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Calcium silicate hydrate

Calcium silicate hydrate (C-S-H), often abbreviated as such, is the primary binding phase in hydrated , constituting 50–70% of the volume of hardened paste and serving as the main contributor to the strength and durability of . It forms as a poorly crystalline, nanoscale gel through the hydration of calcium phases like tricalcium (C₃S, ) and dicalcium (C₂S, ), which are the dominant components of . The hydration process involves a multi-step pathway, beginning with the formation of pre-nucleation clusters of calcium and ions, followed by aggregation into amorphous globules that evolve into the characteristic C-S-H structure resembling defective minerals. The composition of C-S-H is variable, with a typical Ca/Si ratio ranging from 1.5 to 2.0, and a general approximating (CaO)₁.₇(SiO₂)(H₂O)₁.₈, though it can incorporate additional ions such as aluminum, sodium, or , leading to variants like C-A-S-H. Structurally, C-S-H consists of layered sheets featuring dreierketten silicate chains—short, finite chains of three silica tetrahedra—intercalated with calcium ions and water molecules in interlayer spaces, resulting in a disordered, foil-like morphology at the nanoscale with thicknesses of 1–10 . This amorphous nature, lacking long-range order detectable by , arises from defects in the tobermorite-like framework, which cause curvature and prevent dense packing, contributing to its gel-like consistency and high surface area. Key properties of C-S-H include a density of approximately 2.6 g/cm³, an ranging from 20–80 GPa, and the ability to bind aggregates through nanoscale interactions, which underpin concrete's exceeding 100 in mature pastes. Its formation and microstructure significantly influence rates, , and long-term performance, including resistance to chemical attack and dimensional stability, making C-S-H a focal point for advancing sustainable cementitious materials. Over a century of research, from early colloidal models in the to modern atomistic simulations, has elucidated these features, enabling nanoengineering approaches to enhance C-S-H's ordering and properties for ultra-high-performance concretes.

Fundamentals

Definition and Importance

Calcium silicate hydrate (C-S-H) is a poorly crystalline, nanoscale material that forms in the CaO-SiO₂-H₂O system and is denoted using cement chemistry notation, where C stands for CaO, S for SiO₂, and H for H₂O. This gel-like phase arises primarily from the hydration reactions of calcium silicates in , exhibiting a tobermorite-like layered structure that binds the material together. As the principal binding phase in hydrated , C-S-H constitutes 50-70% of the volume of the hydrated paste and accounts for nearly all of concrete's . Its formation during is essential for the development of concrete's mechanical properties, making it indispensable for modern construction. The significance of C-S-H was first recognized in 19th-century studies of , notably by , who proposed its role in strength despite limitations in early . Key advancements came in through the work of William Lerch and Robert H. Bogue, who investigated heats and products, solidifying its central role in chemistry. C-S-H is not a single compound but a family of phases characterized by variable , with Ca/Si ratios typically ranging from 1.2 to 2.0 and commonly around 1.7, reflecting its compositional flexibility in different hydration environments. This variability contributes to its adaptability as the dominant phase in cementitious materials.

Chemical Composition

Calcium silicate hydrate (C-S-H) is characterized by the general (\ce{CaO})_x \cdot \ce{SiO2} \cdot (\ce{H2O})_y, where the values of x and y vary depending on formation conditions, reflecting its non-stoichiometric . In cementitious materials, the Ca/Si (C/S) ratio typically ranges from 1.2 to 2.1, with an average of approximately 1.7 observed in plain pastes. This ratio determines the relative proportions of and silica in the phase, influencing its overall without a fixed composition. The C/S ratio in C-S-H exhibits significant variability based on synthesis conditions and environmental factors. In high-silica environments, such as those involving supplementary cementitious materials like fly ash or , the C/S is lower, often below 1.5, due to increased silicate and reduced calcium availability. Conversely, in calcium-rich settings typical of ordinary , the C/S exceeds 1.7, leading to more calcium incorporation and shorter silicate chains. This compositional flexibility arises from the during formation, where excess calcium or silica alters the phase's balance. C-S-H also incorporates minor elements that modify its composition, primarily aluminum from aluminate phases, sulfate, and alkali ions. Aluminum substitutes into the silicate structure, with uptake levels up to an Al/Si ratio of 0.05 in phases with C/S around 1.0, forming calcium aluminate silicate hydrate (C-A-S-H). ions adsorb onto or incorporate within C-S-H, particularly in sulfate-containing environments, affecting surface charge and . ions such as ^+ and ^+ occupy interlayer sites, with incorporation increasing at lower C/S ratios and higher initial alkali concentrations in the . These elements, typically at low concentrations, arise from impurities or additives and influence the phase's charge balance. The of C-S-H is determined using analytical techniques tailored to its amorphous nature. (XRF) spectroscopy provides bulk , quantifying major components like , , and minor elements in solid samples without . For precise C/S ratios, (ICP) optical emission is employed after , offering high sensitivity for dissolved cations and accurate molar ratio calculations. These methods ensure reliable , often complemented by selective to isolate C-S-H from other products.

Structure and Morphology

Atomic and Molecular Structure

Calcium silicate hydrate (C-S-H) possesses a layered structure closely analogous to the crystalline minerals 11 Å and jennite, serving as primary structural models for its organization. In this arrangement, the fundamental building units are calcium-silicate sheets that form the main layers, separated by interlayers containing loosely bound calcium ions and water molecules, which act as bridges between adjacent sheets. The mainsheet itself comprises edge-sharing calcium octahedra coordinated with silicate tetrahedra, creating a corrugated framework that accommodates structural flexibility. The silicate components within these sheets are organized into dreierketten , characterized by repeating motifs of three tetrahedra: paired dimers and pentamers linked by bridging units in a 3n-1 , where n represents the repeat length. This structure arises from the of isolated tetrahedra (Q^0) into linear and occasionally branched forms, with the predominantly reflected in Q^1 (end-of-chain dimers) and Q^2 (middle-of-chain) silica environments, as determined by ^{29}Si (NMR) spectroscopy.90046-2) These Q^1 and Q^2 units dominate the spectra of synthetic and cement-derived C-S-H, indicating finite lengths typically ranging from 3 to 11 tetrahedra, depending on synthesis conditions.90046-2) Cross-linking between dreierketten chains occurs through bridging silica tetrahedra (Q^3 sites), enhancing connectivity within the layers, though such links are infrequent in low-Ca/Si C-S-H. However, inherent nanoscale disorder, including vacant bridging sites, stacking faults, and irregular chain terminations, results in poor long-range crystallinity, distinguishing C-S-H from its more ordered analogs. This disorder manifests in broadened X-ray peaks and is a key feature of C-S-H's amorphous-like character at the atomic scale.

Nanoscale Features

Calcium silicate hydrate (C-S-H) exhibits distinctive nanoscale morphology characterized by foil-like or needle-shaped nanoparticles, typically consisting of thin sheets 5-10 nm thick that aggregate into fibrillar or honeycomb networks. These foil-like structures, often observed as crumpled or layered nanosheets with thicknesses around 3.5-7 nm, form the basic building blocks in both synthetic and cement-derived systems. Needle-like particles, with lengths exceeding widths by a factor of 10 and diameters of approximately 20 nm, display a layered internal arrangement and contribute to reticulated patterns at the nanoscale. The nanoscale features of C-S-H include high and , arising from gel pores in the 1-10 nm range that form an interconnected nanoporous network. This accounts for approximately 28% of the volume in hydrated paste, primarily within the C-S-H phase, enabling significant adsorption and transport. The typically ranges from 200-300 m²/g, reflecting the extensive exposure of the thin sheet surfaces and contributing to the material's reactivity and durability in cementitious systems. Due to its colloidal nature, C-S-H demonstrates aggregation behavior that results in fractal-like clusters, with dimensions typically between 1.4 and 2.2, forming stable suspensions or dense packs depending on environmental conditions. These clusters, observable as low-density aggregates up to 700 in size, exhibit random nanoscale organization that evolves into continuous foil or needle structures. Techniques such as (AFM) reveal agglomerations of 60 × 30 × 5 ³ particles on surfaces, while (SAXS) confirms the planar, two-dimensional features and high surface area in suspensions. The calcium-to-silicon (C/S) significantly influences C-S-H at the nanoscale, with lower ratios (e.g., below 1.58) promoting more elongated, fiber-like or foil-like forms that enhance structural . In contrast, higher C/S ratios (e.g., above 1.58) lead to denser, globular or fibrillar aggregates with reduced and increased packing density. These variations arise from differences in layer spacing and growth, affecting the overall and response of the hydrate phase.

Formation Processes

In Cement Hydration

Calcium silicate hydrate (C-S-H) forms primarily through the hydration reactions of the main clinker phases in , tricalcium silicate (C₃S) and dicalcium silicate (C₂S). The hydration of C₃S proceeds according to the reaction $2\mathrm{C_3S} + 6\mathrm{H} \to \mathrm{C_3S_2H_3} + 3\mathrm{CH}, where C represents CaO, S represents SiO₂, H represents H₂O, C₃S₂H₃ denotes C-S-H, and CH denotes ; this process is the major contributor to the 's early strength and is highly exothermic. Similarly, C₂S hydrates via $2\mathrm{C_2S} + 4\mathrm{H} \to \mathrm{C_3S_2H_3} + \mathrm{CH}, contributing to longer-term strength development but producing less heat. These reactions result in C-S-H with a typical calcium-to-silicon ratio (C/S) of about 1.7. The kinetics of C-S-H formation are characterized by rapid initial precipitation from C₃S, which dominates the first 24 hours of and involves on clinker particle surfaces, leading to an period of intense growth. This phase is followed by a deceleration as the protective C-S-H layer thickens, limiting further . In contrast, C₂S hydration is slower, extending over 28 days or more, with gradual C-S-H formation that fills remaining pores and enhances durability. The overall process is exothermic, with peak heat evolution during the early C₃S reaction, influencing the setting time and early microstructure development. Several factors influence the rate and extent of C-S-H formation during cement hydration. The water-to-cement ratio (w/c) is critical, with an optimal range around 0.40–0.42 allowing complete hydration without excess ; lower ratios limit reaction progress, while higher ones dilute ions and slow . affects significantly, with an ideal range of 20–30°C promoting balanced hydration rates—elevated temperatures accelerate early reactions but can lead to uneven microstructure, whereas lower temperatures prolong the dormant period. Admixtures, such as superplasticizers, modify the process by dispersing particles to enhance sites and growth, thereby improving workability and early strength without altering w/c. During hydration, volume changes occur as anhydrous clinker phases convert to hydration products, resulting in an overall expansion that densifies the paste microstructure by filling capillary pores with C-S-H gel. This densification reduces porosity and permeability, contributing to the hardened cement paste's mechanical integrity, though the process involves a net chemical shrinkage offset by product precipitation.

Laboratory Synthesis

One common laboratory method for synthesizing pure calcium silicate hydrate (C-S-H) involves precipitation from aqueous solutions of and , typically conducted under alkaline conditions at 12-13 to promote rapid and formation. Concentrations are often set at 0.2 mol/L for and 0.1 mol/L for , with the solutions mixed at controlled rates to achieve desired Ca/Si ratios ranging from 0.8 to 2.0. Following initial precipitation, the resulting is aged for several hours to days at or elevated temperatures (e.g., 40-60°C) to stabilize the structure and refine particle size, allowing precise control over the C/S ratio which influences the interlayer spacing and . Hydrothermal synthesis provides an alternative route to produce more crystalline C-S-H phases, such as tobermorite analogs, by reacting (CaO) and silica (SiO₂) under elevated and conditions of 150-200°C. The reactants are typically mixed in a molar CaO/SiO₂ ratio of 0.8-1.0, sealed in an with water to achieve saturated (around 8-16 ), and heated for 8-24 hours to facilitate phase transformation from amorphous precursors to layered structures like 11 Å . This method yields denser, more ordered materials compared to ambient precipitation, with crystallinity increasing with longer reaction times and higher temperatures within the specified range. Sol-gel routes enable nanoscale control over C-S-H formation by hydrolyzing tetraethyl orthosilicate (TEOS) in the presence of calcium salts, such as calcium nitrate tetrahydrate, under acidic or basic catalysis. The process begins with the acid-catalyzed hydrolysis of TEOS to form a silica sol, followed by addition of the calcium salt and adjustment to neutral or alkaline pH for co-gelation, often incorporating surfactants to tune particle morphology into spheres or fibers with diameters below 100 nm. Aging and drying steps at 60-80°C promote cross-linking and densification, resulting in hybrid gels that mimic the nanoscale features of cementitious C-S-H. Post-synthesis characterization of laboratory-produced C-S-H frequently employs (TGA) to quantify bound water content, which typically ranges from 20-30 wt% and corresponds to interlayer and hydroxyl-bound water lost between 50-300°C. This technique distinguishes evaporable water (below 105°C) from structurally bound components, providing insights into the hydration degree and stability, with higher bound water fractions observed in lower C/S ratio samples.

Properties

Physical and Thermal Properties

Calcium silicate hydrate (C-S-H) exhibits a range of physical properties that are critical to its role in cementitious materials, with varying based on and structural packing. The apparent of nanoscale C-S-H gel particles, including physically bound , is measured at 2.604 g/cm³ using small-angle and techniques on hydrated samples. This value reflects the solid phase incorporating interlayer and gel-bound , as determined from the mean (CaO)1.7(SiO2)(H2O)1.80. The skeletal of the anhydrous C-S-H structure is approximately 2.6 g/cm³, derived from data and consistent with molecular models of the framework. Apparent typically ranges from 2.0 to 2.5 g/cm³ in hydrated forms, decreasing with higher due to the incorporation of evaporable and bound within the . Porosity in C-S-H arises from its gel-like , featuring an intrinsic bimodal at the nanoscale that influences retention and transport. Interlayer pores measure approximately 1.2 , accommodating bound molecules between sheets, while smaller intralayer pores around 0.5 contribute to the tight packing of the structure. This nanoscale is complemented by larger pores (1-10 ), resulting in a total of up to 50% by volume in the C-S-H phase, as observed through and packing density analyses. These pores, derived from the stacking of disordered layers, enable high sorption but also affect the overall compactness of paste. Thermal properties of C-S-H are characterized by distinct dehydration stages, revealing its sensitivity to and implications for under heat exposure. Thermogravimetric analysis (TGA) shows initial loss of evaporable below 105°C, corresponding to free and loosely bound in gel pores. Subsequent of bound and partial decomposition occurs between 105°C and 400°C, followed by silicate framework breakdown in the 400-600°C range, where reflects the release of hydroxyl groups and structural rearrangement. The process contributes to the exothermic nature of setting and influences early-age management. Electrical properties of C-S-H stem from its hydrated structure, exhibiting a high constant due to polarized layers within . Values range from 20 to 80, depending on frequency and hydration state, as measured by impedance spectroscopy on hydrating pastes where mobility enhances . This response is anisotropic, with in-plane constants increasing with thickness, reflecting the influence of interlayer on charge storage and conduction in cementitious systems.

Chemical Properties

Calcium silicate hydrate (C-S-H) plays a key role in maintaining the high of the pore solution in cementitious materials, typically sustaining a range of 12.5 to 13.5 primarily through the of (, CH). Once is depleted during or long-term exposure, C-S-H contributes to pH buffering by releasing calcium ions through selective , thereby mitigating drops in the surrounding environment. C-S-H exhibits low under to alkaline conditions, characterized by a solubility product where the product of calcium and activities is approximately 10^{-8} M², reflecting its in high- environments. However, at lower pH values below 9, C-S-H undergoes decalcification, preferentially calcium ions and leaving behind a silica-rich that further alters the material's chemistry. The material demonstrates significant capacity, particularly for cations, which adsorb onto calcium sites within the C-S-H structure. For instance, lead (Pb²⁺) and (Cd²⁺) can be effectively bound, with adsorption capacities reaching up to 1-2 mmol/g depending on the C-S-H composition and environmental conditions. Exposure to leads to of C-S-H, where calcium ions react to form (CaCO₃) precipitates, progressively reducing the Ca/Si ratio—often down to around 0.67—and enhancing the overall stiffness of the structure through densification. This process not only sequesters CO₂ but also modifies the chemical reactivity of C-S-H by polymerizing silicate chains.

Mechanical Properties

Calcium silicate hydrate (C-S-H) exhibits mechanical properties that are critical to the performance of cement-based materials, primarily assessed at micro- and nano-scales using techniques such as . The elastic modulus of C-S-H gel, measured via , typically ranges from 20 to 30 GPa, with low-density variants showing values around 21.7 GPa and high-density variants around 29.4 GPa. These values are lower than those of (CH), which range from 35 to 45 GPa. The layered structure of C-S-H imparts , with the higher parallel to the sheets (up to 50 GPa) compared to the transverse direction (around 20-25 GPa). within the C-S-H gel reduces the effective , linking nanoscale features to macroscopic . Hardness of C-S-H, also derived from , falls in the range of 0.5 to 1 GPa, with low-density phases at approximately 0.45 GPa and high-density at 0.66 GPa. This property is sensitive to indentation depth, decreasing at shallower depths due to surface effects, and to , where higher levels soften the through interlayer swelling. C-S-H displays a viscoelastic response characterized by and shrinkage, arising from time-dependent deformation under sustained load. This behavior follows a logarithmic model, with the exhibiting higher capacity upon rehydration after drying, governed by within nanopores and sliding between sheets. Toughness in C-S-H is limited, with a low of about 1.7 N/m, resulting from brittle sliding of weakly bonded sheets during propagation. Crosslinking within the , such as through organosilane modifications, can enhance this by strengthening interlayer bonds. These intrinsic properties underpin the of , where C-S-H acts as the primary load-bearing phase.

Applications

In Construction Materials

Calcium silicate hydrate (C-S-H) serves as the primary binding phase in , forming an interlocking network of nanoscale fibers and particles that imparts the material's structural integrity and accounts for approximately 70-80% of the volume of hydrated products. This gel-like structure develops during the hydration process, where calcium silicates in the react with to create a dense matrix that binds aggregates together, contributing the majority of the 's compressive strength, typically 20–40 MPa for standard mixes after 28 days of curing under standard conditions. The mechanical contributions of this network are essential for load-bearing applications in buildings, bridges, and infrastructure. The formation of C-S-H gel significantly influences the workability and handling properties of fresh . As progresses, the gel absorbs free from the mix, leading to increased and a transition from fluid paste to a semi-solid state, which affects by reducing flowability and promoting . This consumption also governs the setting time, with the initial set—defined as the point where the paste loses plasticity—typically occurring within 2-4 hours, depending on factors like and admixtures. In blended , such as those incorporating supplementary materials like fly ash, the calcium-to-silica (C/S) ratio in C-S-H can be optimized to enhance overall performance. Fly ash reacts pozzolanically with from to form additional C-S-H with a lower C/S ratio, resulting in a denser microstructure that improves long-term strength, reduces permeability, and enhances durability without compromising early-age properties. This approach allows for more sustainable formulations by partially replacing clinker while maintaining the binding efficacy of C-S-H. Global cement production, which relies on C-S-H as its core phase, reached approximately 3.9 billion metric tons in 2024, underscoring the scale of its application in worldwide.

Other Industrial Uses

Calcium silicate hydrate (C-S-H) serves as a key binder in synthetic calcium silicate boards used for high-temperature in , providing thermal stability and mechanical strength up to 1100°C. These boards, formed through of C-S-H phases like xonotlite, offer low thermal conductivity (typically 0.05-0.1 W/m·K at 500°C) and resistance to , making them suitable for lining industrial furnaces, kilns, and boilers where they act as backup to linings. The C-S-H matrix in these materials ensures dimensional stability under cyclic heating, reducing cracking and extending in demanding environments. In biomedical applications, C-S-H-based materials exhibit bioactivity and controlled release, enabling their use in cements and scaffolds for regeneration. These cements, often formulated as composites, promote formation on their surface in simulated body fluids, enhancing for orthopedic and dental implants. Additionally, mesoporous C-S-H structures facilitate systems, achieving high loading capacities (up to 50 wt%) for antibiotics or growth factors, with sustained release over weeks due to their ion-exchange properties. For nuclear waste encapsulation, C-S-H in cementitious barriers adsorbs radionuclides through surface complexation and incorporation into its gel structure, leveraging its high calcium-to-silicon ratio for selective uptake. This sorption mechanism effectively immobilizes ions like cesium and , with distribution coefficients exceeding 10^4 mL/g under alkaline conditions typical of pore solutions, preventing in long-term repositories. simulations confirm that radionuclides bind to and calcium sites on C-S-H surfaces, enhancing the durability of waste forms. Emerging applications include the use of nano-C-S-H as additives in 3D-printed to improve printability and early-age strength. These nanoparticles accelerate , reducing and enhancing shape retention during , allowing for complex geometries with minimal (less than 5 mm over 30 minutes). By seeding C-S-H , they increase by 20-30% at 28 days without compromising flowability.

Advanced Topics

Durability and Degradation

Calcium silicate hydrate (C-S-H) plays a pivotal role in the long-term of cement-based materials, primarily through its ability to bind aggressive ions and maintain structural integrity under environmental stresses. However, exposure to external agents can lead to mechanisms that compromise the C-S-H matrix, resulting in reduced performance over time. Key pathways include sulfate attack, chloride penetration, alkali-silica reaction (ASR), and calcium leaching, each exploiting vulnerabilities in the C-S-H structure to induce expansion, cracking, or increased permeability. Sulfate attack involves the ingress of sulfate ions (SO₄²⁻) into pores through and , driven by concentration gradients. These ions react with aluminates and C-S-H components to form expansive ettringite (3CaO·Al₂O₃·3CaSO₄·32H₂O), whose needle-like crystals generate internal stresses by increasing the solid phase volume up to eightfold. This expansion disrupts the C-S-H matrix, leading to micro-cracking and macro-scale surface cracks that accelerate further deterioration. In aggressive environments, such as sulfate-rich soils or , the process reduces and increases , with depths reaching 3-5 mm after extended exposure periods. Chloride penetration poses a significant threat to reinforced concrete by facilitating corrosion of embedded steel. C-S-H binds chloride ions (Cl⁻) primarily through physical adsorption and chemical incorporation into its structure, with absorption following a Freundlich isotherm in concentrations of 0.1-1.0 M Cl⁻, typically achieving capacities of 0.5-1 mol/kg depending on pH and composition. This binding helps maintain the passive oxide layer on steel reinforcement, but once free chloride levels exceed a corrosion threshold of approximately 0.4% by weight of cement, depassivation occurs, initiating pitting corrosion. The process is exacerbated in de-iced roads or marine environments, where chloride ingress increases over time, weakening the C-S-H gel and promoting crack propagation. The alkali-silica reaction (ASR) arises when alkalis in the pore solution react with reactive silica in aggregates, forming expansive ASR gels that infiltrate C-S-H pores. These gels, characterized by low Ca/Si ratios (initially as low as 0.05, rising to 0.25), generate solidification pressures of 6-13 MPa in confined spaces less than 30 nm, driven by electrostatic repulsion and precipitation rather than mere water uptake. The resulting expansion within the C-S-H matrix induces tensile stresses, leading to cracking that propagates from aggregates into the surrounding paste. ASR manifests over years in high-alkali concretes exposed to moisture, causing map-like cracking patterns and substantial volume changes. Calcium leaching occurs when C-S-H is exposed to aggressive waters, such as acidic or soft , causing progressive of calcium ions from and the C-S-H gel itself. This decalcification increases by degrading the solid phases, with capillary and gel pores expanding significantly; in natural conditions, leaching depths can reach 5-10 mm over 100 years, though accelerated in tests. The heightened permeability facilitates further ion ingress, mechanically weakening the matrix and reducing by up to 50% in severe cases. Over decades, this process undermines the overall of structures like or tunnels in leaching-prone environments.

Modeling and Simulations

Molecular dynamics (MD) simulations have been instrumental in elucidating the nanoscale behavior of calcium silicate hydrate (C-S-H), particularly through models based on -like structures that serve as proxies for the disordered C-S-H phase. These simulations predict key dynamical properties, such as water dynamics and ion diffusion, by resolving atomic interactions within nanopores. For instance, unbound water molecules in C-S-H pores exhibit self-diffusion coefficients on the order of 10^{-9} m²/s, while confined water diffuses more slowly due to interactions with the framework. Such models draw from the atomic structure of to validate predictions against nanoscale features observed experimentally. Calcium-silicate chain models provide insights into the processes governing C-S-H formation, incorporating Q^n to describe the of tetrahedra. This approach highlights the role of Q^1 and Q^2 species in the disordered chains typical of C-S-H, offering a theoretical framework for . At the mesoscale, discrete element modeling (DEM) simulates the aggregate behavior in cement paste by representing C-S-H as bonded particle clusters, capturing mechanical interactions and deformation under load. These models treat C-S-H globules as discrete elements to predict creep and stress relaxation, revealing how microstructural evolution affects overall paste rheology. DEM approaches bridge atomic-scale insights with macroscale properties, such as load distribution around aggregates. Recent advances since 2020 have integrated potentials into large-scale simulations of C-S-H, enhancing accuracy for disordered structures beyond traditional force fields. Deep learning-based potentials, trained on data, enable efficient runs on systems with varying Ca/Si ratios, improving predictions of and ion transport in realistic, nanoscale amorphous configurations. These methods reduce computational costs while maintaining quantum-level fidelity, facilitating studies of and degradation at extended timescales. High-throughput atomistic modeling frameworks and potentials have further advanced predictions of structural and across composition ranges as of 2025.

Environmental Impact

The production of calcium silicate hydrate (C-S-H) through cement is closely tied to the environmental footprint of manufacturing, which accounts for approximately 8% of global anthropogenic CO₂ emissions, or about 2.5 Gt per year as of recent estimates. These emissions primarily arise from the of in clinker production, releasing CO₂ during the decomposition of to form , the key precursor for C-S-H formation upon . Cement production also imposes significant resource demands, including high consumption during mixing, typically at a water-to-cement ratio of around 0.4 for optimal workability and strength, which contributes to local water stress in water-scarce regions. Additionally, silica sourcing for clinker—often from clay, , or quarries—leads to habitat disruption, , and dust , exacerbating and in mining areas. Mitigation strategies focus on low-carbon alternatives to traditional , such as geopolymers derived from industrial byproducts like fly ash, which can reduce CO₂ emissions by up to 80% compared to by avoiding clinker production altogether. CO₂-cured C-S-H systems, involving accelerated of calcium silicates, enable of up to 0.2 tons of CO₂ per ton of through mineral during curing, effectively offsetting a portion of production emissions. Lifecycle assessments of C-S-H-based materials highlight how enhanced —through optimized composition and reduced permeability—extends , thereby decreasing the frequency of replacements and lowering cumulative environmental impacts by 20-50% over the structure's lifespan compared to less durable variants. These assessments emphasize that while upfront emissions remain high, long-term eco-efficiency improves with materials that resist , supporting broader .

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