Stretchable Structural Color Filters Based on a Metal–Insulator–Metal Structure

Color filters play a big role in a large number of modern technologies such as displays, sensors, and photovoltaics. In particular, structural color filters possess a number of advantages like high tolerance to heat, resistance to photodegradation, and long‐term stability that make them a promising...

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Published in:Advanced optical materials 2018-11, Vol.6 (22), p.n/a
Main Authors: Ordinario, David D., Jinno, Hiroaki, Nayeem, Md Osman Goni, Tachibana, Yutaro, Yokota, Tomoyuki, Someya, Takao
Format: Article
Language:English
Subjects:
Bend radius
Cameras
Color
color filters
Deformation
Flexible components
flexible devices
Formability
interferences
Materials science
Mechanical properties
Optical components
Optics
Photodegradation
Photovoltaic cells
Sensors
Solar cells
stretchable devices
Substrates
ultrathin devices
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cited_by cdi_FETCH-LOGICAL-c4231-1ad4c01c0a096320ff641057c77e433c6402bd58ceea6559cdb42af21981ca1f3
cites cdi_FETCH-LOGICAL-c4231-1ad4c01c0a096320ff641057c77e433c6402bd58ceea6559cdb42af21981ca1f3
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container_issue 22
container_start_page
container_title Advanced optical materials
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creator Ordinario, David D.
Jinno, Hiroaki
Nayeem, Md Osman Goni
Tachibana, Yutaro
Yokota, Tomoyuki
Someya, Takao
description Color filters play a big role in a large number of modern technologies such as displays, sensors, and photovoltaics. In particular, structural color filters possess a number of advantages like high tolerance to heat, resistance to photodegradation, and long‐term stability that make them a promising choice for potential future optics‐based applications. In the field of flexible electronics, there are many sensors either reliant on optical phenomena or containing simple optical elements that are demonstrably flexible enough to adhere to uneven, deformable surfaces. Such devices require any integrated components to have similar or better mechanical properties. Here, ultrathin, stretchable, and flexible structural color filters based on a simple metal–insulator–metal (MIM) structure are investigated. The filters are fabricated on 1.3 µm ultrathin substrates, feature a minimum bending radius of 5 µm, and can be made to transmit any color in the visible range. Similar levels of performance to existing freestanding flexible color filters are maintained, with transmission degradation of no more than 2% after 1000 stretching or bending cycles. These findings demonstrate the feasibility of fabricating color filters possessing mechanical properties compatible with current state‐of‐the‐art flexible and/or wearable technologies. Color filters are a highly relevant component for modern technologies. Herein, ultrathin, stretchable, and flexible structural color filters are demonstrated. Remarkably, the performance of the filters is not greatly impacted by repeated mechanical deformation. Overall, these findings represent a strategy for making conformal color filters with compatible mechanical properties to current flexible and/or wearable technologies without sacrificing functionality.
doi_str_mv 10.1002/adom.201800851
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subjects Bend radius
Cameras
Color
color filters
Deformation
Flexible components
flexible devices
Formability
interferences
Materials science
Mechanical properties
Optical components
Optics
Photodegradation
Photovoltaic cells
Sensors
Solar cells
stretchable devices
Substrates
ultrathin devices
title Stretchable Structural Color Filters Based on a Metal–Insulator–Metal Structure
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