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Lithium disilicate

Lithium disilicate is a glass-ceramic material primarily composed of (Li₂O) and (SiO₂), with the Li₂Si₂O₅, featuring interlocking needle-like crystals embedded in a residual matrix. This microstructure provides exceptional mechanical properties, including a of 360–400 and of 2.0–3.5 ·m¹/², making it suitable for high-load dental restorations. Its high translucency and color-matching capabilities closely mimic natural , enhancing aesthetic outcomes in clinical applications. Introduced in in the late as a pressed (e.g., Empress 2), it has evolved into CAD/CAM-compatible forms like e.max, enabling precise fabrication through processes such as or milling followed by at approximately 840–850°C. The material's and wear resistance further support its use in monolithic crowns, veneers, inlays, onlays, and fixed partial , with clinical survival rates exceeding 95% over 3–10 years. Advantages include minimal plaque accumulation and reduced risk of chipping compared to earlier ceramics, though successful bonding requires surface etching with and application. While predominantly employed in , lithium disilicate's durability has led to emerging applications in materials and display technologies due to its optical and structural integrity. Limitations involve potential fabrication challenges, such as control during processing, which can affect homogeneity.

Introduction

Definition and composition

Lithium disilicate is a glass-ceramic material primarily composed of crystals embedded in a glassy matrix, classified as a -based glass-ceramic widely used in dental applications due to its and . The primary crystalline phase is lithium disilicate, with the \ce{Li2Si2O5}. Its is 150.05 g/mol. Typical compositions of lithium disilicate consist of 57–80 wt% \ce{SiO2} as the main network former, 11–19 wt% \ce{Li2O} to facilitate , 0–13 wt% \ce{K2O} as a , and 1–7 wt% \ce{P2O5} as a nucleating agent. Minor additives, such as 0–7 wt% \ce{Al2O3} for enhancing mechanical properties, \ce{ZrO2} for and strengthening, and \ce{CeO2} for and coloring, are included to tailor the material's performance.

Historical development

Research on lithium silicates for glass-ceramics began in the 1950s, when Donald Stookey at Corning Glass Works discovered the process of controlled nucleation and crystallization, leading to the identification of lithium disilicate (Li₂Si₂O₅) as a key phase capable of imparting high strength to glass-ceramic materials. During the 1950s and 1970s, extensive studies focused on the lithium silicate system, particularly the stoichiometric Li₂O-2SiO₂ composition, to develop materials with enhanced mechanical properties for industrial applications. In the 1970s, researchers George Beall and Lina M. Echeverria advanced this work by exploring lithium disilicate glass-ceramics with improved microstructures, laying the groundwork for specialized uses. The adaptation of lithium disilicate for dental applications gained momentum in the 1990s, driven by Ivoclar Vivadent's efforts to create high-strength, aesthetically superior alternatives to existing ceramics. This culminated in the launch of in 1998, the first commercial lithium disilicate glass-ceramic for indirect dental restorations. Ivoclar Vivadent further refined the material, introducing the system in 2005, which expanded options for pressable and machinable forms. A key milestone in the 2000s was the development of CAD/CAM-compatible blocks, such as launched in 2006, enabling efficient chairside fabrication of restorations. This evolution was propelled by the demand for all-ceramic restorations over traditional metal-ceramics, primarily to achieve better and while maintaining . Clinical studies have validated its performance, reporting 5-year survival rates of 97.8% for single crowns and 78.1% for partial fixed dental prostheses, and 10-year rates of 96.7% for crowns and 70.9% for partial fixed dental prostheses. These outcomes underscore lithium disilicate's role in shifting dental practice toward metal-free solutions that prioritize natural appearance.

Structure and microstructure

Crystal structure

Lithium disilicate adopts an with Ccc2. The unit cell has approximate parameters a = 5.79 , b = 14.61 , c = 4.77 . In this structure, the atomic arrangement features [SiO₄] tetrahedra sharing corners to form chains, with Li⁺ ions coordinated tetrahedrally by oxygen atoms, resulting in a layered configuration of sheets separated by lithium layers. Lithium disilicate exhibits polymorphism, with a high-temperature β-Li₂Si₂O₅ (orthorhombic) and a low-temperature α-Li₂Si₂O₅ (monoclinic); the β form is the thermodynamically stable observed in used for practical applications.

Glass-ceramic formation

The formation of lithium disilicate involves a controlled process that transforms the amorphous base into a with embedded crystals, primarily through a two-stage . In the initial stage, the is heated to temperatures between 450°C and 550°C, where metastable lithium metasilicate (Li₂SiO₃) seeds form as precursors to the target . This stage typically lasts 1–8 hours to generate a high density of sites, ensuring uniform crystal distribution throughout the material. Nucleating agents play a critical role in this stage by promoting heterogeneous and controlling crystal size and distribution. Common additives such as (P₂O₅) or zirconia (ZrO₂) are incorporated into the composition at concentrations of 1-12 wt%, forming secondary phases like (Li₃PO₄) or zirconate compounds that serve as sites for Li₂SiO₃ precipitation. P₂O₅, in particular, is widely used in dental formulations, contributing 5-15 vol% of the final microstructure as Li₃PO₄ while enhancing the rate by up to two orders of magnitude. These agents lower the energy barrier for crystal formation, preventing uncontrolled and allowing precise tailoring of the microstructure. Following nucleation, the second stage involves heating to 800-850°C (for dental-grade materials), where the Li₂SiO₃ seeds dissolve and recrystallize into the stable lithium disilicate (Li₂Si₂O₅) phase through a solid-state reaction. This growth phase, often held for 1-2 hours, results in the development of a fine-grained microstructure characterized by randomly oriented, interlocking needle-like or plate-like crystals with lengths of 0.5-2 μm. The elongated morphology arises from anisotropic kinetics, where the crystals interlock to form a reinforced network within the residual glass matrix, contributing to the material's overall integrity. In dental-grade lithium disilicate , the crystalline phase typically achieves a of approximately 70 vol%, with the lithium disilicate crystals dominating the structure alongside minor nucleating agent-derived phases. This high crystallinity is optimized during the to balance phase purity and microstructural homogeneity, ensuring reproducible performance in applications.

Properties

Mechanical properties

Lithium disilicate exhibit a biaxial typically ranging from 360 to 530 (depending on specific product and processing, per ISO 6872), enabling their use in load-bearing dental applications. This strength arises from the high volume fraction of interlocking lithium disilicate crystals within the glassy matrix, which distributes stress effectively under flexural loads. The fracture toughness (K_IC) of lithium disilicate is reported as 3.3 ± 0.14 MPa·m^{1/2}, attributed to mechanisms such as crack deflection and bridging facilitated by the needle-like, interlocking crystal morphology. These microstructural features promote energy dissipation during crack propagation, enhancing resistance to brittle failure compared to traditional glass-ceramics. Young's modulus for lithium disilicate falls in the range of 90-100 GPa, reflecting its stiff yet somewhat flexible nature relative to dentin, which aids in mimicking natural tooth biomechanics. Vickers hardness is approximately 5.3–6.0 GPa, contributing to wear resistance. The Weibull modulus, ranging from 10 to 15, indicates a relatively reliable strength distribution with low variability in failure probability, underscoring consistent performance across specimens. Under cyclic loading, lithium disilicate demonstrates good resistance, maintaining structural integrity over extended periods and supporting its suitability for posterior restorations subjected to masticatory forces. This is linked to the material's ability to resist subcritical , as evidenced in simulated simulations.

Physical, optical, and chemical properties

Lithium disilicate have a ranging from 2.5 to 2.6 g/cm³, which supports their lightweight yet robust nature in dental applications. This arises from the fine-grained crystalline structure embedded within a glassy , contributing to overall material efficiency without compromising volume stability. The coefficient of for lithium disilicate is typically 10 to 12 × 10⁻⁶ K⁻¹, making it highly compatible with the thermal expansion coefficients of dental alloys (around 10–14 × 10⁻⁶ K⁻¹) and natural structures (approximately 11 × 10⁻⁶ K⁻¹). This compatibility minimizes internal stresses during thermal cycling in the oral environment, such as from hot or cold foods. The interlocking microstructure formed during glass-ceramic processing further enhances resistance. Optically, lithium disilicate offers excellent translucency, with values of 25–35% at 550 for clinically relevant thicknesses (e.g., 1–2 ), allowing natural light diffusion similar to and . Its of approximately 1.55 closely matches that of human (1.62), reducing light scattering at interfaces and enhancing lifelike . To achieve precise shade matching with the Vita classical shade guide, metal oxides such as iron, , and are incorporated as colorants during synthesis, enabling a range of –D4 shades with minimal opacity variation. Chemically, lithium disilicate demonstrates high , with in oral fluids below 10 μg/cm², well under ISO 6872 standards for dental ceramics (<100 μg/cm²). It resists in acidic environments ( 2–10), including exposure to from beverages or gastric reflux, due to the stable Si–O–Li network that limits . This durability ensures long-term integrity in the oral cavity without significant surface erosion or color alteration. In terms of bioactivity, lithium disilicate promotes through surface formation when immersed in simulated (SBF), where calcium and ions from the solution deposit as layers within 7–14 days. This process, driven by the release of and ions that nucleate crystallization, supports bone apposition around implants or restorations.

Production methods

Synthesis of base glass

The synthesis of the base glass for lithium disilicate begins with the selection of high-purity raw materials, primarily (SiO₂) as the silica source, (Li₂CO₃) to provide Li₂O, (K₂CO₃) for K₂O, (P₂O₅) as a nucleating agent, and additives such as alumina (Al₂O₃) to modify and stability. These reagents, typically of analytical grade with purity exceeding 99%, are weighed according to the target composition—commonly around 65-70 mol% SiO₂, 25-30 mol% Li₂O, 2-3 mol% K₂O, 2-3 mol% P₂O₅, and 0.5-3 mol% Al₂O₃—and ball-milled or mechanically mixed for several hours to ensure uniformity. The homogeneous batch is loaded into crucibles, often or high-alumina types to withstand high temperatures and avoid , and melted in an electric at 1350-1500°C for 1-4 hours. This duration allows for complete dissolution and fining of the melt, resulting in a clear, bubble-free with the desired amorphous structure. Stirring may be employed periodically to enhance homogeneity, particularly in larger batches. Upon completion of melting, the molten glass is rapidly quenched to preserve its amorphous state and prevent unintended . Common methods include pouring the melt into to form or into a preheated metal (e.g., at 450-500°C), followed by controlled annealing at 450-500°C for 1-2 hours to relieve internal stresses, and slow cooling to . This quenching step yields solid ingots or that can be further ground into powder for downstream applications, maintaining the glass's transparency and homogeneity. Composition tuning is essential to tailor the base for specific uses, such as increasing P₂O₅ content (typically 2-3.5 mol%) in dental-grade formulations to promote effective sites during later processing. Compositions are often slightly non-stoichiometric (deviating from the ideal Li₂Si₂O₅ ratio) to enhance and final properties. While industrial variants may incorporate alternative modifiers like ZrO₂ or B₂O₃ for enhanced thermal stability or cost efficiency, these adjustments ensure the glass precursor aligns with performance requirements without altering the core Li₂O-SiO₂ matrix.

Processing techniques

Lithium disilicate are primarily fabricated into finished products through techniques that transform pre-formed ingots or blocks into precise shapes, often tailored for high-strength applications such as dental frameworks. These methods leverage controlled heat treatments to achieve the desired while maintaining structural integrity. One established processing technique is lost-wax , also known as , where lithium disilicate ingots—derived from base —are melted and injected into molds. The ingots are heated to the pressing of approximately 900–950°C to achieve a viscous state suitable for pressing, allowing the material to fill intricate mold cavities created via the lost-wax method for complex frameworks. This process typically involves investment burnout followed by pressing to finalize the shape, resulting in restorations with uniform density and minimal . A widely adopted modern approach is CAD/CAM milling, which enables digital design and subtractive fabrication from partially crystallized blocks. These blocks undergo initial at around 500°C to form lithium metasilicate seeds, making them machinable in a "soft" state; milling then produces the desired geometry, followed by a firing at 840°C for 10–20 minutes to convert the structure to lithium disilicate (Li₂Si₂O₅) and densify the material. This method offers high precision and repeatability, with firing cycles optimized to achieve flexural strengths exceeding 400 . Emerging techniques include additive manufacturing, such as stereolithography-based of lithium disilicate glass or lithography-based manufacturing (LCM). In these processes, a photosensitive is layer-by-layer printed to form green bodies, which are then debound and post-sintered at temperatures up to 900–1000°C to fully crystallize the Li₂Si₂O₅ phase, enabling complex geometries with resolutions down to 25 μm. These methods show promise for customized production, though they require optimization to match the mechanical properties of traditional techniques. Post-processing finishing is essential for achieving optimal and performance. Surfaces are polished using burs and pastes to attain roughness values of 0.1–1 μm Ra, reducing bacterial adhesion and enhancing durability without compromising strength. Aesthetic customization involves and a final low-temperature firing (around 750–800°C) to fuse colors and glazes. Quality control in lithium disilicate processing relies on techniques like X-ray diffraction () to confirm the crystalline phase composition, ensuring the Li₂Si₂O₅ content exceeds 70% for reliable mechanical properties. This verification step detects deviations in , such as residual phases, which could affect clinical performance.

Applications

Dental restorations

Lithium disilicate is widely indicated for various dental restorations, including single crowns, veneers with thicknesses ranging from 0.3 to 1 mm, , bridges up to three units (with the second as the terminal ), and implant-supported crowns. These applications leverage its suitability for both - and implant-supported prosthetics, particularly in anterior and posterior regions where aesthetic demands are high. Key advantages in dentistry include its superior aesthetic matching to natural teeth due to high translucency and shade versatility, allowance for minimally invasive tooth preparation, and excellent bondability with resin cements facilitated by its silica content. Its flexural strength supports reliable performance in load-bearing areas without requiring extensive tooth reduction. The fabrication workflow typically begins with intraoral digital scanning to capture the preparation, followed by computer-aided design (CAD) of the restoration, milling from pre-crystallized blocks using CAD/CAM systems, crystallization firing at 840-850°C for about 10 minutes to achieve the final microstructure, and adhesive cementation after surface treatment with 5% hydrofluoric acid etching for 20 seconds and silane application. Clinical outcomes demonstrate high reliability, with survival rates of 94-98% at five years for crowns and veneers, and low incidence of 1-2% in monolithic forms over extended follow-up periods up to eight years. These rates reflect robust performance in both anterior and posterior applications, with minimal complications such as chipping or debonding when properly bonded. Lithium disilicate exhibits excellent , showing no toward and promoting favorable responses with low plaque retention compared to . It supports epithelial cell and proliferation without and contributes to periodontal health by facilitating healthy gingival adaptation around restorations.

Industrial and other uses

Lithium disilicate serve as non-conductive seals and enamels in , particularly for bonding with nickel-based superalloys and stainless steels in high-temperature environments up to 1050°C, forming seals through interfacial that match coefficients. These applications leverage the material's high electrical resistivity and ability to create strong bonds (up to 14,000 ) without deleterious at the interface. In electronics, lithium disilicate acts as an insulator for sealing to metal substrates, supporting thermal management in components like hard disk drives due to its thermal expansion of approximately 105 × 10⁻⁷ K⁻¹ and chemical stability in harsh environments. It is also employed in bioremediation filters, where its biocompatibility and resistance to degradation enable effective pollutant capture without leaching harmful substances. Emerging applications include smart terminal display windows, utilizing the material's optical transparency and mechanical strength for durable, high-clarity interfaces in consumer electronics. Beyond dentistry, bioactive variants with rod-shaped crystals (aspect ratio 4:1) are explored for coatings on medical implants, promoting bone tissue engineering through enhanced regeneration properties. Key advantages encompass high thermal shock resistance from its tough microstructure, enabling survival in fluctuating temperatures, and excellent compatibility with metal substrates for reliable in . However, industrial adoption remains less widespread than dental uses due to elevated production costs and the need for specialized precision manufacturing.

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