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Engineering Materials

Instructions:

Answer 50 questions in 15 minutes.
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Match each statement with the correct term.
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This is a study tool. The 3 wrong answers for each question are randomly chosen from answers to other questions. So, you might find at times the answers obvious, but you will see it re-enforces your understanding as you take the test each time.

1. Flaws and Defects - They concentrate stress locally to levels high enough to rupture bonds.
Critical Properties of Superconductive Materials
Superconductivity
Why materials fail in service
Dependence of Heat Capacity on Temperature

2. Allows flow of electrons in one direction only (useful to convert alternating current to direct current) - Result: no net current flow
Electrical Conduction
IC Devices: P-N Rectifying Junction
Metallization
4 Types of Magnetism

3. Created by current through a coil N= total number of turns L= length of turns (m) I= current (ampere) H= applied magnetic field (ampere-turns/m) Bo= magnetic flux density in a vacuum (tesla)
Plastic Deformation (Metals)
Generation of a Magnetic Field - Vacuum
Critical Properties of Superconductive Materials
Translucent

4. Becomes harder (more strain) to stretch (elongate)
Impact - Toughness
Large Hardness
Work Hardening
Incoherent

5. High toughness; material resists crack propagation.
Luminescence
High impact energy
Elastic Deformation
Two kinds of Reflection

6. Degree of opacity depends on size and number of particles - Opacity of metals is the result of conduction electrons absorbing photons in the visible range.
Thermal Shock Resistance
Stages of Failure: Ductile Fracture
Plastic Deformation (Metals)
Opacity

7. They are used to assess properties of ceramics & glasses.
Superconductivity
Ductile-to-Brittle Transition
M is known as what?
Bending tests

8. Defines the ability of a material to resist fracture even when a flaw exists - Directly depends on size of flaw and material properties - K(ic) is a materials constant
Stages of Failure: Ductile Fracture
Stress Intensity Factor
Hysteresis and Permanent Magnetization
Magnetic Storage Media Types

9. The ability of a material to be rapidly cooled and not fracture
Specific Heat
Conduction & Electron Transport
Thermal Shock Resistance
Large Hardness

10. 1. Ability of the material to absorb energy prior to fracture 2. Short term dynamic stressing - Car collisions - Bullets - Athletic equipment 3. This is different than toughness; energy necessary to push a crack (flaw) through a material 4. Useful in
Stress Intensity Factor
Thermal Expansion: Symmetric curve
Thermal Stresses
Impact - Toughness

11. Measures impact energy 1. Strike a notched sample with an anvil 2. Measure how far the anvil travels following impact 3. Distance traveled is related to energy required to break the sample 4. Very high rate of loading. Makes materials more "brittle."
Charpy or Izod test
Incoherent
Brittle Fracture
Luminescence

12. Liquid polymer at room T - sandwiched between two sheets of glass - coated with transparent - electrically conductive film. - Character forming letters/ numbers etched on the face - Voltage applied disrupts the orientation of the rod- shaped molecule
How an LCD works
Engineering Fracture Performance
Refraction
Hardness

13. Measures Hardness - No major sample damage - Each scales runs to 130 but only useful in range 20-100 - Minor load is 10 kg - Major load: 60 kg (diamond) - 100 kg (1/16 in. ball) - 150 kg (diamond)
Electrical Conduction
Where does DBTT occur?
Rockwell
Force Decomposition

14. Cp: Heat capacity at constant pressure Cv: Heat capacity at constant volume.
Coefficient of Thermal Expansion
Refraction
Valence band
Two ways to measure heat capacity

15. For a metal - there is no ______ - only reflection
Stress Intensity Factor
Hysteresis and Permanent Magnetization
Refraction
How an LCD works

16. Occur when lots of dislocations move.
Slip Bands
Luminescence examples
Metallization
Incoherent

17. Not ALL the light is refracted - SOME is reflected. Materials with a high index of refraction also have high reflectance - High R is bad for lens applications - since this leads to undesirable light losses or interference.
Soft Magnetic Materials
Slip Bands
Reflectance of Non-Metals
Iron-Silicon Alloy in Transformer Cores

18. 1. General yielding occurs if flaw size a < a(critical) 2. Catastrophic fast fracture occurs if flaw size a > a(critical)
There is no perfect material?
Engineering Fracture Performance
Fatigue
Transparent

19. Dimples on fracture surface correspond to microcavities that initiate crack formation.
Pure Semiconductors: Conductivity vs. T
Color
Ductile Fracture
Stages of Failure: Ductile Fracture

20. Light Amplification by Stimulated Emission of Radiation
Response to a Magnetic Field
Domains in Ferromagnetic & Ferrimagnetic Materials
LASER
Magnetic Storage Media Types

21. 1. Hard disk drives (granular/perpendicular media) 2. Recording tape (particulate media)
Meissner Effect
Magnetic Storage Media Types
Thermal Expansion: Asymmetric curve
Ductile Fracture

22. (sigma)=F/Ai (rho)=(rho)'(1+(epsilon))
True Stress
The Transistor
Metals: Resistivity vs. T - Impurities
There is no perfect material?

23. Impurities added to the semiconductor that contribute to excess electrons or holes. Doping = intentional impurities.
Extrinsic Semiconductors
Metals: Resistivity vs. T - Impurities
Reflectance of Non-Metals
The Transistor

24. Large coercivities - Used for permanent magnets - Add particles/voids to inhibit domain wall motion - Example: tungsten steel
Generation of a Magnetic Field - Within a Solid Material
Thermal expansion
Opacity
Hard Magnetic Materials

25. Occur due to: restrained thermal expansion/contraction -temperature gradients that lead to differential dimensional changes sigma = Thermal Stress
How to gage the extent of plastic deformation
Thermal Stresses
Internal magnetic moments
Not severe

26. Growth of an oxide layer by the reaction of oxygen with the substrate - Provides dopant masking and device isolation - IC technology uses 1. Thermal grown oxidation (dry) 2. Wet Oxidation 3. Selective Oxidation
Oxidation
Etching
Where does DBTT occur?
Stress Intensity values

27. Without passing a current a continually varying magnetic field will cause a current to flow
Incoherent
Ductile Materials
Response to a Magnetic Field
Conduction & Electron Transport

28. 1. Tensile (opening) 2. Sliding 3. Tearing
Holloman Equation
The three modes of crack surface displacement
Refraction
Transparent

29. 1. Metals: Thermal energy puts many electrons into a higher energy state. 2. Energy States: Nearby energy states are accessible by thermal fluctuations.
Fourier's Law
Conduction & Electron Transport
Charpy or Izod test
Impact energy

30. Increase temperature - no increase in interatomic separation - no thermal expansion
Scattering
Color
Extrinsic Semiconductors
Thermal Expansion: Symmetric curve

31. - A magnetic field is induced in the material B= Magnetic Induction (tesla) inside the material mu= permeability of a solid
Generation of a Magnetic Field - Within a Solid Material
Refraction
Fatigue
Hard Magnetic Materials

32. Is analogous to toughness.
Brittle Fracture
How to gage the extent of plastic deformation
Impact energy
Modulus of Rupture (MOR)

33. To build a device - various thin metal or insulating films are grown on top of each other - Evaporation - MBE - Sputtering - CVD (ALD)
Film Deposition
IC Devices: P-N Rectifying Junction
Generation of a Magnetic Field - Within a Solid Material
True Stress

34. Failure under cyclic stress 1. It can cause part failure - even though (sigma)max < (sigma)c 2. Causes ~90% of mechanical engineering failures.
Fatigue
Generation of a Magnetic Field - Within a Solid Material
Hard Magnetic Materials
Domains in Ferromagnetic & Ferrimagnetic Materials

35. 1. Ductility- % elongation - % reduction in area - may be of use in metal forming operations (e.g. - stretch forming). This is convenient for mechanical testing - but not very meaningful for most deformation processing. 2. Toughness- Area beneath str
Impact - Toughness
Thermal Expansion: Asymmetric curve
Linewidth
How to gage the extent of plastic deformation

36. 1. Electron motions 2. The spins on electrons - Net atomic magnetic moment: sum of moments from all electrons.
What do magnetic moments arise from?
Why do ceramics have larger bonding energy?
Critical Properties of Superconductive Materials
There is no perfect material?

37. Another optical property - Depends on the wavelength of the visible spectrum.
Color
Thermal expansion
Refraction
Force Decomposition

38. Undergo little or no plastic deformation.
High impact energy
Brittle Materials
What do magnetic moments arise from?
Griffith Crack Model

39. - The emission of light from a substance due to the absorption of energy. (Could be radiation - mechanical - or chemical energy. Could also be energetic particles.) - Traps and activator levels are produced by impurity additions to the material - Whe
Luminescence
Conduction & Electron Transport
Thermal Conductivity
Brittle Materials

40. Ohms Law: voltage drop = current * resistance
Electrical Conduction
Dependence of Heat Capacity on Temperature
Ductile Materials
Thermal Expansion: Symmetric curve

41. Energy is stored as atomic vibrations - As temperature increases - the average energy of atomic vibrations increases.
Influence of Temperature on Magnetic Behavior
Heat Capacity from an Atomic Prospective
Luminescence
Charpy or Izod test

42. Sigma=ln(li/lo)
True Strain
Hard Magnetic Materials
Diamagnetic Materials
Two ways to measure heat capacity

43. Width of smallest feature obtainable on Si surface
Thermal Expansion: Symmetric curve
Coherent
Linewidth
There is no perfect material?

44. Undergo extensive plastic deformation prior to failure.
Impact - Toughness
Heat Capacity from an Atomic Prospective
Coefficient of Thermal Expansion
Ductile Materials

45. These materials are relatively unaffected by magnetic fields.
Diamagnetic Materials
Energy States: Insulators and Semiconductors
Thermal Conductivity
Pure Semiconductors: Conductivity vs. T

46. With Increasing temperature - the saturation magnetization diminishes gradually and then abruptly drops to zero at Curie Temperature - Tc.
Impact energy
Influence of Temperature on Magnetic Behavior
The Transistor
Heat Capacity from an Atomic Prospective

47. Growing interconnections to connect devices -Low electrical resistance - good adhesion to dielectric insulators.
Luminescence
LASER
Etching
Metallization

48. If a material has ________ - then the field generated by those moments must be added to the induced field.
Pure Semiconductors: Conductivity vs. T
Metals: Resistivity vs. T - Impurities
Reflectance of Non-Metals
Internal magnetic moments

49. These are liquid crystal polymers- not your normal "crystal" -Rigid - rod shaped molecules are aligned even in liquid form.

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50. 1. Necking 2. Cavity formation 3. Cavity coalescence to form cracks 4. Crack propagation (growth) 5. Fracture
Intrinsic Semiconductors
Stages of Failure: Ductile Fracture
Insulators
How to gage the extent of plastic deformation