From the pre-Columbian period of the Americas –during which cultures such as the Olmec, Maya, Purepecha, and Mexica (Aztec) thrived– to the modern era where architecture has been influenced by social movements and even natural disasters, Mexican architecture showcases a valuable architectural expression, with its own unique voice and distinctive characteristics. Nobel Literature Laureate Octavio Paz argued that architecture is an incorruptible witness to history. Likewise, the materials used to shape it have acted as protagonists of that history, enduring in many cases over time and evolving thanks to the generations of architects who have contributed to it, from different perspectives.
To trace a timeline, it is possible to take as a starting point pre-Hispanic architecture, which exhibited a diversity of nuances due to Mexico's vast territorial extension. This allowed diverse cultures to find their niche and develop their characteristic architectural styles. Subsequently, the era of Spanish colonization, which itself drew influence from Islamic architecture, represented a noteworthy turning point in architectural development. This phase endured until the advent of Mexican Independence in the 19th century. In turn, this marked the initiation of social and cultural movements, both during and after the Mexican Revolution in the early 20th century.
https://www.archdaily.com/1005554/materials-that-define-the-contemporary-mexican-architectural-aestheticEnrique Tovar
As the world increasingly recognizes the importance of adopting sustainable construction practices, bamboo’s versatility, strength, and renewable qualities are generating significant momentum in the transition toward a circular material economy. From initial idea to completion, this article will provide you with valuable insights to begin your bamboo building project, from the perspective of Bamboo U.
Oulu City Council has approved the AALTOSIILO restoration proposal by Skene Catling de la Peña. The concrete structure will be restored and reimagined as a multi-media performance, exhibition space, and “Tar Bar.” The 525 sqm Silo used to be used for storing woodchips and will now become a digitized communication point to connect the building with its surroundings. Now nearing its 100th anniversary, the proposal aims to at least double its lifespan.
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Courtesy of Atrium Ljungberg | White Arkitekter
Atrium Ljungberg has just revealed Stockholm Wood City – the world's largest urban construction project in wood. Construction on the project is expected to begin in 2025, and the first buildings are expected to be completed in 2027. The initiative is a demonstration of Swedish sustainability.
The largest wood-building project in the world is now in progress, covering an impressive 250,000 square meters. The project sets a sustainable example for the real estate market, which is essential because built structures contribute a sizeable 40% of the world's CO2 emissions. Furthermore, Stockholm Wood City is set to become a turning point in sustainable architecture and urban planning. Situated in Sickla, southern Stockholm, this innovative neighborhood will offer an additional 2,000 houses and 7,000 business spaces. By merging workplaces, homes, neighborhoods, dining establishments, and retail spaces, it aims to create a vibrant and dynamic urban environment.
As awareness of water scarcity, water stress and environmental sustainability grows around the world, the concept of "water footprint" is becoming increasingly relevant. Unlike its more popular cousin, "carbon footprint", which focuses on greenhouse gas emissions, the water footprint (WF) provides a holistic view of water used throughout the life cycle of a product, process, or activity. It measures the amount of water consumed (directly and indirectly) and polluted –taking into account different types of water resources– and serves as a valuable tool for companies, policymakers, and individuals to understand and address their water-related impacts. There are even online calculators that measure our individual footprints through simple questions about our homes, appliances and even eating habits.
Timber is a natural, renewable material, easy to fabricate, and with low-carbon emissions. As a construction material, however, when put under enough directional force along its grain, sawn timber is structurally unstable, so deemed unsuitable under higher loads. In comparison, the manufacture of cross-laminated timber (CLT) involves simply gluing multiple layers of timber together at right angles. By crossing the direction of the grains, CLT achieves a far higher level of structural rigidity along both axes. CLT boards start with a minimum of three layers but can be strengthened further with the addition of more. Simply put, due to the complex physics involved in the perpendicular lamination, the strength of CLT board is similar to that of reinforced concrete, and has proven performance under seismic forces.
So what’s new? Wood’s been around for long enough now, and we’ve been using it as a building material for centuries. Surely this isn’t the first time someone’s realized it gets stronger the more you use it? Well… as you’d expect, the changing popularity of cross-laminated timber in construction does coincide with a greater understanding and focus on environmental causes, but the relationship hasn’t always been positive.
Housing is one of the primary aspects of the architecture profession. There are many ways to explore it, from a subordinate program such as a religious cloister to the splendor of a single-family home. Luis Fernández-Galiano is torn between the "waste" of a low-density area in this type of housing and its seductive formal charm. He reminds us that high-density collective housing, such as apartments, makes more sense in an urban context.
"Biodomes" in the mountains of the United Arab Emirates seek to promote ecotourism. Courtesy of Baharash Architecture
Buckminster Fuller's obsession with geodesic shapes placed them in architectural history. The spherical appearance and the complex structural framework gained different appropriations and scales over the years, one of the most iconic works being the Montreal Biosphere, the US pavilion for the 1967 World Expo, designed by him. These structures emerged from his interests in material efficiency, structural integrity and modularity. Back in the 60s, he understood these features as essential for a sustainable and easily replicable intervention
Kampung Admiralty / Ramboll Studio Dreiseitl and WOHA. Image Courtesy of WOHA
A heavily cited fact within the architecture industry is that the built environment accounts for 40% of global carbon emissions. The concerning statistic puts immense responsibility on construction professionals. The idea of sustainability in architecture urgently emerged as a way of bandaging environmental damage. A wide range of sustainability practices aims no higher than making buildings “less bad”, serving as inadequate measures for current and future architecture. The problem with sustainable architecture is that it stops with ‘sustaining’.
In order to maintain the current state of the environment, the architecture community has been working towards greener means of production. Conventionally, a green building employs active or passive features as a tool for reduction and conservation. Most sustainable designs view buildings as a vessel of their own rather than integrated parts of their ecosystem. With the planet’s current needs, this approach is not enough. It is not enough to sustain the natural environment, but also restore its processes.
There are several constructive technologies to configure the structural system of a building. From the 1960s onwards, the adoption of techniques that enabled the interaction between different materials became increasingly common, diversifying the design language and seeking the main advantages each element has to face certain situations. Over the years, some mix concrete, wood, stones or steel.
When organizing the elements, materials and colors of an architectural layout, architects can successfully guide users through a room and its different spaces, therefore creating an easy and seamless trajectory for those inhabiting it. By exploring innovative strategies to create new ways of arranging a space, architecture can use color to boost certain aspects of a project’s scheme. The use of color in architectural design combines different factors beyond aesthetic preferences by also affecting the user’s emotions and behavior. Before launching into the color selection, the design process entails certain decision making, such as which architectural elements to highlight, if there is a zonification or division of spaces within the use of colors, the creation of focal points, and the consideration of how each color is associated with a determined mood.
With a breakdown of five architecture projects, the following article analyzes how color is applied as a design strategy to define spaces through three categories: structure, elements and objects, and definition of spaces.
'Color in certain places has the great value of making the outlines and structural planes seem more energetic' - Antoni Gaudí
St. Marks Square (Piazza San Marco) during flood (acqua alta). Image via Shutterstock | Ihor Serdyukov
The Italian city installed glass barriers around the 900-year-old church to keep the waters out. The decision was made after near-record flooding in December 2022, preventing a repeat of the November 2019 near-catastrophe that aged parts of the building “20 years in a day,” according to Basilica’s Procuratoria governing body. The temporary structure is fixed until the MOSE system fully works by the end of 2025, protecting the city of Venice, Italy, and the Venetian Lagoon from flooding.
A mud mosque in Mali, West Africa. Image Courtesy of Emilio Labrador
Earth architecture is built on a far-reaching history. Its story continues to be told through aged structures that have stood the test of time. Across the world, indigenous earth construction techniques have been pioneered by many ancient civilizations. Communities originally built shelters from earth - the most readily available material to them - and have passed on their construction techniques through generations. Earth architecture evolved with a careful understanding of land and location. With practices perfected decades ago, it is fascinating to see earth architecture remaining resilient through adversities
German-based architecture firm OMT designed Africa's tallest hybrid timber tower in Zanzibar City, Tanzania. In partnership with Birk Heilmeyer Frenzel Architects, engineering firm Knippers Helbig Advanced Engineers, and CPS Developers, the "Burj Zanzibar" will rise 96 meters tall to accommodate 266 residences and recreational and conferencing facilities. The mixed-use tower will promote the locally available wood and support the growing urban infrastructure that, according to the government plans, expects to attract tech companies to turn the island into a leading hub for Africa's technology companies.
Interior view to the Lobby . Image Courtesy of UNStudio
Incorporating the Environmental, social, and corporate governance objectives, the 45,000 m2 Office Tower in the Europaviertel in Frankfurt aims to be one of Germany's most sustainable office buildings. Designed by UNStudio in partnership with Groß & Partner in collaboration with OKRA landscape architects, the project focuses on environmental and social sustainability as an integral part of Frankfurt's green network. The ecological agenda includes a low-carbon load-bearing structure and recyclable construction materials. The architecture program offers a public urban space to add value to its surroundings to encourage communication and gathering.
BUGA Pavilhão de Fibra / ICD/ITKE Universidade de Stuttgart. Image Cortesia de ICD/ITKE University of Stuttgart
Let us return to the first architecture class on structures and the classification of structural efforts. In most structures, whether natural or man-made, compression forces are the primary actors. These are efforts undertaken with equal and opposing loads, applied in the interior of the structure, which tend towards the shortening of the piece in one direction - or compressing it, as the name indicates. It is not difficult to find examples of this: for example, a stone wall or a wooden log can resist the weight of a covering through internal compression efforts that are inherent to each material. Tension efforts, on the other hand, tend to lengthen components in the direction of the applied force of action. Steel, for example, is a material with good tensile strength. It is used in reinforced concrete precisely in the parts where the piece is in traction. But it is also possible for a structure to only have tensile parts, as is the case of membrane, tensioned, or tension structures, which consist of surfaces pulled by the action of cables or ropes in which the masts absorb compression efforts.
One of the first elements used by humans to build shelters, wood is a versatile material that, along with technological advances, remains a protagonist in the construction industry, being used in different ways and moments in a work.
