Plant-Mimetic Functional Materials for Thermal Management and Suppression of Freezing

Abstract

Aeronautical technologies must operate under extreme dynamic and environmental conditions that challenge conventional systems for the management of thermal loads and make exposed surfaces prone to the accumulation of ice. Desirable solutions for addressing these challenges should involve a minimum of components and active elements, allow for multi-functional deployment within structural materials, and operate effectively over a wide range of environmental conditions. In developing new technologies to accomplish these tasks, we have adapted strategies observed in vascular plants. These organisms have evolved elegant, largely passive methods to manage fluxes of mass and energy to maintain hydration, provide thermal regulation, and control phase transitions to avoid damage due to cavitation and freezing. These plant strategies bring together micro- and nano-structured materials with metastable states of liquid water(both supercooled and superheated). In this project, we have designed and fabricated synthetic devices that capture the features of plant vascular physiology. We have exploited these systems to elucidate the fundamental physico-chemistry of phase equilibrium and transport involving metastable liquids. Further, we will use these platforms and our acquired knowledge of them to develop new technologies for heat transfer and control the formation of ice at supercooled temperature. In parallel, we have investigated the physiological features that allow plants to operate with metastable liquid states. Together, these studies provide a foundation of concepts and techniques to build high performance, multi-functional materials for current and future Air Force applications.

Document Details

Document Type

Technical Report

Publication Date

Oct 10, 2021

Accession Number

AD1153243

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