在時間的流動下，不管是自然條件的氣候改變或是人為條件的生活轉變，建築空間必須反應人與環境的變動，透過主動或被動的方式改變現有的物質狀態，空間產生新的面貌及回饋。為了改變物質的本身性質，材料成為研究對象。
本研究嘗試材料的重新詮釋及構築的發想，賦予複合新材料在空間環境上的新形式，除了達到創新的空間體驗與永續發展的目的，並探索材料潛力及多樣性。本論文從「生物性材料」為主題，探索以智能建築為基礎的動態建築表層設計，生物性材料牽涉到隨著時間成長的構造、感應環境能力、物理反應的變動關係，並自我折疊的調整組構形態及大小。材料特性與形態控制將是初步的研究方法，伴隨而來材料與型態的組織與連結，折疊結構、複雜形狀等的變動關係，使空間具有彈性的動態表現。
本研究進行一連串的實驗，包括探討材料的形式、構築及適應，並配合跨領域技術的整合與實體模型的演練及紀律，分析動態效果與電腦參數化運算來同步模擬及測試，最終將現有自然條件及環境因子，反應在空間形式本體上，使其顯著地表現其構築與材料的對話關係。

As time progresses, whether it is nature’s changing conditions or human adaptation, architectural space must react to the change in circumstances that interact between people and the environments. Space will produce new appearances and feedback in response to change. Thus, materials become the increasingly research topic in order to deal with the very nature of change.
This research attempts to explore the concept of materials, providing complex new spatial environments and forms, not only achieving innovative architectural expressions, different types of experiences in space and sustainable development, but also exploring the potential and diversity of materials. This thesis, with “biomimetic materials” as its main subject, explores intelligent building based on dynamic architectural surface design, the involvement of biomimetic materials in the process of construction, the ability to sense physical changes in the environment, and the capacity to self-adjust shape and size with folding mechanisms. The first step on the research is the full comprehension of the material properties and morphology control, with the organization patterns, connections, and folding structures, to make room for an elastic dynamic performance.
This research conducted a series of experiments, studying the forms, construction and adaptation of materials. Using interdisciplinary technologies and practical models, analyzing the dynamic effects and using parametric design to synchronize both simulation and testing. Finally, this study presents how the natural conditions and environmental factors react together, affecting the form of the space, giving significance to the performance in a dialogue between construction and the material.

英文文獻
[1] Ming Tang. (2014). Energy Forum：AdaptiveSkin-Data driven design and fabrication
[2] Andreas, H. (2014). Energy Forum：Feasibility studies of photovoltaic and bionic aspects of future energy-generating building skins
[3] Kathy, V., Geoffrey, T., Lars, J., Mary, O. (2014). Energy Forum：Research Through Design for Responsive Multi-Cellular Pneumatic Envelope Systems
[4] Kynthia, C., Antigoni-Maria, K., Konstantinos-Alketas, O. (2013). Energy Forem：Climate-responsive shading systems with integrated Shape Memory Alloys (SMA)
[5] Geoffrey, T., Kathy, V, (2013). Energy Forum：Responsive Envelopes-Bridging environmental response and human interaction
[6] J.B. da Concei
中文文獻
陳嘉懿(2014). 環境感應式建築物外殼的發展方向,第十一屆臺灣建築論壇-建築宏觀 宏觀建築

潘晨安.(2007). 可回應建築 成功大學建築研究所 -以感知運算為基礎的動態建築設計.,國立成功大學建築研究所., 碩士論文