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2024 Study Architecture Student Showcase - Part V

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Welcome to Part V of the 2024 Study Architecture Student Showcase! In today’s installment, materiality plays a pivotal role in the functionality of buildings, designs, and various architectural processes. 

Cork, acrylic, steel, concrete, wood, timber, and wires – for many, they may seem like mere materials for building. However, the projects below invite viewers to think about these materials through a different lens. 

From rethinking raw material standardization to highlighting the benefits of mass timber, viewers are encouraged to think deeply about sustainable production and opportunities for innovation. Other projects focus on the use of cork as a sound-insulative and the integration of natural materials such as clay and man-made elements such as steel. 

L-Shape Modular Cork Shelving System by Suna Choi & Sara Mohamed, B. Arch ‘24
American University of Sharjah | Advisor: Tania Ursomarzo

This installation is designed to create a double-functional partition that provides sound insulation and serves as a shelving system. It will be installed between the open studio spaces in our architecture, art, and design college building (CAAD) to reduce noise while offering students a place to store their items. Additionally, it serves as an aesthetic decoration for the space.

We chose cork as the main material due to its excellent sound-insulative qualities. Plywood was initially selected as the secondary material to create the shelving planes; however, we later decided to use only cork to fulfill both sound insulation and shelving purposes. Cork is not only sound-insulative but also biodegradable and aesthetically pleasing with its natural color.

The L-shaped modules, consisting of three rectangular patterns, are strategically stacked to form a shelving system that can be used on all sides. To connect the cork L-shaped modules together, we experimented with different materials such as thin plywood and acrylic to create simple connectors. After multiple iterations, we chose acrylic for its transparency, which would not distract from the natural aesthetic of the cork, unlike plywood.

Finally, we painted the top view of the model (the shelving surfaces) using primary colors: red, yellow, and blue, inspired by Mondrian’s compositions.

Instagram: @suliman.studio, @suna.choi_i, @triptychnyc

MODULAR CORK ACOUSTIC INSULATION AND FURNITURE SYSTEM by Rabab Al-Ali & Razan Almajid, B. Arch ’24
American University of Sharjah | Advisor: Tania Ursomarzo

In approaching this project, our primary objective was to address the disruptive noise levels at the College of Architecture, Art, and Design (CAAD), where our site will be located. These noise levels are highly distracting for both students and visitors, necessitating an effective solution to enhance the acoustic environment. Our considerations for the site location are based on the noise levels. We identified the two loudest areas as the spaces between studios and the main entrance. These areas are particularly disruptive during pinups and reviews, necessitating a strategic approach to mitigate the noise and improve the overall environment.

Our aim is to design a flexible, easily movable, and rebuildable structure, ensuring multi-functionality. We sought to develop a solution that could be effortlessly relocated and reassembled multiple times, providing adaptability and improved acoustic management throughout the space. An additional benefit of our modular design is its versatility; the modules can be easily reconfigured into different types of furniture, demonstrating their efficiency and practicality.

We have selected cork as the primary material for our project due to its numerous advantages. Firstly, cork possesses excellent sound absorption properties, effectively addressing our main noise concern by significantly reducing noise levels and minimizing sound transmission between spaces. Secondly, its lightweight yet durable nature facilitates the easy construction, deconstruction, and relocation of our structure. Lastly, cork is a natural and sustainable material, harvested from the bark of cork oak trees without causing harm, making it an environmentally friendly choice.

Instagram: @ralali.arch, @rnm.arch, @triptychnyc

Wheel House by Tilden Reid Puckett, B.S. Architecture ‘24
University of Virginia | Advisor: Peter Waldman

I designed the Wheel House after experiencing land and water I know to be beautiful. Its sleek, sailboat-inspired lines and lotus flower aesthetics evoke a sense of tranquility and orthogonal organic beauty. The building’s foundation integrates seamlessly with the dam’s robust concrete structures, enhancing the synergy between natural and man-made elements. Inside, large windows and open spaces ensure an abundance of natural light, crafting an atmosphere reminiscent of being on an open ocean or beneath a cascading waterfall. Every detail, from the material strategy of utilizing the natural erosion of corten steel to the proportional light/heaviness that attributes to its vertical and horizontal harmony. 

The design draws inspiration from the works of renowned architects such as Frank Lloyd Wright, known for his integration of structures with their natural surroundings; Tadao Ando, whose use of concrete and light creates spaces that are both minimalist and profoundly serene; and Peter Waldman, my studio professor of whom’s work intelligently collages materials into profound sculptures of place. With its placement, the Wheel House defines the nature around it. Built on a steep slope, its terracing and retaining walls allow it to seamlessly rest under, on, and above its environment. This project reimagines the home and presents a more careful architectural attention to beauty and art. I believe that when one looks at this structure, they can start to imagine the coarse roar of the water falling down the dam and feel the rippling wind stream across the reservoir. I designed the Wheel House to express further land and water I know to be beautiful. 

This project won the Duncan J. McCrea Memorial Award.

Instagram: @tilden.reid, @aschool_uva

Epiphytic-Retrofitting: Wooden Structures to Top Out Unfinished Constructions on the Galapagos by Paula Cano-Vergara, M. Arch ’24
University of Texas at Austin | Advisor: David Heymann

Epiphytic-Retrofitting: Wooden Structures to Top Out Unfinished Construction on the Galapagos Research explores potential applications of lightweight timber members to envision design possibilities that might lead to more environmentally responsive architecture, endemic to the Galapagos Island in Ecuador. 

The study focuses on ten wood species, both endemic and introduced—Avocado, Bamboo, Black Carob, Cascarilla Cinchona, Guava, Galapagos Guava, Machinel, Mahogany, Matazarno, and Spanish Cedar—to explore how timber can replace conventional construction methods and address rapid urbanization and the prevalence of unfinished concrete structures.

The title emphasizes two concepts: “Epiphytic,” referring to plants that use other vegetation for physical support rather than nutrients, and “Retrofitting,” a sustainable method for vertical growth and densification. The project aims to protect the fragile ecosystem by reducing the exploitation of natural resources and restoring endemic vegetation. The proposed vertical expansion utilizes lightweight timber from six selected species to complete unfinished buildings, up to 5 floors total.

The structural capacity of each species is determined by grain structure, categorized into three main types: 1) Curvy and wavy, 2) Irregular, and 3) Straight grain. Structural elements are designed based on standard branch and trunk diameters and lengths, with Mahogany and Matazarno ideal for joints, Spanish Cedar and Guava for primary and secondary elements, and Avocado and Carob for cladding and decking planks. The proposal also includes three vertical growth strategies that prioritize efficiency by branching to the nearest points from the top element to the next floor, based on [the types of] tree branching: Dichotomous, Monopodial, and Sympodial. Additionally, trusses integrate the vertical elements and transfer loads to concrete frames ranging from 3x3m to 9x15m.

Despite common perceptions of timber as an unsafe and inferior material compared to its competitors, this research advocates for its potential in developing safe, low-carbon buildings. Timber supports better forest management, curbs deforestation, and promotes the use of locally-sourced materials. Additionally, the research serves to protect and contribute data records of remote geographies like the Galapagos Island, the “living museum and showcase of evolution.”

This thesis was selected for the Innovation and Material category, Fall 2024.

Instagram: @utsoa

De-Framing the Built Environment by Drew Dunphy, M. Arch ’24
University of Miami School of Architecture | Advisors: Christopher Meyer & Joachim Perez

To design is to challenge what has come before to create something new. In today’s modern era of architecture, there has been an explosion of new programs and materials that facilitate the design process and have increased the production rate exponentially. In doing so, the profession has accepted standard practices as rules and allowed material use and industry to become rigid.

Challenging what makes architecture function as a profession is not easy, but it is necessary to continue driving innovation. Using mass timber as a case study, De-Framing the Built Environment looks holistically at manufacturing, architecture, and construction to break down what is immediately accepted as best practice. 

De-Framing the Built Environment breaks the process by which design goes from raw materials to an inhabitable space into three focus areas. Starting with the manufacturing process, it challenges the current centralized system of material sourcing and calls for a regionalist approach that emphasizes sustainable sourcing. From there, it stresses the importance of integrated design that reorients the cost from strictly economic to include ecological and temporal design costs. Finally, De-Framing the Built Environment rejects the accepted lifespan of a building by focusing on architecture that is easy to assemble, inhabit, and disassemble with a low margin of wasted material. 

Design, by its very nature, should be synonymous with innovation. While this thesis focuses on mass timber, questioning the process by which raw materials are transformed into space is a universal principle that must be applied across disciplines and building practices. You, as architects, designers, and construction professionals, are integral to this change.

This project was awarded an Honorable Mention by the University of Miami School of Architecture Faculty Award for Outstanding Thesis Work in the Master of Architecture Program. 

Instagram: @dunphy_27, @LU_lab_miami, @ateliermey 

Turning Tree Forks into Structures: An Experimental Analysis of a Minimally Processed Material Within the Age of Standardization by Zachary Chartrand, M. Arch ’24
Lawrence Technological University | Advisor: Scott Shall

Since the Industrial Revolution, the building industry has dedicated enormous energy to developing processes that can take raw, idiosyncratic materials and produce highly controlled, specifiable products. This has served the building industry well for years. Material standardization allows for standardized structural details and procedures that can be easily followed by the common builder, [allowing them] to produce structures that can be analyzed and designed based on the uniform properties of the building product. Unfortunately, this process rejects those materials that do not meet the uniformity required, regardless of their unique structural potential.

Recent advancements in digital analysis allow for the ability to identify unique qualities within raw materials. Advancements in computational technology allow for the optimization of a structural design to accommodate for these idiosyncratic properties. The development of a platform, involving digital analysis and computational design, would make this method of design available to the common builder and architect. The development of a process, using common construction techniques, would allow the common builder to build structures using these idiosyncratic pieces. The development of this platform for design, and system of construction, would demonstrate that advancements in technology can initiate a movement towards more sustainable architecture by reducing the amount of processing necessary to use raw materials in a structural capacity.

This will be studied by obtaining an inventory of tree forks and scanning them into a digital inventory. A script will then be developed that optimizes fork fitment to different assembly logics for shell structures. Next, a joinery system and system of construction will be developed that processes the forks based on data outputs from the script. Success will be measured in joint precision and structural rigidity.

This thesis won the 2024 CoAD Deans Award. 

Instagram: @scott_shall

Moore Square Indie Music Center by Daniel Knorr, Bachelor of Environmental Design in Architecture ’24
NC State University | Advisor: Zach Hoffman

Moore Square Indie Music Center gives a home to the indie musicians of Raleigh, fulfilling their three core needs: practicing, recording, and performing. The center contains practice and recording room clusters in addition to a main performance venue space. The center embodies the spirit of the indie music community through the use of rhythm and movement and a familiar gritty materiality that alludes to the idea of “garage” or “basement” bands. 

Interstitial spaces generate chance encounters between musicians and fans. This not only strengthens the indie music community, but more importantly, allows musicians to engage and grow their fan base.

The Stitch / Chance Encounters

The most important elements of the Center are the interstitial spaces that occur between major programmatic elements. These spaces act as an environment where chance encounters can happen between musicians and fans. This is especially important for indie music, a culture that thrives on strong interpersonal connections, and a strong dedicated fanbase. 

The entire Center is split down the middle, with the left theater half belonging to the community, and the right practice and recording half belonging to the musicians. The atrium space, “the stitch,” bridges the two halves of the Center together.

Materiality

The idea of a garage band has pervaded indie music culture since its inception. To capture this spirit, the Center uses materials such as cast-in-place concrete and raw metal, alluding to the origins of indie music. On the other hand, wood is used in the interiors of the practice studios to create a homey atmosphere, alluding to the idea of a sole musician practicing in their bedroom.

Texture and material are also used to signify the function of the spaces within the Center. The interiors of both the theater and the studios have highly textured acoustic paneling systems, whereas their exteriors are seamless and perfect. The exterior wood cladding of the theater serves to create an inviting presence that guides visitors into the theater. On the other hand, the monolithic concrete used in the exterior of the studios creates a fortress-like feeling, “protecting” the musicians inside.

This project won the ​​2024 AIA Triangle Student Design Award.

Instagram: @daniel.knorrr 

The Clay Huts and Metal Shed by Shixian Zhang & Ruozhao Cui, B. Arch ’24
Cal Poly University – Pomona | Advisor: Claudia Wainer

The Clay Huts and Metal Shed is a community-oriented ceramic arts and design center located in Elysian Valley. It is positioned with its north side facing the LA River and the future Taylor Yard development, and its south side overlooking the Lewis MacAdams Riverfront Park. The rich history of Elysian Valley, marked by a blend of manufacturing facilities, single-family homes, and a flourishing artist community, forms a distinctive backdrop for this project. The design merges existing industrial elements with new, organically inspired clay volume, aiming to create not just an artistic space for ceramic artists but also a vibrant community hub for the Elysian Valley neighborhood. 

This project involves the adaptive reuse of an existing industrial building, which serves as a shell for the newly proposed clay volumes. The design strategy begins by categorizing program spaces into enclosed and loose types. Each clay volume, distinct in its form, encompasses a variety of enclosed functions. The interstitial spaces between these volumes, designated as loose programs fostering interaction and community engagement. Additionally, the design incorporates two sculptural gardens within these volumes. The clay huts deform the metal shed perimeter and break down the scale of the building, making it more approachable and relatable to the community.   

The material palette is a harmonious blend of clay and steel, symbolizing the integration of traditional craftsmanship with industrial production. The clay walls, constructed of rammed earth, feature a scalloped facade that lends a tactile, organic feel to the design. The primary structure utilizes the existing metal framework, altered and updated to support the new programmatic volumes. This interplay of materials is a defining characteristic of the design, with some areas showcasing an overlap of clay and steel through openings, while in others, the metal shell stops short, allowing the clay volumes to peek through. 

The juxtaposition of the clay huts against the metal shed highlights the contrast between stereotomic and tectonic, creating varied transitions in different spaces. For instance, upon approaching the building, one can see both the clay and corrugated metal cladding simultaneously. Entering the building through the open programs, visitors experience the interplay of the metal shed, steel structure, and clay huts. Once inside a clay volume, the surroundings are entirely enveloped by clay finish, offering a distinct spatial experience.

Instagram: @claudwain

Debunking the Myths of Wood: Mass Timber Contemporary Architecture to the Rescue of Cultural Heritage by Neftalí X. Luciano-Castillo, B. Arch ’24
Pontifical Catholic University of Puerto Rico | Advisors: Manuel De Lemos-Zuazaga & Pedro A. Rosario-Torres

Wooden architectural heritage represents an invaluable asset in the cultural and historical narrative of Puerto Rico. With its unique characteristics, craftsmanship and carpentry of a bygone era, it stands out from other architectural styles. Moreover, wooden heritage serves as a catalyst for reevaluating our approaches to designing and constructing buildings. As society gravitates towards sustainable practices, the resurgence of wood as a primary construction material offers a promising opportunity. This resurgence not only revitalizes historical structures but also enables a harmonious coexistence between traditional wooden architecture and contemporary design. However, this traditional architecture is often misjudged and misunderstood due to the poor knowledge and involvement of people in their culture, and the lack of legislations in favor of heritage preservation. Due to these and other external threats, these structures have begun to disappear from our urban fabric, leaving not only a void in space, but also in our culture and identity.

As a response to these factors, the proposal seeks to promote the preservation of wooden architectural heritage through community engagement, tourism, education, testing and manufacturing, in a design that serves as a living laboratory that combines historic structures with mass timber construction. The synergy between historic preservation and the incorporation of contemporary architecture signifies a unique chance to embrace the past while paving the way for a more sustainable future. The project’s location is the Central Aguirre Historic District in Salinas, Puerto Rico, an old sugar cane company town that houses a collection of historic wooden structures. The design is organized into three main volumes: a restored and repurposed historic building that houses museum spaces; a second volume that contains a manufacturing laboratory; and a taller volume that functions as a school of wooden architecture design and conservation. The main goal of this project is to serve as a catalyst for the preservation and restoration of historic wooden structures in Aguirre and all around Puerto Rico.

Instagram: @neftalixavier

Harmonic Convergence by Nicholas Owens, M. Arch ’24
Lawrence Technological University | Advisor: Masataka Yoshikawa

This project explores spatial and structural design, inspired by the concept of a ‘Cabinet of Curiosities’ and music. The initial phase focused on finding objects and integrating music, using guitar strings and thick wire to symbolize sheet music, representing order in chaos.

In the representation phase, the project incorporated methodologies from Neil Denari and Borges. The transition to 2D representation utilized Maya to create music stand models linked by chains, with six layers of wire illustrating chaos and order visually.

During development, Rhino was used for initial designs and Zbrush for refinement, creating a wire mesh structure. This phase emphasized materiality and spatial dynamics, resulting in a unique architectural design facilitating gallery spaces and visitor pathways.

The final phase integrated the structure with its landscape, showcasing LED wires and spatial potential. Interior renders highlighted the gallery space’s unique characteristics, creating a quasi-moiré effect with overlapping glass structures. The project envisioned future enhancements, including wire animation to visualize music flow, enhancing the visitor experience and reflecting the project’s foundation in music and organized chaos.

Overall, the project is a sophisticated blend of design, representation, and development, creating an innovative space that intertwines musical and structural elements to find order in chaos.

Instagram: @owensarchitecturaldesign, @masataka.yoshikawa

Stay tuned for Part VI!

2023 Study Architecture Student Showcase - Part XXVIII

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In Part XXVIII of the 2023 Study Architecture Student Showcase, each project focuses on the construction and architecture fields’ roles in climate change. The presented student theses and designs present a tangible solution to address climate change with proposals ranging from using materials including mass timber and “Hempbrick” to systematic changes such as incorporating decay into the designs and introducing sustainable product life cycles. Overall, the projects advocate for reducing waste to support long-term sustainable practices.

Reconstituting Rubble by Andrew Griffin, M.Arch ‘23
University at Buffalo | Advisors: Christopher Romano & Miguel Guitart

Five hundred and thirty-four million tons of construction and demolition debris are generated by the United States every year. This debris is anonymously moved away, invisible to most, to distant landfills far removed from its origin to lie dormant at the presumed end of its life. This demolition is a natural and necessary part of our current economic cycle, the permanence of the buildings we design is too often overstated. In a time when environmental issues plague the industry, simply discarding material is no longer a reasonable long-term option. Perhaps the scope of an architect’s involvement should extend into a building’s afterlife. Reconstituting Rubble proposes an adjustment to the material flow of building debris after demolition, advocating ways of transforming architectural rubble to develop building procedures that integrate waste-bound materials into new architecture. Drawing from new innovations and old technology, the project strives to lay out building end-of-life processes to divert would-be discarded material into new building assemblies.

This research looks at demolition rubble as a continuous stream of usable material in need of transformation. The proposed process steps involve demolishing, cataloging, refining, assembling, and reconstituting. The eventual result of this process examines the qualities of rubble, the roughness, the irregularity of its texture, shape and size. These are all traces of its past and show the immense effort it took to become reconfigured remains. 

Instagram: @arc_andrewgriffin

Banished Into Existence: Agritecture at The Intersection of Architecture and Agriculture by Yan Ferris Konan, M.Arch & M.Red ‘23
University of Maryland, College Park | Advisor: Michael T. Ezban

Building operating emissions account for 28% of global greenhouse gas emissions while building components account for 11%. To mitigate these effects, we must reduce the carbon footprints of construction activities, building materials, and sequestering carbon dioxide in forests and farmland. Industrial hemp is a solution to all these challenges. Hemp is a carbon-negative crop, absorbing more carbon dioxide than trees, and thus represents a unique sequestration opportunity. By using hemp as a construction material, we can improve the thermal efficiency of our buildings, therefore reducing operational carbon. Finally, by substituting Hempbrick, a mixture of hemp and various binders, for more carbon-intensive materials, we can reduce the embodied carbon of the built environment. This thesis proposes a productive hemp landscape that will be open to the public as an agritourism destination. The project will raise public awareness about hemp cultivation as an agricultural opportunity and demonstrate the potential of hemp as a construction material, highlighting its multiple possible contributions to tackling the climate crisis.

The Intersection, located in Beltsville, Maryland, is a Productive Hybrid Hemp Farm with a visitor center, a manufacturing facility, a multipurpose Classroom, and office seating on two floors to serve as a demonstration and educational hub for Prince George’s County. This proposal aims to educate the public on the opportunities of this insulating material known as “Hempbrick.”

The site is divided into Three Parcels totaling 77 Acres. Parcel 1: Baltimore Avenue (15.5 Acres). Parcel 2: Baltimore Avenue (50 Acres). Parcel 3: Rhode Island Avenue (11.5 Acres). The Farm’s primary goal is cultivating and harvesting Hemp for industrial applications. There will also be a manufacturing facility where the hemp will be decorticated into bast and hurd fibers required to produce Hempbrick. In addition, there will be a Visitor Center where the public will learn about the benefits and processes of hemp. Tenants from The University of Maryland extensions have already expressed an interest in leasing office spaces to further their research on hemp and its advantages.

This project received The Architecture Thesis Award – 2023 University of Maryland, College Park 

Forest to Framework by Eleanor Selzer, M.Arch ‘23
University of Southern California | Advisor: Sascha Delz

With the construction industry accounting for roughly 40% of all global carbon emissions, a clear and vast opportunity exists within the Architectural and Construction industry to enact real change in fighting the climate crisis. This change, as seen from a top-down perspective within the supply chain, could include material substitutions, technology innovation and implementation, and independence from non-renewable energy sources. These initiatives geared up in practice in recent years, but the industry is lagging behind if we are to make any real impact on our emissions and meet global climate goals. 

The UN projects that there will be roughly 2.3 billion new urban dwellers by 2050. All of these new residents will require an enormous amount of infrastructure to sustain this influx, most importantly housing. Most low-to-medium-rise housing buildings are constructed using timber products, and so there is a profound opportunity to exploit this demand for new development as a means to mitigate the climate crisis and create a carbon sink within our cities. 

When designers consider viable substitutions that are readily available, mass timber products are the top contenders. The opportunity to sequester carbon from the atmosphere while also providing a structurally sound, lightweight, and aesthetic material makes wood a clear solution for fighting climate change. 

It is vital for timber products used in the construction industry to be sourced from sustainable-certified forest lands to ensure that deforestation of green reserves is mitigated and there is a guarantee of a true renewable resource. The existing supply chain, however, is not vertically integrated, and it follows the cradle-to-grave pipeline, where building materials will most likely end up in landfills following demolition. As a solution to climate impacts, the industry must introduce a closed-loop product life cycle system following the cradle-to-cradle ideology. 

This sustainable wood products cycle requires all players across the supply chain to redefine how they purchase, distribute, design and use mass timber products. The main priorities within this sustainability product cycle are ensuring the increase in sustainable land management practices, growing the demand for sustainably harvested and produced mass timber products, updates to the building codes to mandate the use of these products and creation of deconstruction and reusable toolkits that can be adopted into standard design and construction practices.   

This project seeks to re-frame the framework of sustainably harvested mass timber products and show how they can be utilized in design practices to maximize flexibility, incremental growth, reuse and adaptability. Specifically this framework is applied to an affordable housing cooperative model located in Venice Beach, Los Angeles, comprising of flexible and deconstructable mass timber modules. 

This project received the USC Master of Architecture Social & Environmental Dimensions in Directed Design Research Award – In recognition of the most outstanding graduate final degree project exploring social, cultural, and environmental concerns.

Instagram: @ellie_selzer, @coop_urbanism

Heteromorph by Grégoire Gaudreault, M.Arch ‘23
University of Montreal | Advisor: Andrei Nejur

On a global scale, more than one billion people live in precarious housing situations, many construction materials are regularly sent to landfill sites or, worse, burned. However, these rejected materials represent a richness whose reallocation would lead to a significant economy of resources. Therefore, reusing materials from the construction industry could be part of the solution. This thesis project attempts to establish an architectural response to these challenges. Specifically, the proposed solution involves a constructive system for assembling temporary shelters using a diverse range of reclaimed and heterogeneous materials. The research focus of this thesis primarily revolves around utilizing digital technologies to discover new solutions to social and urban problems, while promoting the development of innovative construction methods that aim to reduce the environmental impact of architecture.

In a conventional architectural project, the materials used are directly linked to the envisioned form conceived during the design process and are typically integrated toward the end of the project. The proposed workflow seeks to invert this logic: reclaimed materials are used as inputs to imagine the shape of a shelter. Available resources dictate the morphology and composition of the projected form. More specifically, the proposed digital solution is based on an algorithm created using visual programming software, which enables the revalorization of materials recovered from waste in the construction industry. Any shape obtained through this method is composed of a configuration of 10 typical triangles, resulting from a combination of three specific edge lengths. These triangles can be constructed using either three linear elements or a single planar element, thereby expanding the range of possible materials. Low-tech metal nodes are utilized to connect these elements, facilitating the assembly and disassembly of the system. This flexibility allows for several variations or even partial or complete reconfiguration of the initial shape. In addition, the proposed system’s evolutive character encourages its components’ re-employment to limit its environmental impact.

This project received “Prix de l’Observatoire Ivanhoé Cambridge Nomination au Prix d’excellence pour étudiants Canadian Architect”

Instagram: @greg_g, @fac_ame_umontreal, @architecture.udem

An Architecture of Decay: Addressing Building Waste Through Biologically Integrated Architecture by Carson Stickney, M.Arch ‘23
Lawrence Technological University | Advisors: Scott Shall (Chair), Dan Faoro (Member) & Sara Codarin (Member)

There is a dissonance within architectural practice between buildings designed to be permanent, and the inevitability of building impermanence. This produces unusable waste at the end of a building’s life cycle. Materials are designed to become obsolete and replaced over time, leading to additional waste during a building’s inhabitance. Construction conventions value the low-cost consumption of resources such as concrete and metals over their effect on the environment (McDonough, Braungart, 2002). The current model of construction, maintenance, and demolition that most buildings go through ignores the resources and materials that are used and discarded, creating by-products that can never be used again by humans or the natural environment.

In order to align programmatic lifecycles with building creation and material decay, architects must incorporate decay in design, allowing building materials to continuously support human and biological use when a building is abandoned or demolished (figure 0.1). All buildings must die, but their material by-products do not need to be wasted. Incorporating decay is an opportunity for the future growth of architectural spaces and realigns the buildings that we make with the natural cycles that affect them. Therefore, to explore this potential, and minimize the waste associated with a building’s decay or demolition, architects need to design buildings and urban landscapes with the eventual decay of products in mind, to eliminate wasted resources, and reinforce the existing natural cycles impacting our work.

To investigate this claim, this project will design a 2-story mixed-use structure, using fully biodegradable materials. This development type has a legacy in architectural practice and is a staple construction type of most major U.S. cities. It also acts as an advantageous operating system relative to this thesis due to its cyclical resiliency to programmatic cycles, and its need for continual replacement and maintenance of materials. This investigation is intended to relink human spaces with natural ones, fostering the perpetual growth and balance of both systems with each other.

Instagram: @cstickney02, @scott_shall

Passing Permanence: Reversible Building Practices in the U.S. by Aaron Baldwin, M.Arch ‘23
Lawrence Technological University | Advisors: Scott Shall, M.Arch/RA, Sara Cordarin, Ph.D & Daniel Faoro March/UD, RA

The construction and demolition industries generate abhorrent amounts of waste through the inefficient generation and unplanned removal of permanently intentioned buildings that cannot last forever. Current strategies of material construction often consume, permanently alter or degrade materials being used, resulting in the inability to wholly reuse valuable building components. As a result, existing unused structures will often become waste, or require resource-intensive recycling or remanufacturing to salvage portions of material (USEPA 2018).

Buildings are not permanent. The current lack of life-cycle design and expectation for buildings to last indefinitely leads to a loss of “technical nutrient” potential (Braungart 2002). The reduction of waste, the continued reuse of materials and designing for component longevity can achieve a fundamental level of sustainability, as the concept of waste is antithetical to the ability to maintain a process over time. To recapture the potential of a building and remove the ecologically harmful effects of permanence that occur after the building is no longer needed, the production, construction, use and demolition of architecture should ‘leave minimal trace’ on its building materials and site.

A current lack of reversible and circular practice in the U.S. exists due to many existing social, cultural and economic factors. The focus on tradition, risk aversion and bountiful space for new development allows the country to remain stagnant and reliant on existing building methodologies without the push for change. Initial reversible architecture located in the U.S. will not be made out of newly developed components, but primarily of existing standardized materials joined in newly reversible methods.

Architecture should not be destructive. An architecture that leaves minimal trace does not have to employ highly engineered componentry and new modular solutions that restrict design outcomes but rather can modify existing techniques and tectonic understandings to remove wasteful practices that intentionally degrade or destroy material resources. Minimal trace architecture simultaneously upholds the health of its materiality through the redefinition of connection types while supporting its site and larger context through the removal of systemic inefficiencies and unnecessary permanently intended change.

See you in the next installment of the Student Showcase!