TY - JOUR

T1 - Plants and architecture: the role of biology and biomimetics in materials development for buildings

AU - Raghavalu Thirumalai, Durai

AU - Spear, Morwenna

AU - Curling, Simon

AU - Ormondroyd, Graham

AU - Wootton-Beard, Peter C.

AU - Donnison, Ian

AU - Jones, Philip

PY - 2019

Y1 - 2019

N2 - This paper reviews plant-inspired biomimicry for novel materials applied within architecture and building elements. Bioinspiration is considered at a materials level, and examples explored through increasing scale, towards elements and components for application at the building level in new designs and approaches. The review of plant biology mechanisms indicates that a single plant attribute can give rise to many biomimetic concepts. It is common for these to overlap, providing different routes to interrelated technological or design challenges. By focusing on six specific plant inspirations (self-cleaning, self-healing, cell wall structures, plant movements, cellular structures and branched structures) the paper highlights established and emerging approaches in bioinspired materials. Several areas are identified where additional research is needed to progress from materials and small assemblies up to building element or full structure. One is service life, and may necessitate that self-cleaning and self-healing concepts are re-visited for new inspiration applicable to new generation materials. Multi-functionality will become increasingly important. Scaling of concepts from small prototypes to full elements also poses challenges in both the materials selection for stresses incurred, and the alteration of geometry to fit the structural form while retaining the biomimetic function. A holistic approach of multiple inspirations is often required.

AB - This paper reviews plant-inspired biomimicry for novel materials applied within architecture and building elements. Bioinspiration is considered at a materials level, and examples explored through increasing scale, towards elements and components for application at the building level in new designs and approaches. The review of plant biology mechanisms indicates that a single plant attribute can give rise to many biomimetic concepts. It is common for these to overlap, providing different routes to interrelated technological or design challenges. By focusing on six specific plant inspirations (self-cleaning, self-healing, cell wall structures, plant movements, cellular structures and branched structures) the paper highlights established and emerging approaches in bioinspired materials. Several areas are identified where additional research is needed to progress from materials and small assemblies up to building element or full structure. One is service life, and may necessitate that self-cleaning and self-healing concepts are re-visited for new inspiration applicable to new generation materials. Multi-functionality will become increasingly important. Scaling of concepts from small prototypes to full elements also poses challenges in both the materials selection for stresses incurred, and the alteration of geometry to fit the structural form while retaining the biomimetic function. A holistic approach of multiple inspirations is often required.

KW - Building materials

KW - biomimicry

KW - multi-functionality

KW - plant biology

U2 - 10.1080/17508975.2019.1669134

DO - 10.1080/17508975.2019.1669134

M3 - Article

VL - 11

SP - 178

EP - 211

JO - Intelligent Buildings International

JF - Intelligent Buildings International

SN - 1750-8975

IS - 3-4

ER -