Basic Science for Dental Materials PDF

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SuperiorAntigorite4686

Uploaded by SuperiorAntigorite4686

LMU College of Dental Medicine

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dental materials dental science materials science dentistry

Summary

This document details the basic science behind dental materials, encompassing their properties, mechanical and chemical tests, and degradation processes. It's a foundational resource for understanding the materials used in dentistry.

Full Transcript

Basic Science for Dental Materials • Fauchard proposed the use of porcelain • G.V Black published the first study of the properties of amalgam The 3 solids: • ceramics: ionic bond (e.g crystalline and amorphous form, also glass) • metals: metallic bond • molecular solids: covalent, secondary bonds,...

Basic Science for Dental Materials • Fauchard proposed the use of porcelain • G.V Black published the first study of the properties of amalgam The 3 solids: • ceramics: ionic bond (e.g crystalline and amorphous form, also glass) • metals: metallic bond • molecular solids: covalent, secondary bonds, polymers The 3 principle types of stress: • tensile • compressive • shear Stress • force per unit cross-sectional area that is acting on a material Strain • fractional change in the dimensions caused by force The 8 Mechanical Properties • Elastic Limit and Plastic Flow o Point where material exceed elastic limit, begin permanent deformation o Material does not return to normal shape after stress removed • Young’s Elastic Modulus: Modulus of elasticity • Fracture Strength: Ability of material to resist propagation of a preformed crack • Yield Stress and Proof Stress: Restoration will permanently deform if tensile stress exceeds yield stress (e.g. 3 unit metal bridge) • Fracture Toughness: Stress required to break material • Ultimate Tensile Strength: Max stress that specimen can withstand • Ductility: Amount of plastic strain produced in specimen at point of fracture • Resilience and Toughness: Amount of energy a material can absorb without any permanent deformation Mechanical Tests • Tensile Test o Material is stretched and recovery of normal dimensions noted • Compression test o Sample is compressed • Hardness Test o Resistance of material to an indenter or cutting tool • Impact Test o Resistance of material to application of load • Fatigue Test o Materials subjected to fluctuating stresses rather than static loads • Creep Test o Influence of constant stress that will eventually lead to material fracture Physical Properties • Rheological Properties (flow of materials) o Viscosity § As substance flows under force bonds, chemical bonds are broken and remade to form resistance flow o Thixotropy § Molecular rearrangement from agitation/mixing § Longer mixing at shear rate = lower shear stress and lower viscosity o Viscoelasticity § Solids showing capacity to rearrange molecules under applied load, when load released the material may/may not return to original shape • Thermal Properties (influence hot/cold sensation; cause mechanical failure from expansion/contraction) o Thermal conductivity § Ease of heat transference through material o Specific Heat § Heat energy required to raise temp of unit volume by one degree centigrade o Thermal Diffusivity § Rate of rise of temperature at one point due to a heat source at another point o Thermal Expansion § Ideal restorative material will have coefficient of expansion identical to that of tooth tissue bc thermal mismatch could give rise to marginal gap formation and breakdown of adhesive bonds • Optical Properties (the light source, the object, and the observer) o Color § Eye most sensitive to green-yellow, least sensitive to red/blue § Chroma = strength of hue (how vivid color is) § Value = brightness/darkness of object, black and white for diffusive/reflective objects and black to clear for translucent objects o Translucency § Allows passage of light in such a way that little distortion takes place o Surface Texture § As surface gets rougher, light scatters and gives matte appearance § restored tooth can be spoiled by the restoration having a matte surface finish, making it stand out from the rest of the tooth Chemical Properties • • • • • • oral environment very hostile materials may dissolve in the water present in saliva, or release soluble components corrosion may tarnish due to acid presence Materials may discolor or break down due to absorption of substances from saliva These possibilities can adversely affect the chemical stability of the materials and limit their durability The products released may have an adverse effect on the biological environment, both locally and systemically Degradation of Polymers • Water sorption and soluble fraction o Solvent molecule forces the polymer chains apart, causing swelling. o As strength of bond decreases, the polymer becomes softer, the glass transition temperature is reduced and strength is lowered o Effects properties of Nylon, Soft denture liners and GI cements • Bond rupture o Scission: degradation of covalent bonds in polymers o from radiation, heat, chemical attack Degradation of Ceramics • Resistant to electrochemical corrosion • Susceptible to chemical corrosion Tarnish and Corrosion of Metals • Tarnish o Surface discoloration from formation of hard/soft deposits (e.g. sulfides, chlorides) o Tarnish DOES NOT cause deterioration of material itself o Ugly but easily removed from surface by polishing the metal • Corrosion o Chemical rxn between material and environment (more serious than tarnish) o Decrease in free energy as metal reacts with liquid or gas § In metals, corrosion process is electrochemical via oxidation reduction o Types of corrosion: § Dry Corrosion: All metals will form surface oxide coating when in contact w oxygen in air (NOT gold and other noble metals) § Wet Corrosion: Takes place in neutral, acid or alkaline environments. Metal ions and electrons released into water § Galvanic Corrosion: two dissimilar metals combined resulting in corrosion of one of the metals is increased § Crevice Corrosion — metal ions are released into space forming corrosion products — electrons are unable to react because of the lack of oxygen — electrons travel thru metal to get to oxygen for oxidative reduction, pick up crevice anode and cathode — material lost from crevice based, metal weakness — damage done out of proportion to amount of material destroyed in corrosion process — localized corrosion is MORE DANGEROUS than uniform

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