# Smart patterned surfaces with programmable thermal emissivity and their   design through combinatorial strategies

**Authors:** Nikolaos Athanasopoulos, Nicolaos J. Siakavellas

arXiv: 1706.03229 · 2017-10-13

## TL;DR

This paper introduces smart patterned surfaces with programmable thermal emissivity, designed through combinatorial strategies, enabling passive control of thermal radiation by transforming motifs from 2D to 3D structures with shape memory effects.

## Contribution

It presents a novel approach to designing surfaces with tunable emissivity using combinatorial design of motifs and their interactions, enabling passive thermal regulation without external power.

## Key findings

- Motifs can transform from 2D to 3D with shape memory effects.
- The global emissivity behavior is determined by motif orientation and material combination.
- Design strategies enable programmable thermal emissivity based on temperature-dependent interactions.

## Abstract

The emissivity of common materials remains constant with temperature variations, and cannot drastically change. However, it is possible to design its entire behaviour as a function of temperature, and to significantly modify the thermal emissivity of a surface through the combination of different materials and patterns. Here, we show that smart patterned surfaces consisting of smaller structures (motifs) may be designed to respond uniquely through combinatorial design strategies by transforming themselves from 2D to 3D complex structures with a two-way shape memory effect. The smart surfaces can passively manipulate thermal radiation without-the use of controllers and power supplies-because their modus operandi has already been programmed and integrated into their intrinsic characteristics; the environment provides the energy required for their activation. Each motif emits thermal radiation in a certain manner, as it changes its geometry; however, the spatial distribution of these motifs causes them to interact with each other. Therefore, their combination and interaction determine the global behaviour of the surfaces, thus enabling their a priori design. The emissivity behaviour is not random; it is determined by two fundamental parameters, namely the combination of orientations in which the motifs open (n-fold rotational symmetry (rn)) and the combination of materials (colours) on the motifs; these generate functions which fully determine the dependency of the emissivity on the temperature.

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Source: https://tomesphere.com/paper/1706.03229