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PHYSICAL PROPERTIES OF MATERIALS

PHYSICAL PROPERTIES OF MATERIALS. Volumetric and Melting Properties Thermal Properties Mass Diffusion Electrical Properties Electrochemical Processes. Physical Properties Defined.

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PHYSICAL PROPERTIES OF MATERIALS

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  1. PHYSICAL PROPERTIES OF MATERIALS Volumetric and Melting Properties Thermal Properties Mass Diffusion Electrical Properties Electrochemical Processes

  2. Physical Properties Defined - Physicalproperties: propertiesthat define the behavior of materials in response to physical forces other than mechanical, volumetric, thermal, electrical, electrochemical properties Components in a product must do more than withstand mechanical stresses. They must - conduct electricity (or prevent conduction), - allow heat to transfer (or allow its escape), - transmit light (or block transmission), - satisfy many other functions

  3. Physical Properties in Manufacturing - Physicalproperties: Important in manufacturing because physical properties often influence process performance - In machining, thermal properties of the work material determine cutting temperature, which affects tool life - In microelectronics, electrical properties of silicon and how these properties can be altered by chemical and physical processes is the basis of semiconductor manufacturing

  4. 1) VOLUMETRIC AND MELTING PROPERTIES Properties related to the volume of solids and how these properties are affected by temperature a) Density b) Melting Characteristics for Elements

  5. a) Density and Specific Gravity Density(yoğunluk) = weight per unit volume symbol = r Typical units are g/cm3 (lb/in3) Determined by atomic number and other factors such as atomic radius, and atomic packing. Specific gravity (özgül ağırlık) = density of a material relative to density of water Since it is a ratiowithsameunits, it has no units

  6. Why Density is Important - Density (yoğunluk) is an important consideration in the selection of a material for a givenapplication, but it is generally not the only property of interest. Strength (sağlamlık, dayanıklılık) is also important, The two properties are often related in a strength-to-weight ratio, which is the tensilestrength of thematerial divided by its density. - The ratio is useful in comparing materials forstructural applications in aircraft, automobiles, and other products in which weight andenergyare of concern.

  7. b) Melting Characteristics for Elements Melting point Tmof a pure element = temperature at which it transforms from solid to liquid state The reverse transformation occurs at the same temperature and is called the freezing point

  8. Melting of Metal Alloys - Unlike pure metals, most alloys do not have a single melting point Instead, melting begins at a temperature called the solidus and continues as temperature increases until converting completely to liquid at a temperature called the liquidus. Phase diagram for the nickel-copper alloy system

  9. Melting of Metal Alloys Between the two temperatures, the alloy is a mixture of solid and molten metals Exception: eutectic alloys melt (and freeze) at a single temperature Phase diagram for the nickel-copper alloy system

  10. Changes in volume per unit weight as a function of temperature for a hypothetical pure metal, alloy, and glass Volume-to-Weight Changes

  11. Melting of Noncrystalline Materials - In noncrystalline materials (glasses), a gradual transition from solid to liquid states occurs - The solid material gradually softens as temperature increases, finally becoming liquid at the melting point - During softening, the material has a consistency of increasing plasticity (increasingly like a fluid) as it gets closer to the melting point

  12. Importance of Melting inManufacturing - Metal casting - the metal is melted and then poured into a mold cavity - Metals with lower melting points are generally easier to cast , but if the melting temperature is too low, themetal loses its applicability as an engineering material. - Plastic molding - melting characteristics of polymers are important in nearly all polymer shaping processes - Sintering of powdered metals - sintering does not melt the metal, but temperatures must approach the melting point to achieve bonding of the powders

  13. 2) THERMAL PROPERTIES a) Thermal expansion (ısısal genleşme), b) Heat of fusion (erime ısısı) are thermal properties because temperature determines the thermal energy level of the atoms, leading to the changes in materials Additional thermal properties: c) Specific heat (özgül ısı) d)Thermal conductivity (ısısal iletkenlik) These properties relate to the storage and flow of heat within a substance

  14. a) Thermal Expansion - The density of a material is a function of temperature. The general relationship is thatdensity decreases with increasing temperature. Thermal expansion (ısısal genleşme) is the name given to this effect thattemperature has on density. It is usually expressed as the coefficient of thermal expansion, which measures the change in length per degree of temperature, asmm/mm/C(in/in/F).

  15. Coefficient of Thermal Expansion

  16. Coefficient of Thermal Expansion - Itis a length ratio rather than a volume ratio because this is easier to measure and apply. - It is the changein length for a given temperature change: L2 ‑ L1 = L1(T2 ‑ T1) where = coefficient of thermal expansion; L1(initial)and L2(final)are lengths (in mm), T1(initial) and T2(final)(oC)corresponding temperaturesrespectively

  17. Coefficient of Thermal Expansion - Forsome materials values, coefficient of thermal expansion increases with temperature; for other materials it decreases. - Valueslikethose in the table givenare quite useful in design calculations for the range of temperatures consideredin service. - Changes in the coefficient are more important when the metal experiences aphase transformation, such as fromsolid to liquid, or fromone crystal structure to another.

  18. Thermal Expansion in Manufacturing Thermal expansion is used in shrink fit and expansion fit assemblies - Part is heated to increase size or cooled to decrease size to permit insertion into another part - When part returns to ambient temperature, a tightly‑fittedassembly is obtained Thermal expansion can be a problem in heat treatment and welding due to thermal stresses that develop in material during these processes

  19. b) Heat of Fusion Heat of fusion : heat energy required at Tm to accomplish transformation from solid to liquid

  20. c) Specific Heat The specific heat (C)of a material is defined as the quantity of heat energy required toincrease the temperature of a unit mass of the material by one degree. To determine the energy (H) to heat a certain weight of metal to a given temperature: H = C W (T2 ‑ T1) where H= amount of heat energy (heatcapacity) (J); C= specific heat of the material (J / kg oC); W= its weight (kg); (T2 ‑ T1) = change in temperature (oC)

  21. Volumetric Specific Heat Density multiplied by specific heat C Volumetric specific heat = C The quantity of heat energy required to raise the temperature of a unit volume of material by one degree

  22. d) Thermal Conductivity - Conduction is a fundamental heat-transfer process. It involves transfer of thermalenergy within a material frommolecule tomolecule by purely thermal motions; no transfer ofmass occurs. - The thermal conductivity of a substance is therefore its capability to transferheat through itself by this physical mechanism. - No mass transfer - It is measured by the coefficient of thermalconductivity (k), which has typical units of J/s mm C (Btu/in hr F). - Coefficient of thermal conductivity k is generally high in metals, low in ceramics and plastics Units for k:J/s mm C (Btu/in hr F)

  23. Thermal Diffusivity The ratio of thermal conductivity (k) to volumetric specific heat(C ) is frequently facedin heat transfer analysis. It is called the thermal diffusivity (K) and is determined as Where K = thermal diffusivity k = coefficient of thermalconductivity r = density c = specificheat

  24. Thermal Properties in Manufacturing - Thermal properties play an important role in manufacturing because heat generation iscommon in so many processes. - In some cases heat is the energy that completesthe process; in others heat is generated as a result of the process. Specific heat is of interest for several reasons. In processes that require heating of thematerial (e.g., casting, heat treating, and hot metal forming), specific heat determines theamount of heat energy needed to raise the temperature to a desired level. - In other cases, heat is generated as a result of the process (cold forming and machining of metals) (coolingoftenused, mostlywithwater – highheatcarryingcapacity)

  25. 3) MASS DIFFUSION - In addition to heat transfer in amaterial, there is alsomass transfer. - As well as in gasesandliquids, massdiffusion occurs in pure metals, in alloys, andbetween materials that share a common interface. - MassDiffusion: movementof atoms or molecules within a material or across a boundary between two materials in contact - Because of thermal agitation of the atoms in a material (solid, liquid, or gas), atoms are continuously moving about - In metals, atomic motion is facilitated by vacancies and other imperfections in the crystal structure

  26. Mass Diffusion Two blocks brought into contact: at first, each block has its own composition; after time, an exchange of atoms begins; finally, uniform concentration occurs (1) (2)(3)

  27. Mass Diffusion Concentration gradients for metal A during diffusion of metal A into metal B each block has its own composition; exchange of atoms begins; uniform concentration occurs (1)(2)(3)

  28. The concentration gradient is plotted in Figure (2)to correspond to the instantaneous distribution of atoms in the assembly. The relationshipoften used to describe mass diffusion is Fick’s first law: dm = - D (dc / dx) where dm = small amount of material transferred, D= diffusion coefficient (diffusivity) of the metal, dc / dx= concentration gradient, Mass Diffusion

  29. Mass Diffusion in Manufacturing - Surface hardening treatments based on diffusion include carburizing and nitriding - Diffusion welding - used to join two components by pressing them together and allowing diffusion to occur across boundary to create a permanent bond - Diffusion is also used in electronics manufacturing to alter the surface chemistry of a semiconductor chip in very localized regions to create circuit details

  30. 4) ELECTRICAL PROPERTIES Engineering materials exhibit a great variation in their capability to conduct electricity Flow of electrical current involves movement of charge carriers ‑ infinitesimally small particles possessing an electrical charge - In solids, these charge carriers are electrons - In a liquid solution, charge carriers are positive and negative ions

  31. Electrical Properties Movement of charge carriers is driven by the presence of electric voltage andresisted by the inherent characteristics of the material, such as atomic structure and bonding between atoms and molecules. This is the familiar relationship defined by Ohm’s law Ohm's law: I= where I= current, (A), E= voltage, (V), R= electrical resistance, ()

  32. Electrical Resistance Resistance (R)in a uniform section of material (e.g., a wire) is givenbytheequatio or r = resistivity of the material L = length A = cross‑sectional area where resistivity r has units of ‑m2/m or ‑m (‑in.)

  33. Conductivity Often more convenient to consider a material as conducting electrical current rather than resisting its flow Conductivity of a material is simply the reciprocal of resistivity: Electrical conductivity = where conductivity has units of (‑m)‑1 or (‑in)‑1

  34. Materials and Electrical Properties - Metals are the best conductors of electricity, because of their metallic bonding - Most ceramics and polymers, whose electrons are tightly bound by covalent and/or ionic bonding, are poor conductors - Many of these materials are used as insulators because they possess high resistivities

  35. Superconductors - In addition to conductors and insulators (or dielectrics), there are also superconductorsand semiconductors. - Asuperconductor is a material that exhibits zero resistivity. - Itis a phenomenon that has been observed in certain materials at low temperaturesapproaching absolute zero. - These superconductingmaterials areof great scientific interest. - If materials could be developed that exhibitthis property at more normal temperatures, there would be significant practical implicationsin power transmission, electronic switching speeds, and magnetic field applications.

  36. Semiconductors Application of semiconductorsrangefrom mainframe computers to household appliances and automotive engine controllers. A semiconductor is a material whose resistivity lies between insulators and conductors Most common semiconductor material is silicon, largely because of its abundance in nature, relative low cost, and ease of processing. What makes semiconductors unique is the capacity to significantly alter conductivities. Theyarewidelyusedto fabricate integrated circuits

  37. Semiconductor Video 1-2

  38. 5)ELECTROCHEMISTRY - Field of science concerned with the relationship between electricity and chemical changes, and the conversion of electrical and chemical energy - In a water solution, molecules of an acid, base, or salt are dissociated into positively and negatively charged ions - Ions are the charge carriers in the solution - They allow electric current to be conducted, playing the same role that electrons play in metallic conduction

  39. Terms in Electrochemical Processes Electrolyte - the ionized solution Electrodes – where current enters and leaves the solution in electrolytic conduction Anode - positive electrode Cathode - negative electrode - The whole arrangement is called an electrolytic cell - At each electrode, some chemical reaction occurs, such as thedeposition or dissolution of material, or the decomposition of gas from the solution. - Electrolysis is the name given to these chemical changes occurring in the solution.

  40. Electrolysis example: decomposition of water Electrolyte = dilute sulfuric acid (H2SO4) Electrodes = platinum and carbon (both chemically inert) Electrolysis Example

  41. Chemical Reactions in the Decomposition of Water Electrolyte dissociates into the ions H+ and SO4= H+ ions are attracted to negatively charged cathode. Upon reaching it they each acquire an electron and combine into molecules of hydrogen gas 2H+ + 2e  H2 (gas) The SO4= ions are attracted to the anode, transferring electrons to it to form additional sulfuric acid and liberate oxygen 2SO4= ‑ 4e + 2 H2O  2H2SO4 + O2 The product H2SO4 is dissociated into ions of H+ and SO4= again and so the process continues .

  42. Electrolysis in Manufacturing Processes Electrolysis is also used in several other industrial processes. Two examples are electroplating, an operation that adds a thin coating of onemetal (e.g., chromium) tothe surface of a second metal (e.g., steel) for decorative or other purposes; and Electrochemicalmachining, a process in whichmaterial is removedfromthesurface of a metal part. Boththeseoperationsrely on electrolysistoeitheraddor removematerialfromthesurface of a metal part.

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