{"id":"CU26250","slug":"biopolymer-stabilized-clay-for--CU26250","source":{"id":"CU26250","dataset":"techtransfer","title":"Biopolymer-stabilized clay for 3D printing","description_":"

This technology is a biopolymer system combining xanthan gum and locust bean gum to enhance the rheology, buildability, and mechanical strength of earthen materials for 3D-printed construction applications.

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Unmet Need: Earthen materials lack strength, cohesion, and 3D printability

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The construction industry contributes heavily to global carbon emissions and energy use, with cement as a major contributor, driving interest in lower-impact alternatives. Earthen materials have emerged as a promising option due to their low carbon footprint, local availability, and minimal waste, but their adoption is limited by poor mechanical strength, slow processing, and inadequate printability. Current approaches to improve these materials rely on single biopolymer additives, which fail to simultaneously provide sufficient cohesion, strength, and structural stability for 3D printing. Addressing these limitations is critical to enabling scalable, low-carbon, and structurally reliable construction solutions.

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The Technology: Biopolymer-stabilized clay enables stronger, 3D-printable earthen materials

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The technology combines two biopolymers, xanthan gum (XG) and locust bean gum (LBG), to form a stable, reversible gel network that coats clay particles in the earthen mixture. This synergistic combination substantially increases yield stress and storage modulus, enhancing the material’s buildability while maintaining smooth extrusion. Compared to single-polymer systems, the XG-LBG mixture provides improved thixotropic behavior, mechanical strength, and shape retention, making it well-suited for extrusion-based additive manufacturing of earthen materials.

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This technology has been validated with kaolinite clay, the most abundant clay mineral on Earth.

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Applications:

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Advantages:

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Lead Inventor:

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Shiho Kawashima, Ph.D.

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Lola Ben-Alon, Ph.D.

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Patent Information:

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Patent Pending

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Related Publications:

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Tech Ventures Reference:

\r\r","tags":["3D printing","Biopolymer","Carbon footprint","Cement","Clay","Clay mineral","Energy","Erosion control","Extrusion","Gel","Interior design","Kaolinite","Rheology","Self-assembly","Soil erosion","Thixotropy","Urban planning","Xanthan gum","Yield (engineering)"],"file_number":"CU26250","collections":[],"meta_description":"Biopolymer-stabilized clay enhances 3D-printed earthen materials, boosting strength, buildability, and low-carbon construction.","apriori_judge_output":"{\"scores\":{\"novelty\":4.0,\"potential_impact\":4.0,\"readiness\":4.0,\"scalability\":4.0,\"timeliness\":4.0},\"weighted_score\":4.0,\"risks\":[\"Date is 2026-04-20; materials science claims may exceed 3-year window from today but within typical 3-5 year horizon for adoption; risk of overclaiming near-term deployment without field trials.\",\"Potential regulatory and safety considerations for new earthen composites in construction.\",\"Need independent replication across clays and polymers to confirm robustness across geographies.\"],\"one_sentence_take\":\"Strong novelty with a synergistic XG-LBG network; solid potential impact and readiness, but ensure independent validation and clear low-emission deployment path.\"}","inventors":["Maierdan Yierfan","Rachel Lola Ben-Alon","Shiho Kawashima","Wilfred Vencil Srubar III"],"manager":"Dovina Qu","depts":["Civil Engineering and Engineering Mechanics","Graduate School of Architecture, Planning and Preservation"],"divs":["Fu Foundation School of Engineering and Applied Science (SEAS)","Graduate School of Architecture, Planning and Preservation (GSAPP)"],"date_released":"2026-04-20"},"highlight":{},"matched_queries":null,"score":0.0}