Eco-efficient valorization of gold tailings: A low-carbon binder with high early strength and reduced carbon footprint
金尾鉱のエコ効率的な価値化:高い初期強度と低炭素フットプリントを実現する低炭素バインダー (AI 翻訳)
Yukang Wu, Yuzhong Li, Mengxia Xu, Jingwei Li, Qun Chen, Maofeng Nie, Hongkun Pai, Hailong Liu
🤖 gxceed AI 要約
日本語
金尾鉱の固化を目的に、硫黄・アルミ・鉄系低炭素材料(LSCM)と石膏、石灰、普通ポルトランドセメント(OPC)を組み合わせたSGCMを開発。最適配合比(LSCM:(石膏+石灰):OPC=1:1.2:0.4)で3日強度3.40 MPa、28日強度8.26 MPaを達成。さらにセメント比を下げるとOPC同等強度でCO2排出係数70.2%削減、コスト15%低減を実現した。
English
A sulfur-aluminum-ferric gold tailings cementitious material (SGCM) was developed using low-carbon binder components. Optimal proportions achieved 3d/28d compressive strengths of 3.40/8.26 MPa. At a reduced cement ratio, SGCM maintained comparable strength while cutting carbon emission factor by 70.2% and cost by 15.0%.
Unofficial AI-generated summary based on the public title and abstract. Not an official translation.
📝 gxceed 編集解説 — Why this matters
日本のGX文脈において
日本では鉱山廃棄物処理と建設材料の脱炭素化が課題であり、本成果は低炭素セメント技術として応用可能性がある。ただし、日本の規制・業界動向との直接的な連動は限定的。
In the global GX context
This paper offers a practical low-carbon binder for gold tailings valorization, relevant to global efforts in reducing construction material emissions and mining waste management. It contributes empirical data on material performance and carbon reduction.
👥 読者別の含意
🔬研究者:Provides a new binder formulation and hydration mechanism insights for low-carbon cementitious materials.
🏢実務担当者:Companies in mining and construction can adopt this binder to reduce carbon footprint and material costs.
📄 Abstract(原文)
To address the demand for low-carbon binders with high early-age strength for gold tailings cementation, a sulfur-aluminum-ferric gold tailings cementitious material (SGCM) was developed using low-carbon sulfur-aluminum-ferric cementitious material (LSCM), gypsum, lime, and ordinary Portland cement (OPC). The binder composition was optimized through ternary and quaternary system experiments, and the corresponding hydration mechanism was investigated by isothermal calorimetry, X-ray diffraction, thermogravimetric analysis and scanning electron microscopy. The optimal proportion was identified as an LSCM:(gypsum + lime):OPC mass ratio of 1:1.2:0.4. At a cement-to-sand ratio of 1:4 and a filling concentration of 71%, the optimized SGCM achieved compressive strengths of 3.40 MPa at 3 d and 8.26 MPa at 28 d, showing superior early-age strength and competitive long-term strength compared with representative cementitious systems reported in previous studies. In addition, when applied at a reduced cement-to-sand ratio of 1:6, SGCM maintained compressive strength comparable to that of the OPC system at 1:4, while reducing the carbon emission factor by 70.2%; under the self-produced LSCM scenario, the material cost was further reduced by 15.0%. Mechanistic analyses revealed that increasing gypsum and lime contents promoted AFt formation but also transformed AFt into shorter and thicker crystals, whereas OPC incorporation enhanced early hydration, increased C-S-H generation, and densified the microstructure. AFt provided skeletal support, while C-S-H provided filling and bonding, and their synergy governed the strength development of SGCM. • Developed a low-carbon high early-strength binder for gold tailings cementation. • Achieved superior 3 d (3.40 MPa) and 28 d (8.26 MPa) compressive strengths. • Reduced carbon emission factor by 70.2% and cost by 15.0% at comparable strength. • Revealed synergistic mechanism of AFt skeleton and C-S-H gel adhesion.
🔗 Provenance — このレコードを発見したソース
- openalex https://doi.org/10.1016/j.gerr.2026.100187first seen 2026-05-17 05:30:08
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