Building facades, as the interface separating indoor and outdoor environments, are pivotal in moderating energy exchange and central to occupant comfort and energy performance. Conventional facades are static and cannot adapt to climate fluctuations, often causing overheating, glare, and discomfort. Existing Climate Adaptive Façades address this through sensors and actuators, but add energy demand, complexity, and maintenance burden.

This research investigates a passive alternative in which responsiveness is embedded directly within the material. Shape Memory Polymers (SMP) are combined with 4D Printing (4DP), a fabrication approach that adds time as a fourth dimension, allowing a printed component to change shape after fabrication when triggered by heat above a transition temperature, recovering its original permanent shape without external energy. The main research question is how 4D-printed SMP can create a passive, climate-responsive façade, addressed across the material, component, and building scales. At the material scale, this thesis establishes an empirical parameter-to-deformation map, showing infill pattern governs deformation direction while thickness and infill ratio tune its magnitude. Three implementable façade designs were then developed, shown to be tunable toward opposing climates through fabrication parameters alone, supported by an integrated CAD tool linking material behavior, geometry, fabrication, and performance. Validated across two contrasting climates, Delft and Taipei, the resulting façades reduced solar exposure in the subtropical case and balanced shading with passive heating in the temperate case. The one-way SMP limits current durability and scalability. This study provides prototyping and evaluation framework for integrating SMP-based 4DP elements into passive façades, serving as a preliminary guideline for autonomous, energy-efficient envelopes. ... Read more