking structural colors that blueshift upon strain independently. The sharp details of the patterns were preserved even under deformation and the system returned to the initial state upon strain removal. Our work offers a simple photo‐switch approach to prepare stimuli responsive optical polymers imprinted with color‐changing pictures of unprecedented complexity.

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Sticky Multicolor Mechanochromic Labels

Cited by 6 publications

References 39 publications

Bio‐Inspired Cellulose Composites With Multicolor Separation via Electro‐Thermal and Magneto‐Thermal Techniques for Multifunctional Applications

Bio‐Inspired Cellulose Composites With Multicolor Separation via Electro‐Thermal and Magneto‐Thermal Techniques for Multifunctional Applications

Programmable Mechanochromic Time Integrators

Mechanochromic Displays Based on Photoswitchable Cholesteric Liquid Crystal Elastomers

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