en گروه سرامیک Ceramic Materials and Engineering Research Paper Research Paper <div style="text-align: justify;"><span style="font-size:11pt"><span style="line-height:200%"><span style="font-family:Calibri,sans-serif"><span style="font-size:12.0pt"><span style="line-height:200%"><span new="" roman="" style="font-family:" times="">This study investigates the crystallization behavior and microstructural evolution of lithium metasilicate (Li</span></span></span><span style="font-size:12.0pt"><span style="line-height:200%"><span cambria="" math="" style="font-family:">₂</span></span></span><span style="font-size:12.0pt"><span style="line-height:200%"><span new="" roman="" style="font-family:" times="">SiO</span></span></span><span style="font-size:12.0pt"><span style="line-height:200%"><span cambria="" math="" style="font-family:">₃</span></span></span><span style="font-size:12.0pt"><span style="line-height:200%"><span new="" roman="" style="font-family:" times="">) glass subjected to thermal histories designed to emulate the cooling stage of zirconia infiltration in dental restorations. Three thermal routes were examined: (i) a non-isothermal schedule to identify crystallization and melting events, (ii) a controlled isothermal schedule to obtain homogeneous glass&ndash;ceramic microstructures, and (iii) a quasi-isothermal natural cooling schedule from the molten state to mimic the thermal profile during infiltration without reproducing actual capillary flow or interfacial reactions. Phase identification and quantitative analysis were performed by X-ray diffraction with Rietveld refinement, and the resulting microstructures were characterized by field-emission scanning electron microscopy. Under isothermal conditions, lithium metasilicate (Li₂SiO₃), lithium disilicate (Li₂Si₂O₅), &gamma;-spodumene (</span></span></span><span style="line-height:200%"><span new="" roman="" style="font-family:" times="">&gamma;-</span></span><span style="font-size:12.0pt"><span style="line-height:200%"><span new="" roman="" style="font-family:" times="">LiAlSi₂O₆), &beta;-lithium phosphate (&beta;-Li₃PO₄), and quartz crystallized with an overall crystallized fraction of approximately 62</span></span></span><span dir="RTL" lang="AR-SA" new="" roman="" style="font-family:" times="">&plusmn;</span><span new="" roman="" style="font-family:" times="">0.9</span><span style="font-size:12.0pt"><span style="line-height:200%"><span new="" roman="" style="font-family:" times=""> wt.%. In contrast, quasi-isothermal cooling produced a crystallized fraction exceeding </span></span></span><span new="" roman="" style="font-family:" times="">87&plusmn;1 </span><span style="font-size:12.0pt"><span style="line-height:200%"><span new="" roman="" style="font-family:" times="">wt.%, dominated by lithium metasilicate (Li</span></span></span><span style="font-size:12.0pt"><span style="line-height:200%"><span cambria="" math="" style="font-family:">₂</span></span></span><span style="font-size:12.0pt"><span style="line-height:200%"><span new="" roman="" style="font-family:" times="">SiO</span></span></span><span style="font-size:12.0pt"><span style="line-height:200%"><span cambria="" math="" style="font-family:">₃</span></span></span><span style="font-size:12.0pt"><span style="line-height:200%"><span new="" roman="" style="font-family:" times="">), &beta;-lithium phosphate, quartz, and cristobalite, with neither lithium disilicate (Li₂Si₂O₅) nor &gamma;-spodumene (</span></span></span><span style="line-height:200%"><span new="" roman="" style="font-family:" times="">&gamma;-</span></span><span style="font-size:12.0pt"><span style="line-height:200%"><span new="" roman="" style="font-family:" times="">LiAlSi₂O₆) detected under the present XRD conditions. The quasi-isothermal route also generated significantly coarser morphologies: average crystal length and thickness were roughly 10-fold and 31-fold larger, respectively, than those in the isothermally treated sample. These results demonstrate that the thermal path strongly governs phase assemblage, crystallized volume fraction, and crystal morphology in lithium silicate glass&ndash;ceramics. By clarifying how controlled versus quasi-isothermal cooling histories shape the final microstructure, this work provides a structural basis for optimizing lithium silicate glasses used in zirconia infiltration technology and for guiding future studies on the mechanical and functional performance of these materials.</span></span></span></span></span></span><br> &nbsp;</div> Lithium metasilicate glass-ceramics, thermaltreatment pathways, microstructure, glass infiltration 109 122 http://ijmse.iust.ac.ir/browse.php?a_code=A-10-3897-3&slc_lang=en&sid=1 Mohsen Sadeghpour Motlagh mohsen.628@gmail.com 1800319475328460022068 1800319475328460022068 No Materials and Energy Research Center Sara Banijamali banijamali@merc.ac.ir 1800319475328460022069 1800319475328460022069 Yes Materials and Energy Research Center Bijan Eftekhari Yekta beftekhari@iust.ac.ir 1800319475328460022070 1800319475328460022070 No Iran University of Science and Technology