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Mudbrick

A mudbrick is a rectangular building block made from a mixture of clay-rich soil, water, and often organic materials such as straw or animal dung for reinforcement, which is molded into shape and allowed to dry in the sun without firing. This ancient construction material, also known as , has been utilized for due to its availability, low cost, and suitability for load-bearing walls in arid climates. Mudbricks trace their origins to prehistoric times, with evidence of their use in early settlements like around 8000 BCE, where they formed simple dwellings, and in by the fourth millennium BCE for more complex structures such as ziggurats and city walls. In , mudbricks became the primary material for houses, palaces, temples, and tombs from the predynastic period onward, crafted from silt mixed with straw and sun-dried in wooden molds measuring approximately 34x18x10 cm. Their widespread adoption across civilizations, including the Indus Valley, , and the , stemmed from the abundance of earth resources and the material's properties, which provide natural against heat. Today, mudbricks continue to be employed in , particularly in regions like the , , and , where they require minimal energy for production compared to fired bricks or . The construction process involves selecting soil with 30–70% clay content, mixing it with to achieve a workable , incorporating stabilizers like (typically 5–10% by volume) to prevent cracking, and pressing the mixture into molds before sun-drying for 6–9 days. Walls are then built using mud mortar, often with thicknesses of 240–300 mm for stability, and may include reinforcements like wooden beams or reeds in seismic areas. While mudbricks offer advantages such as fire resistance, pest deterrence, and excellent sound insulation, they are vulnerable to from and require protective coatings or overhangs in wetter climates. Modern stabilized variants, incorporating or , enhance durability for contemporary applications.

Definition and Materials

Composition and Ingredients

Mudbricks are primarily composed of a mixture of , with clay-rich serving as the foundational component to provide . Suitable soils typically contain 30-70% clay by weight, balanced with and to achieve optimal workability and strength, as lower clay contents may result in poor while excessive amounts can lead to excessive shrinkage. To enhance and prevent cracking during drying, organic binders such as , grass fibers, or animal dung are commonly incorporated into the mixture. These materials act as tensile reinforcements, with typical addition rates ranging from 5-10% by volume depending on soil type; for instance, dung is often used at 10-20% in traditional formulations to improve and resistance. Additives like or are frequently included to improve and load-bearing capacity, comprising up to 50-70% of the volume in sandy loam soils to reduce and enhance . In modern stabilized mudbricks, chemical binders such as or are added at 5-10% by weight to increase resistance to and , particularly in regions prone to heavy rainfall. Regional variations reflect local resources; for example, rice husks serve as a lightweight binder in parts of , while functions as a pozzolanic in certain African traditions to boost . Prior to production, suitability is assessed through testing methods like the test, where a soil-water suspension is allowed to settle to measure the proportions of clay, , and layers, ensuring the mixture meets requirements of at least 15-25% fines content. This preparation step confirms the earth's viability, avoiding unsuitable aggregates that could weaken the final product.

Production Process

The production of mudbricks begins with the mixing stage, where suitable —typically clay-rich earth—is combined with and organic binders such as to achieve a workable consistency that can be molded without excessive crumbling or stickiness. The is prepared by first pulverizing and sieving the soil to remove , then gradually adding to reach an optimum content of around 20%, often kneaded by foot or hand in a until it forms a cohesive ball when squeezed. In traditional settings, this process incorporates brief references to as a to enhance tensile strength during handling, though detailed composition is handled separately. Forming the bricks follows mixing, primarily through hand-molding techniques using simple wooden frames or molds to shape the mud into rectangular prisms. In ancient , for instance, molds produced standardized sizes such as approximately 22 cm long by 11 cm wide by 8 cm high during the , allowing for efficient stacking in walls. The wet mixture is pressed into the mold, compacted firmly by hand or with a tamper to eliminate air pockets, smoothed on the top surface, and then carefully removed onto a flat ground or drying bed. Modern production may employ mechanical presses or extrusion machines for stabilized mudbricks, enabling higher volumes and uniformity in larger-scale operations. Drying is a critical to prevent warping or cracking, typically achieved through sun-drying in controlled environmental conditions over 7-14 days. Bricks are arranged in single layers on flat surfaces, initially shaded or covered with straw mats to regulate and avoid rapid surface that could cause fissures, then gradually exposed to direct as they harden. In ancient Egyptian practices, this natural air- process was conducted off-site near construction areas, with bricks stacked in low piles to facilitate even . The duration varies by , but optimal results occur in dry, warm seasons to ensure structural integrity before transport. Quality control ensures the bricks meet basic standards for uniformity and performance, involving visual inspections for consistent shape, color, and absence of cracks, alongside simple tests like dropping a brick from height without shattering. is assessed through manual or basic , with traditional mudbricks typically achieving 1-3 , sufficient for load-bearing in low-rise structures. Defective bricks, such as those with substantial fractures from uneven drying, are discarded or repurposed as fill. Production scale ranges from small-batch traditional methods, where communities hand-produce hundreds of bricks daily for local building, to using for thousands of stabilized units per hour in contemporary earthen projects. In historical contexts like the Middle Bronze Age , evidence of standardization in brick size and tempering suggests organized labor for larger projects. Modern adaptations incorporate machinery to enhance efficiency while maintaining the core sun-drying principle for .

Historical Development

Ancient Origins

The earliest known use of mudbricks dates to the period in the , with archaeological evidence from the site of in the revealing mudbrick structures around 9000 BCE. These included circular dwellings and protective walls constructed from sun-dried mudbricks made from local clay-soil mixtures, marking one of the first instances of permanent in . Excavations at Jericho's levels have uncovered remains of these mudbrick homes topped with domed roofs, demonstrating early experimentation with molded bricks for communal settlements. In , the site of provides further evidence of mudbrick construction from approximately 7500 BCE during the era. Inhabitants built densely packed, multi-story houses entirely from mudbricks, often accessed via rooftops, forming a honeycomb-like urban layout without streets. These structures, made from local earth and water, highlight mudbricks' role in supporting large-scale, sedentary communities in the region's fertile plains. By around 4000 BCE, mudbrick production became standardized in during the , where bricks were molded to uniform sizes for monumental . This innovation facilitated the construction of ziggurats, such as the Great around 2100 BCE, primarily built from layers of mudbricks cased in baked bricks for durability. These stepped temples, dedicated to deities like the moon god , exemplified mudbricks' scalability in religious and civic buildings amid the Tigris-Euphrates floodplains. In the Nile Valley, mudbricks were widely employed from about 2700 BCE for both monumental and everyday structures, including the cores of early pyramids and housing for laborers. For instance, worker settlements near pyramid sites like featured modular mudbrick houses arranged in organized grids, supporting the workforce during . The addition of to the clay mixture, as referenced in ancient accounts, improved tensile strength and prevented cracking during drying, a practice integral to construction. Further east, the Indus Valley Civilization utilized both fired and unfired mudbricks around 2500 BCE at sites like , where they formed the bulk of urban infrastructure, including sophisticated drainage systems with brick-lined channels. These standardized bricks, often measuring about 28 x 14 x 7 cm, enabled the city's grid layout and covered drains, reflecting advanced in a riverine environment prone to monsoons. Mudbrick use spread to other regions, appearing in ancient China during the Neolithic around 5000 BCE, where early forms of molded earth bricks supported semi-subterranean houses in the basin.

Evolution Through Eras

In the medieval , mudbrick construction saw widespread adoption in (modern-day ) from the 9th to 13th centuries, particularly for utilitarian and monumental structures suited to arid environments. Mud, often mixed with straw or other stabilizers, served as the primary material for walls and vaults in mosques and qanats— aqueducts essential for in regions. For instance, qanats featured mudbrick linings to prevent collapse and facilitate flow, exemplifying adaptive that supported growth in areas like and . Mosques from this era, such as early iterations of the Great Mosque of (dating to the under Seljuk patronage), utilized mudbrick cores overlaid with decorative plastering to create intricate geometric and calligraphic designs, enhancing both structural integrity and aesthetic appeal in a resource-scarce . During the European (c. 1000–1500 CE), mudbrick manifested primarily as daub in wattle-and-daub techniques, prevalent in rural and where timber was abundant but stone scarce. This method involved weaving a of wooden stakes and branches (wattles) and coating it with a mixture of mud, clay, and organic binders like or animal dung to form walls for homes and farm buildings. In rural and , such constructions formed the for timber-framed hall houses, providing affordable, insulating enclosures that withstood moderate climates when regularly maintained against . Archaeological evidence from sites like in reveals these structures' ubiquity in village settings, underscoring mud-based building's role in sustaining agrarian communities amid feudal economies. In the African Sahel region, mudbrick architecture expanded significantly during the (c. 1200–1600 CE), symbolizing the realm's wealth and Islamic scholarship. The Djingareyber Mosque in , commissioned in 1327 by Emperor and completed by architect Abu Ishaq al-Sahili, exemplifies this era's monumental earthen works, constructed from sun-dried mudbricks (banco) reinforced with wooden beams and palm wood scaffolding for stability. Spanning over 5,000 square meters with a towering , the mosque integrated local Sahelian styles—such as projecting wooden beams for annual replastering—with North African influences, serving as a center for learning and prayer that drew scholars across the . Its enduring form highlights mudbrick's suitability for the region's intense heat and infrequent rains, with recognizing it as a pinnacle of 14th-century . Colonial influences in the marked a transatlantic diffusion of mudbrick techniques, as settlers introduced formalized production to the , blending it with indigenous methods. Upon arrival in regions like (modern and Southwest U.S.), Spaniards adapted their Iberian traditions—molding sun-dried bricks from clay, sand, and straw—to local soils, using iron tools for efficiency and constructing missions and presidios. This merged with pre-existing Native American practices, such as the ' multi-story pueblos in the Valley, resulting in hybrid structures like the San Esteban Rey Mission in (built c. 1629–1630s), where plans incorporated indigenous labor and materials for thermal regulation in arid zones. Such fusions facilitated rapid settlement while respecting environmental constraints, spreading across colonial frontiers from to . By the post-18th century, mudbrick use declined in industrialized regions of Europe and due to and technological shifts favoring fired bricks. The Industrial Revolution's demand for scalable, weather-resistant materials—accelerated by events like London's Great Fire of 1666 and subsequent building codes mandating non-combustible construction—promoted kiln-fired bricks, which offered superior durability against urban pollution and crowding. Mechanized production, including extrusion presses by the mid-19th century, made fired bricks cheaper and more uniform, supplanting labor-intensive sun-dried methods in growing cities like and . However, mudbrick persisted in arid climates of the , , and parts of the , where its low cost and thermal properties remained advantageous for rural and vernacular building, as seen in ongoing Yemeni and Moroccan traditions.

Variations and Types

Adobe Bricks

Adobe bricks are sun-dried blocks formed from a mixture of clay-rich , water, and organic stabilizers like straw or grass, without any firing process, distinguishing them from fired mudbricks. These blocks are typically larger than standard fired bricks to facilitate manual handling and drying, with common dimensions in the Southwest measuring 10 by 14 by 4 inches. This size standard, prevalent in regions like New Mexico's [Rio Grande](/page/Rio Grande) Valley, allows for efficient and stacking while accommodating local soil compositions. A key characteristic of adobe bricks is their high , which enables them to absorb solar during the day and release it slowly at night, promoting and temperature regulation in arid climates. With a ranging from 0.17 to 0.47 W/mK, adobe acts as a natural , maintaining interior comfort without mechanical systems. However, their low tensile strength and susceptibility to necessitate thick walls for , typically 12 to 24 inches in historical and modern applications, often requiring buttresses in taller structures. Adobe bricks gained regional prominence in across the , particularly in Pueblo-style buildings in starting from the , following the Spanish arrival in 1598. This style integrated techniques with earthen traditions, resulting in multi-story structures like those at Pecos Pueblo, where formed durable, earth-toned facades suited to the desert environment. In , the bricks are laid in a running bond pattern and stacked with mud mortar composed of similar soil to minimize differential shrinkage, ensuring long-term cohesion. Walls are commonly finished with , which provides a breathable protective layer against and UV degradation while preserving the material's permeability. Contemporary standards for adobe construction emphasize durability in seismic zones, as outlined in the International (IBC Section 2109), which requires units to achieve a minimum average of 300 when tested per ASTM C67. In high-seismic areas, such as parts of , additional measures like continuous bond beams and collar joints are mandated to enhance resistance to lateral forces. For finishing, ASTM C926 governs the application of portland cement-based plasters on surfaces, ensuring compatibility and weather resistance in engineered builds. These guidelines support adobe's revival in sustainable housing while addressing vulnerabilities observed in traditional forms.

Banco and Similar Methods

Banco is a traditional earth-building technique involving the hand-forming and sculpting of moist clayish earth into continuous walls, without the use of discrete bricks, prevalent in West African Sahelian architecture. This method creates seamless mud structures that integrate organically with the landscape, as seen in the cliffside villages of the Dogon people in Mali, where banco walls form compact, terraced compounds adapted to rugged escarpments. The technique emphasizes direct manipulation of wet earth to achieve fluid, sculpted forms, distinguishing it from molded brick systems by allowing for more expressive, non-rectilinear designs. The construction process employs a layer-by-layer application of kneaded, moistened , typically starting with a wide base that tapers upward for stability. Each layer, approximately 25 cm high and up to 45 cm thick at the base, is thrown and shaped using tools like hoes, then compressed to ensure before ; subsequent layers are added only after partial curing to prevent slumping. Wooden forms or guides may be used to define curves and openings, enabling the creation of rounded walls or decorative elements such as protruding buttresses in structures like Djenné's historic buildings. This iterative building allows for on-site adjustments, resulting in seamless walls that facilitate organic shapes and can be faster than laying individual bricks in resource-limited settings, as the material is sourced and applied locally without extensive pre-forming. Similar to banco, —or pisé—involves compacting moist soil within temporary forms to create solid walls, a method that shares the emphasis on layered earth but uses mechanical tamping rather than hand-sculpting. In Yemen's , a 16th-century walled city, sun-dried mud brick techniques produced multi-story mud towers up to seven levels high, demonstrating vertical load-bearing capacity in arid environments. Banco's advantages lie in its adaptability for curved, sculptural forms without visible joints, promoting and aesthetic integration in communal . Historically, banco emerged in Sahelian architecture around the , as evidenced by early mud structures at sites like Oursi Hu-Beero in (c. 1020–1070 CE), featuring rectangular earth walls that laid the foundation for later elaborations. This period marked the transition to more complex earthen forms in the region, including conical granaries in and adjacent , which use banco walls elevated on stone bases to store grains while resisting pests and moisture. These examples highlight banco's role in sustainable, community-driven building across the .

Physical Properties

Durability Factors

Mudbricks exhibit low tensile strength, typically ranging from 0.1 to 0.5 , which contributes to their under lateral loads. This inherent weakness, combined with poor resistance to forces, makes them particularly susceptible to seismic , where even moderate earthquakes can cause extensive cracking and due to the material's inability to flex without fracturing. Additionally, mudbricks are highly vulnerable to , as exposure to moisture leads to rapid dissolution of the earthen matrix, accelerating structural degradation. Environmental conditions significantly affect mudbrick , with performance varying markedly between arid and humid climates. In arid regions, where rainfall is minimal, unprotected mudbrick structures can endure for centuries with periodic , benefiting from low levels that preserve structural integrity. Conversely, in humid environments, mudbricks degrade significantly faster without protective measures, as persistent promotes and weakening of the material. Standard testing metrics evaluate mudbrick durability, including assessed via ASTM C67 procedures, which measure load-bearing capacity under axial compression, often yielding values between 0.5 and 7 for unstabilized specimens. Water absorption rates, determined by immersing samples and calculating weight gain, can reach up to 30% by weight in unstabilized mudbricks, indicating high and potential for ingress. Common failure modes in mudbricks include cracking due to shrinkage during , which results in 5-10% volume loss as water evaporates from the soil mixture, leading to tensile stresses that form fissures. damage is another prevalent issue, particularly when organic binders like are used, as and borers can infest and degrade these reinforcements, compromising overall cohesion. Mudbricks also offer excellent fire resistance and sound insulation due to their dense, inorganic . Basic enhancements, such as adding 5% cement by weight as a stabilizer, can significantly improve durability by increasing compressive strength (e.g., by 50-100% depending on the soil mix).

Environmental Performance

Mudbricks exhibit high thermal mass due to their dense composition, primarily from and stabilizers, which enables effective heat absorption and release. This property, characterized by a specific heat capacity of approximately 1.0-1.3 kJ/kg·K, allows mudbrick walls to moderate indoor temperatures by storing daytime heat and radiating it at night, promoting natural in passive building designs. In regions with diurnal temperature swings, such as hot-dry climates, this thermal regulation can reduce heating and cooling energy demands by up to 50% compared to conventional materials when integrated with proper and . From a lifecycle , mudbricks demonstrate superior environmental performance through low , typically ranging from 0.7 / for sun-dried production, in contrast to 2.5-3.0 / for fired clay bricks. This minimal energy input arises from the reliance on solar drying and locally sourced materials, rendering mudbricks fully biodegradable at the end of their service life and facilitating easy reintegration into the without long-term waste accumulation. Traditional production methods further contribute to very low life cycle emissions (near zero for variants without chemical additives), far below the emissions associated with fired bricks. Additionally, the -based nature of mudbrick fabrication supports potential , as microbial activity in the soil matrix can stabilize organic carbon during material preparation and . Mudbricks' inherent permeability enhances , allowing moisture vapor to pass through and regulate indoor , but this also necessitates protective measures in wet climates to mitigate . Without overhangs, sealants, or stabilizers, exposure to prolonged rainfall can lead to significant surface , potentially reducing structural by 20-30% annually in humid environments. For optimal performance, mudbricks are particularly suited to hot-dry regions, where their low thermal conductivity—averaging 0.5-1.0 W/(m·K)—yields an R-value equivalent of about 0.25-0.4 per inch of thickness, aiding in while minimizing heat gain.

Architectural and Cultural Role

Global Architectural Examples

In the , in exemplifies vertical mudbrick architecture, known as the "Manhattan of the Desert" for its dense cluster of tower houses rising up to seven stories and approximately 100 feet in height, constructed primarily from sun-dried mud bricks in the to adapt to limited land in the Wadi Hadramaut valley. These structures feature thick walls that taper inward for stability, with wooden beams projecting outward to support during annual maintenance plastering, demonstrating innovative use of local earthen materials in a harsh desert environment. In , the in stands as the largest mudbrick building in the world, rebuilt in 1907 using sun-dried adobe bricks and banco techniques for its towering minarets and expansive courtyard, originally dating to the 13th century. The mosque's maintenance involves the annual crepissage festival, where community members apply a fresh layer of plaster to protect the structure from , highlighting collective architectural preservation practices. In the Americas, in represents enduring multi-story complexes, with continuous habitation since around 1000 CE in reddish-brown mudbrick dwellings stacked up to five or six stories along the Rio Pueblo de Taos. These structures incorporate thick earthen walls for thermal regulation and wood ladders for access between levels, forming a self-contained village that integrates residential and ceremonial spaces without modern utilities. In , sections of the , particularly in arid western regions like Jiayuguan, utilize —a compacted technique akin to mudbrick—for expansive defensive barriers up to several meters thick, layered and pounded for durability against invasions. In , cob cottages in illustrate low-rise from the 17th to 19th centuries, with walls formed from a mixture of clay, sand, straw, and water hand-tamped between wooden , often topped with thatched roofs to shed rainwater and protect the earthen structure. These single- or two-story homes feature lime-rendered exteriors and deep , adapting local soils for insulated, housing in rural settings.

Cultural and Symbolic Significance

In ancient Egyptian culture, mudbrick held profound ritual significance, particularly in funerary contexts where it symbolized the eternal earth and the cycle of rebirth. Mud, derived from the Nile's fertile silt, was viewed as the primordial substance of creation, embodying the origin of life and the eternal mound from which the world emerged, as described in the . This symbolism extended to tombs, where magical mudbricks were placed in niches during the New Kingdom to invoke protection and facilitate the deceased's rebirth, aligning with rituals like the "Opening of the Mouth" that paralleled birth ceremonies. Personified as the goddess Meskhenet, mudbrick represented fate and the life-giving properties of the earth, connecting the mortal realm to cosmic eternity. Among the of , mud-based construction, known as banco, is intertwined with and ancestral veneration, serving as a material bridge between the physical world and the spirits of forebears. The , amphibious ancestral beings central to Dogon mythology, are believed to influence architectural forms, with mud walls and structures embodying the harmony between earthly existence and the spiritual domain of gods and ancestors. This connection underscores banco's role in rituals that honor the dead, where the earth's reinforces communal ties to the and the eternal presence of lineage spirits. Socially, mudbrick construction fosters community rituals that strengthen interpersonal bonds, as seen in Mali's annual crepissage practice in , where residents collectively replaster mud structures like the Great Mosque. This event transforms maintenance into a festive gathering, with participants from all walks of life contributing labor, music, and shared meals to reaffirm social cohesion and before the rainy season. By involving elders, , and families, crepissage not only preserves buildings but also reinforces cultural continuity and mutual support within the community. Economically, mudbrick's low cost and local availability enabled widespread urban development in ancient civilizations, serving as the primary material for housing and infrastructure in Mesopotamian cities. Formed from abundant clay, , and without needing kilns, it allowed for rapid, affordable construction of homes, temples, and ziggurats, supporting population growth in riverine settlements like those of . This accessibility democratized building, facilitating the erection of thousands of structures that formed the backbone of early urban economies. Symbolically, mudbrick often evoked earth's fertility in Mesoamerican traditions, where adobe pyramids represented the nurturing soil and agricultural abundance vital to societies like the Moche. Structures such as Peru's , built from over 143 million sun-dried mudbricks, embodied the life-giving essence of the land, linking human endeavors to deities of rain and harvest in rituals that celebrated renewal. In Buddhist contexts, mud stupas in earthen regions further symbolized impermanence, their transient material mirroring the Buddhist doctrine of anicca, where all forms dissolve back to the , reminding practitioners of the fleeting of existence. Preservation efforts highlight mudbrick's enduring cultural value, exemplified by UNESCO's recognition of Yemen's as a in 1982 for its pioneering vertical mudbrick architecture, which illustrates adaptive in arid environments. In 2008, UNESCO conducted a mission following devastating floods that damaged the site's mud towers, emphasizing the need for ongoing protection to safeguard this testament to Hadrami heritage and trade history. As of 2025, the site remains on UNESCO's List of World Heritage in Danger due to ongoing conflict and environmental risks, with recent initiatives including a project to support conservation. These initiatives underscore mudbrick's role as a living emblem of cultural identity, prompting global collaboration to mitigate environmental threats while honoring its symbolic depth.

Contemporary Uses

Modern Construction Applications

In contemporary construction, stabilized mudbricks have gained prominence through the addition of or to enhance and durability, enabling their use in seismic-prone areas. For instance, incorporating 5-6% by weight can achieve compressive strengths of 3.5-7 , making the blocks suitable for load-bearing walls. In post-2001 Gujarat earthquake reconstruction efforts in , -stabilized mud blocks were employed to rebuild , providing improved resistance to and earthquakes while adhering to local building standards. Similarly, lime stabilization can increase strength significantly, with nearly 80% improvement observed from 0% to 14% lime content, as shown in studies on mud bricks, facilitating their application in modern engineering projects where traditional earthen materials are adapted for higher performance. Hybrid systems combining mudbricks with reinforcement represent another key adaptation for 20th- and 21st-century . In , modern homes integrate ladder reinforcement or rods within walls to meet International Building Code (IBC) requirements for seismic and structural integrity, allowing for multi-story constructions that were previously limited. These reinforcements are embedded during , securing adobe units to foundations and enhancing overall stability without compromising the material's benefits. Such hybrids have enabled the production of millions of stabilized adobe bricks annually in the region, supporting residential and commercial developments. Urban applications of mudbricks focus on low-income housing in developing countries, where compressed stabilized earth blocks (CSEBs) offer scalable solutions for community-scale projects. In , , since the late , earth-dome structures built with CSEBs have been used for affordable residences and public facilities, demonstrating free-spanning vaulted designs that reduce material needs while providing durable shelter. These initiatives have trained local builders in CSEB production, promoting self-construction for low-cost urban expansion. In , post-2015 conflict restoration projects by organizations like the Daw'an Mud Brick Architecture Foundation have revived historic mudbrick structures in Hadramaut, incorporating stabilized earthen techniques to reconstruct cultural sites and housing amid war damage, fostering community recovery. Cost benefits drive the adoption of mudbricks in labor-intensive regions, where they can be 50-70% cheaper than alternatives due to locally sourced materials and simplified . In Kenyan low-cost , CSEB walls achieve savings of 20-70% over blocks, factoring in on-site that minimizes costs. These economic advantages make mudbricks viable for large-scale in developing economies, balancing affordability with structural reliability.

Sustainability and Revival

Mudbrick construction has gained renewed attention in movements due to its alignment with the , which promotes sustainable cities and human settlements through resilient, low-impact materials that reduce urban environmental footprints. This resurgence is propelled by the material's minimal carbon emissions during —often near zero for unfired variants—contrasting sharply with , which accounts for approximately 8% of global anthropogenic CO₂ emissions. By leveraging locally sourced earth, mudbrick supports eco-movements aimed at slashing the construction industry's contribution to , particularly in resource-constrained areas where it minimizes transport-related emissions. Key revival projects highlight this trend. The Biotecture community in , pioneered in the 1970s by architect Michael Reynolds and expanded through the 2020s, integrates mud-based walls with off-grid systems to create self-sufficient hybrid structures that recycle water and generate energy on-site. The Nubian Vault program has constructed thousands of low-carbon homes since around 2000, using traditional mud techniques to provide durable, resilient to and extreme heat in Africa's . These initiatives demonstrate mudbrick's role in addressing housing shortages while advancing environmental advocacy, often in partnership with international development efforts. In 2025, projects like the Bayt Isa restoration in continued to employ mudbrick for heritage preservation, integrating traditional techniques with modern sustainability goals. Innovations are further driving adoption. The TECLA house in , completed in 2021, represents a in 3D-printed structures, utilizing locally sourced clay to fabricate curved walls with two large-format printers, reducing material waste and construction time to under 200 hours. Additionally, bio-based stabilizers such as —fungal networks grown on —enhance mudbrick strength and water resistance, enabling production of lightweight, biodegradable composites suitable for modern applications. Despite these advances, challenges persist, particularly in wet climates where mudbrick's vulnerability to erosion requires protective measures like lime renders or elevated foundations, limiting widespread use without adaptations. Policy barriers, including restrictive building codes in humid regions that favor conventional materials, also hinder integration, though earthen options increasingly qualify for sustainability certifications such as LEED's Materials and Resources credits for their low embodied energy and regional sourcing. As of 2025, mudbrick adoption has accelerated following the IPCC's 2022 report on impacts, , and , which underscores the need for low-carbon building strategies to mitigate urban heat and resource strain in vulnerable regions. Market projections indicate steady growth for sustainable brick materials in developing countries, with the global bricks sector expected to expand at a of around 3-4% through 2033, fueled by demand for eco-friendly alternatives in hotspots. This outlook positions mudbrick as a cornerstone of future green architecture, balancing tradition with innovation for resilient communities.

References

  1. [1]
    Mud brick - | YourHome
    Key points. Mud bricks are one of the oldest building materials in the world. Mud bricks usually only require earth and the energy of the sun, ...Missing: history | Show results with:history
  2. [2]
    [PDF] Earthen Architecture Teaching Guidelines - Getty Museum
    The origins of mud-brick construction in early civilizations: Jericho-Munata b. Mesopotamia: Babylon c. The influence of Mesopotamian earthen construction ...
  3. [3]
    Mud-Brick Construction in Ancient Egypt | Middle East And North Africa
    Unfired brick, made from mud, river, or desert clay, was used as the primary building material for houses throughout Egyptian history.Missing: definition | Show results with:definition
  4. [4]
    The 3000 Year Old History of an Arabian Mud Brick Technology
    The layered mud brick construction technique spans 3000 years, evident from Iraq to Zanzibar. Each layer of the system measures approximately 40 cm, optimizing ...
  5. [5]
    MODIFIED MUD BRICKS FOR STRENGTHENING HISTORIC ...
    Mud bricks consist of clay and, sand, reinforced with plant fibers such as rice husks or straw. Mud bricks in most heritage buildings made of earth have ...Missing: definition | Show results with:definition
  6. [6]
    Mud and burnt Roman bricks from Romula | Scientific Reports - Nature
    Sep 23, 2022 · In general, they should fulfill two conditions: (1)—the amount of clay is minimum ~ 20 wt.% (sometimes even lower for mudbricks, down to 6–10 wt ...<|control11|><|separator|>
  7. [7]
    Experimental investigation on mud bricks reinforced with natural ...
    Jul 1, 2017 · To make mud bricks of clay, sand and gravel were used to be same as available materials for brick construction. Aggregate (sand – gravel) played ...
  8. [8]
    The use of Cement, Lime and Cow-Dung in Adobe Air-Dried Bricks ...
    Aug 20, 2021 · The cement and lime percentage used for stabilization of adobe air dried bricks are 10% and 15%, while cow-dung with 17% and 20% respectively.
  9. [9]
    Mechanical Properties of Adobe Stabilized With Cow-Dung and ...
    Adobe stabilized with Cow-dung & 4% Gamba-straw (mix ratio; of 6:90) (6% Cow-dung) records the highest compressive strength of 1.75N/mm 2 at 28days compared ...
  10. [10]
    Appropriate Mixes for Adobe - Green Home Building
    I find that 8 to 16 liquid ounces is about right to stabilize a cubic foot of my soil's adobe mud. That is about 1/2 to 1% by weight. It is not fully stabilized ...
  11. [11]
    Assessment of mechanical properties and durability of compressed ...
    Jan 14, 2025 · This research aim was to enhance the mechanical properties and durability of compressed mud bricks through a partial replacement technique
  12. [12]
    A Journey to the West: The Ancient Dispersal of Rice Out of East Asia
    Sep 25, 2021 · ... rice may have originally been an elite commodity in West Asia. Impressions of rice husks in mudbricks were reported at sites in the South ...Missing: traditional | Show results with:traditional
  13. [13]
    [PDF] A FIELD INVESTIGATION OF COMPOSITE MUD BRICK ...
    high silt/clay content. If the soil stays coarse, then it is primarily sand ... Natural elements such as rain change the physical composition of the mud brick.
  14. [14]
    None
    ### Mudbrick Production Methods in Ancient Egypt
  15. [15]
    [PDF] Pages 73-96 - The Appearance of Bricks in Ancient Mesopotamia By ...
    Compressive strength is strongly influenced by the characteristics of the raw material and by the production process. It is known that the raw clay of old brick ...
  16. [16]
    [PDF] 6th International Conference on Earthen Architecture - Getty Museum
    Board recommends "a raft-mum compressive strength of 1 .08 - 1.30 N/mm2 ("10 to. 12 tons per sq ft")". 18. Tests carried out at Norwich city College of.<|control11|><|separator|>
  17. [17]
    Mud Bricks and the Process of Construction in the Middle Bronze ...
    This study investigates patterns in the process of construction during a period of ur- banization early in the Middle Bronze Age of the southern Levant.
  18. [18]
    Early Jericho - World History Encyclopedia
    Sep 19, 2016 · Excavations have revealed that Jericho is one of the earliest settlements dating back to 9000 BCE. It also has the oldest known protective wall in the world.
  19. [19]
    Jericho - Smarthistory
    Specifically, in the Pre-Pottery Neolithic A levels at Jericho, archaeologists found remains of a very large settlement of circular homes made with mud brick ...
  20. [20]
    Ҫatalhöyük - World History Encyclopedia
    Dec 17, 2021 · 8500-7500 BCE), Aşikli Höyük (c. 8200-7400 BCE), and Çatalhöyük (c. ... Room-flats completely made of mudbricks with painted and decorated walls.
  21. [21]
    Ziggurat of Ur - Smarthistory
    One of the largest and best-preserved ziggurats of Mesopotamia is the Great Ziggurat at Ur. ... 2100 B.C.E. mudbrick and baked brick, Tell el-Mukayyar, Iraq.
  22. [22]
    [PDF] Giza Field SeaSon - Institute for the Study of Ancient Cultures
    Selim Hassan excavated the KKT in 1932 and found an L-shaped mudbrick settlement with modular houses arrayed 150 m (492 feet) east–west along a causeway leading ...Missing: BCE | Show results with:BCE
  23. [23]
    How to Make a Mudbrick - Biblical Archaeology Society
    Jan 19, 2025 · When Pharoah stopped giving the Israelite slaves straw for their bricks, it was still necessary for them to gather it on their own (Exodus 5:6–8 ...
  24. [24]
    Ancient Chinese Architecture - World History Encyclopedia
    Oct 24, 2017 · House remains excavated at Neolithic Yangshao period sites (5000-3000 BCE) indicate houses were built with a subterranean level. Houses at ...
  25. [25]
    Bricks in Ancient China and the Question of Early Cross-Asian ... - jstor
    Apr 21, 2018 · At the moment there is little to suggest that mud-bricks or fired ceramics played any significant rôle in architecture. East Asian builders ...
  26. [26]
    https://www.tappersia.com/blog/iranian-architecture-history/
  27. [27]
    Iranian Architecture History | TAPPersia
    Rating 5.0 (2) Dec 31, 2022 · In Central Asia, mudbrick domes from as far back as the third millennium BC have been discovered. Buildings with unfired brick domes have been ...
  28. [28]
    Wattle and daub | Building Technique, House, History, & Architecture
    Oct 15, 2025 · Method of constructing walls in which vertical wooden stakes (wattles) are woven with horizontal twigs and branches, and then covered with clay, mud, or other ...Missing: France 1000-1500
  29. [29]
    Timbuktu - UNESCO World Heritage Centre
    Built in the 14th century, the Sankore Mosque was, like the Djingareyber Mosque, restored by the Imam Al Aqib between 1578 and 1582. He had the sanctuary ...Missing: mudbrick | Show results with:mudbrick
  30. [30]
    Djingereyber Mosque Restoration Timbuktu, Mali - Archnet
    Load-bearing elements are generally in mud brick with wooden tie-beams laid at intervals at the courses. Reinforcing layers of alhore stone have been added at ...
  31. [31]
    The History and Significance of Adobe Construction in Texas
    Feb 25, 2021 · In early Spanish Texas adobe bricks, fashioned by Spanish and American Indian workers, were used to build a variety of structures, including ...Missing: colonial mudbrick 16th indigenous
  32. [32]
    Mud Brick Wonder - Authentic Texas
    The building method of erecting structures using sun-dried mud to practiced a similar style of using brick made from dry mud as a building material as far back ...Missing: definition | Show results with:definition
  33. [33]
    Bricks and the Industrial Revolution - Construction Physics
    Sep 17, 2021 · Bricks (like so much else during the industrial revolution) gradually changed from hand-made, crafted items to mass-produced, factory-made objects.
  34. [34]
    The earliest adobe monumental architecture in the Americas - PNAS
    Nov 15, 2021 · Klimscha, 7,200 years old constructions and mudbrick technology: The evidence from Tel Tsaf, Jordan Valley, Israel. ... Volcanic ash ...
  35. [35]
    Adobe and Product Prices
    PRICES & SIZES. The standard size of adobes in the Rio Grande Valley is 4x10x14. In addition to the standard size, we make a veneer adobe that is 4x5x14.
  36. [36]
    [PDF] Adobe as a building material
    Introduction. Adobes are dried mud or unburned bricks that have been used for thousands of years in the construction of dwellings and bther structures. Even ...
  37. [37]
    [PDF] THERMAL PROPERTIES OF AN ADOBE BRICK WALL - OCERINT
    Jun 26, 2019 · Adobe has a thermal conductivity of 0.17 to 0.47 W/mK, acts as a heat reservoir, and transfers heat to the interior for hours after sunset.
  38. [38]
    Structural Concerns with Adobe - Green Home Building
    Minimum wall thickness is 10-inches for single story construction. Two-story construction may be done with 14-inch walls below and 10-inch walls on the second ...
  39. [39]
    [PDF] THE SPANISH COLONIAL ARCHITECTURE OF PECOS PUEBLO ...
    Page 1. THE SPANISH COLONIAL ARCHITECTURE. OF PECOS PUEBLO, NEW MEXICO. Archaeological Excavations and Architectural History of the Spanish Colonial Churches ...
  40. [40]
    [PDF] Adobe bricks in New Mexico
    The Pueblo V segment of the Indian period began after the 1598 arrival of the Spanish and continues to the present day. This latter period of the Indian style ...
  41. [41]
    Add Water, Then Stir - How Adobe Construction Works
    Apr 11, 2023 · Lay the bricks with mortar. Mud works best because it shrinks and swells with the bricks. Cement and similar mortars are too strong and rigid.Missing: stacking | Show results with:stacking
  42. [42]
    [PDF] Lime Plaster on Adobe Walls
    The lime, being a harder material than the mud, resists erosion, but retains the quality of permeability. Later, as lime technologies became more prevalent, ...Missing: stacking | Show results with:stacking
  43. [43]
    Compressive Strength - UpCodes
    Adobe units shall have an average compressive strength of 300 psi (2068 kPa) when tested in accordance with ASTM C67. Five samples shall be tested.
  44. [44]
    14.7.4 NMAC - New Mexico State Records Center and Archives
    The thickness of an adobe buttress shall be a minimum 14 inches. Rammed earth walls greater than 24 inches in thickness are self-buttressing and do not require ...Missing: stability | Show results with:stability
  45. [45]
    [PDF] The Mason and Banco, or Raw Material as a Power for ... - HAL
    Jul 4, 2024 · In short, banco is earth as both material and power. built cracks, or lumps of banco come loose and fall out while the mason is laying them. In ...
  46. [46]
    Cliff of Bandiagara (Land of the Dogons) - UNESCO World Heritage ...
    The Bandiagara site is an outstanding landscape of cliffs and sandy plateaux with some beautiful architecture (houses, granaries, altars, sanctuaries and ...<|control11|><|separator|>
  47. [47]
    A complete history of the Sudano-Sahelian architecture of west Africa
    Jan 12, 2025 · Sudano-Sahelian architecture, one of the world's oldest, uses bricks and timber, with buttressing, pinnacles, and wooden spikes, and is often ...
  48. [48]
    Old Walled City of Shibam - UNESCO World Heritage Centre
    Surrounded by a fortified wall, the 16th-century city of Shibam is one of the oldest and best examples of urban planning based on the principle of vertical ...Missing: rammed pisé
  49. [49]
    Influence of Moisture on the Mechanical Properties of Load-Bearing ...
    In this case, the acceptance criteria for unit blocks establish that adobe's tensile strength is lower-limited to 0.25 MPa by NZS 4298 and 0.35 MPa by NMAC 14.7 ...
  50. [50]
    Experimental study on the in-plane behavior of mud brick walls ...
    However, because of their low strength and brittle nature, they are susceptible to natural disasters, especially earthquakes, which is a concern for many mud- ...
  51. [51]
    Strength Behavior of Mud Brick in Building Construction
    Jun 13, 2016 · This study is devoted to enhance the low compressive strength of mud brick without sacrificing its low thermal conductivity properties.Missing: 0.1-0.5 damage
  52. [52]
    How can adobe mud brick houses stand up to the rain?
    Feb 22, 2003 · Mostly, adobe is used in climates which have little rain, such as the desert southwestern United States, and in arid climates such as Egypt.
  53. [53]
    C67/C67M Standard Test Methods for Sampling and Testing Brick ...
    Mar 28, 2023 · These test methods cover procedures for the sampling and testing of brick and structural clay tile. The tests include modulus of rupture, compressive strength, ...
  54. [54]
    [PDF] Analysis of Physical and Mechanical Properties of Mud Brick ...
    Scientifically, the term mud brick refers to a clay mix, silt (sand with finer aggregate), sand, and sometimes coarse aggregates such as gravel. To talk of the ...
  55. [55]
    Interdisciplinary approaches to understanding and preserving ...
    2. Mudbrick: a primer. A mixture of sand, silt, clay, and organic and inorganic aggregates, mudbrick has been a popular building material for millennia ...
  56. [56]
    Building Physics in Africa's Tropical Paradise: Designing ... - LinkedIn
    Oct 25, 2024 · Passive design can reduce cooling energy needs by 30-50% [23]. Research in Tanzania demonstrated that buildings incorporating passive cooling ...
  57. [57]
    A comparative study of life cycle carbon emissions and embodied ...
    Dec 1, 2020 · This study presents a comparison of the life cycle carbon emission (LCCO 2 ) and embodied energy calculation between two kinds of bricks, sun-dried and fired ...
  58. [58]
    Mudbricks with tea grounds: A zero CO2 emission option for more ...
    Apr 18, 2025 · Mudbricks with tea grounds offer a sustainable, zero CO 2 emission alternative to fired bricks, ideal for regions with high tea consumption and limited energy.
  59. [59]
    Microbes key to sequestering carbon in soil - Cornell Chronicle
    May 24, 2023 · Microbes are by far the most important factor in determining how much carbon is stored in the soil, according to a new study.Missing: mudbrick emissions<|separator|>
  60. [60]
    Performance Analysis of Spinifex Fibre-Reinforced Mudbrick as a ...
    The average tensile strength of spinifex was measured at 17.8 MPa. In samples with 5% cement, the compressive strength increases by the amount of fibre. However ...
  61. [61]
    Thermal Conductivity of Clay Bricks - Thermtest
    Dec 13, 2021 · Clay bricks have a low thermal conductivity, averaging 0.5 – 1.0 W/(m/K), making them thermal insulators that restrict heat transfer.
  62. [62]
    Can you build mud houses in cold climates?
    Oct 23, 2017 · Mud buildings are amazingly energy efficient and warm. Why is that? First, earth actually has some insulation properties (R value of 0.25 per inch compared to ...
  63. [63]
    Great Mosque of Djenné - Smarthistory
    The Great Mosque of Djenné, in present-day Mali, is also the greatest achievement of Sudano-Sahelian architecture. It is also the largest mud-built structure ...
  64. [64]
    Mosque of Djenné | Whose Culture? - Harvard University
    The entire mosque is made out of rammed earth, and the building is replastered annually as part of a festival called the Crepissage de la Grand Mosquée. As ...
  65. [65]
    Taos Pueblo - UNESCO World Heritage Centre
    The property includes the walled village with two multi-storey adobe structures, seven kivas (underground ceremonial chambers), the ruins of a previous pueblo, ...Gallery · Maps · Documents · Videos
  66. [66]
    Taos Pueblo: World Heritage Site (U.S. National Park Service)
    Jul 23, 2020 · At the time, Hernando de Alvarado described the pueblo as having adobe houses built very close together and stacked five or six stories high.
  67. [67]
    Archaeological Ruins at Moenjodaro
    The Archaeological Ruins at Moenjodaro comprise the first great urban center of the Indus civilization built 5000 years ago with burnt brick structures. The ...
  68. [68]
    Building the Great Wall - Association for Asian Studies
    Posts or boards, sometimes bamboo poles, were used to create two walls with a space between. The loess soil was deposited in this space, then pounded by hand.
  69. [69]
    A Guide to Traditional English Buildings - The Historic England Blog
    Aug 25, 2022 · Notable examples include the cob of Devon, the mud and stud buildings of Lincolnshire and the clay dabbins of the Solway Firth in Cumbria.
  70. [70]
    Cottage Building in Cob, Pisé, Chalk & Clay - Project Gutenberg
    The house is very picturesque; it has cob walls and a thatched roof, and is built in the shape of the letter E; a wing projects at either end, and in the ...<|separator|>
  71. [71]
    http://www.focusongeography.org/publications/articles/mali/index.html
  72. [72]
    The Myth of the Mundane: The Symbolism of Mud Brick and Its ...
    Aug 10, 2025 · The Egyptological truism that mud brick was simply mundane limits our understanding of the material and how it functioned in architecture.
  73. [73]
    Living and Spirtual Worlds of Mali's Dogon People
    This article explores living and spiritual worlds of the Dogon, together with the dama's role in sustaining traditions amidst external influences on village ...Missing: banco mudbrick
  74. [74]
    The massive mosque built once a year - BBC
    Aug 2, 2019 · During the Crépissage, residents of Djenné, Mali, work together to repair and rebuild the Grand Mosque, the world's largest mud-brick ...<|separator|>
  75. [75]
    [PDF] Mud-Brick - eScholarship
    Aug 27, 2009 · Apart from molds from foundation deposits, which were probably mainly ceremonial and symbolic. (especially in the case of miniature molds),.
  76. [76]
    The power of mud bricks - The Past
    Mar 17, 2024 · Mud bricks were used widely in construction across Mesopotamia; made of a combination of earth, chopped straw, and water, these were generally ...
  77. [77]
    ARCHITECTURE of the South American Pyramids - Academia.edu
    ... pyramids of adobe, or sun-dried mud-bricks. The Huaca del Sol (or Holy Place of the Sun) was almost 100 feet tall and built of more than 143 million bricks ...
  78. [78]
    Stupas - A Reflection on What They Symbolize - Buddhistdoor Global
    They are calls to the Right Understanding about the human condition, which is unsatisfactory, impermanent and devoid of a self. One poignant example is the ' ...
  79. [79]
    Compressed Stabilized Earthen Blocks and Their Use in Low-Cost ...
    Earthen houses are claimed to be up to 35% cheaper than concrete construction [25]. In a study in India, Cement stabilized CSEBs were reported to be 15% cheaper ...Missing: mudbrick labor-
  80. [80]
    Assessment of Cement-Lime as Stabilizer on Mud Bricks
    Lime and cement improve mud brick strength; lime up to 80% and cement up to 65% at 14 days. Cement is the best stabilizer, reducing water absorption.
  81. [81]
    N.M. Admin. Code § 14.7.4.9 - ADOBE CONSTRUCTION
    3.18 NMAC. They shall be integrated into adjacent adobe walls during construction or secured to them by suitable steel ladder reinforcement or reinforcing rods.
  82. [82]
    Chapter 22 Steel: New Mexico Building Code 2021 | UpCodes
    Chapter 22 requires that the design and use of steel structures and components be in accordance with the applicable specifications and standards of the American ...
  83. [83]
    [PDF] NEw ME - Adobe Home Tour
    8). Stabilized adobe bricks. Fully stabilized adobe brick is defined by the. New Mexico Building Code as water-resistant.
  84. [84]
    Compressed Stabilised Earth Block - Auroville Earth Institute
    The input of soil stabilization allowed people to build higher with thinner walls, which have a much better compressive strength and water resistance. With ...
  85. [85]
    Vaulted Structures - Auroville Earth Institute
    Arches, Vaults and Domes are usually built with compressed stabilised earth blocks, which are laid in “free spanning” mode, without using a formwork.Missing: mudbrick | Show results with:mudbrick
  86. [86]
    Post-war historical site reconstruction | Holcim Foundation
    This proposal aims to rehabilitate or reconstruct important Yemeni cultural landmarks, notably three Sufi shrines and two mosques in Hadramut, two mosques and ...Missing: compressed | Show results with:compressed
  87. [87]
    Cost-effectiveness and affordability evaluation of a residential ...
    Mar 26, 2023 · In Kenya, CSEB walls cost 20%–70% less than concrete block walls, depending on production. A feasibility study in Sri Lanka by Davis and Maïni ...
  88. [88]
    Review of economic and environmental benefits of earthen ...
    For example, rammed earth walls are 50% and 60% cheaper than conventional cement-based sandcrete walls in Egypt (Dabaieh and Sakr, 2015) and Zimbabwe (Zami and ...
  89. [89]
    Doing Your Bit: A cool alternative to concrete – DW – 08/22/2025
    Aug 22, 2025 · Producing mudbricks emits minimal CO₂ compared to concrete, which contributes up to 8% of global carbon emissions. The bricks are made by ...
  90. [90]
    Climate change: The massive CO2 emitter you may not know about
    Dec 17, 2018 · Cement is the source of about 8% of the world's carbon dioxide (CO2) emissions, according to think tank Chatham House. If the cement industry ...
  91. [91]
    Discover the off-grid Earthship community | Wallpaper*
    Jul 6, 2024 · The off-grid Earthship community in New Mexico is an otherworldly desert landscape. Earthship ... 1970s by architect Michael E Reynolds, the ...
  92. [92]
    Nubian Vaults: Sustainable homes to earn carbon credits for families ...
    May 6, 2024 · Nubian Vault homes are built using a technique originating in upper Egypt. Mud, stones and water. That's just about all it takes to construct ...
  93. [93]
    TECLA Technology and Clay 3D Printed House / Mario Cucinella ...
    Apr 27, 2021 · Completed in 2021 in Massa Lombarda, Italy. Images by Iago Corazza. The first eco-sustainable housing model 3D printed entirely from local ...
  94. [94]
    Using Waste in Producing Bio-Composite Mycelium Bricks - MDPI
    In this study, the use of sustainable construction materials from waste in brick production with mycelium as a binder is investigated.
  95. [95]
    How to Build a Mud (or Straw) Home in a Wet Climate
    Jul 6, 2023 · 1. "Make the rubble trench foundation wider than the stem wall by 12-15 cm." This is a good point, and often happens by accident:) 2. "I would ...
  96. [96]
    LEED rating system | U.S. Green Building Council
    To achieve LEED certification, a project must first complete all prerequisites and then earn points by selecting and satisfying credit requirements. Projects go ...LEED v4 · Guide to LEED Certification · LEED certification for new... · LEED v4.1
  97. [97]
    6 Big Findings from the IPCC 2022 Report on Climate Impacts ...
    Feb 27, 2022 · The 2022 IPCC report breaks new ground by analyzing various climate adaptation measures' feasibility, effectiveness and potential to deliver co- ...
  98. [98]
    Bricks Market Size to Reach USD 2.36 Trillion By 2034
    Jun 26, 2025 · The global bricks market is projected to grow from USD 1.79 trillion in 2025 to over USD 2.36 trillion by 2034, registering a CAGR of 3.09%.