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Engineering Materials

Instructions:

Answer 50 questions in 15 minutes.
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Match each statement with the correct term.
Don't refresh. All questions and answers are randomly picked and ordered every time you load a test.

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. Light Amplification by Stimulated Emission of Radiation
LASER
Hardness
Thermal Conductivity
Charpy or Izod test

2. Diffuse image
High impact energy
Hysteresis and Permanent Magnetization
Translucent
Fatigue

3. 1. General yielding occurs if flaw size a < a(critical) 2. Catastrophic fast fracture occurs if flaw size a > a(critical)
Engineering Fracture Performance
Luminescence examples
Why materials fail in service
Impact - Toughness

4. 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.
True Stress
Opacity
Valence band
Metallization

5. Emitted light is in phase
Coherent
Metals: Resistivity vs. T - Impurities
Influence of Temperature on Magnetic Behavior
Etching

6. There is always some statistical distribution of flaws or defects.
Incoherent
M is known as what?
Thermal expansion
There is no perfect material?

7. Superconductors expel magnetic fields - This is why a superconductor will float above a magnet.
Griffith Crack Model
Liquid Crystal Displays (LCD's)
Meissner Effect
Paramagnetic Materials

8. The ability of a material to absorb heat - Quantitatively: The energy required to produce a unit rise in temperature for one mole of a material.
Insulators
Why fracture surfaces have faceted texture
Heat Capacity
Incoherent

9. 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."
Dependence of Heat Capacity on Temperature
Hard Magnetic Materials
Charpy or Izod test
Impact - Toughness

10. Because of ionic & covalent-type bonding.
Why do ceramics have larger bonding energy?
Luminescence
Fatigue
Iron-Silicon Alloy in Transformer Cores

11. Cracks propagate along grain boundaries.
Reflection of Light for Metals
Intergranular Fracture
Thermal Stresses
Large Hardness

12. Without passing a current a continually varying magnetic field will cause a current to flow
Dependence of Heat Capacity on Temperature
Response to a Magnetic Field
Shear and Tensile Stress
Linewidth

13. 1. Necking 2. Cavity formation 3. Cavity coalescence to form cracks 4. Crack propagation (growth) 5. Fracture
Why do ceramics have larger bonding energy?
Hard Magnetic Materials
Critical Properties of Superconductive Materials
Stages of Failure: Ductile Fracture

14. Ability to transmit a clear image - The image is clear.
Valence band
Transparent
Influence of Temperature on Magnetic Behavior
Relative Permeability

15. 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)
Generation of a Magnetic Field - Vacuum
Where does DBTT occur?
Translucent
Extrinsic Semiconductors

16. For a metal - there is no ______ - only reflection
Valence band
The three modes of crack surface displacement
Refraction
HB (Brinell Hardness)

17. If a material has ________ - then the field generated by those moments must be added to the induced field.
Griffith Crack Model
Internal magnetic moments
Generation of a Magnetic Field - Within a Solid Material
Magnetic Storage Media Types

18. 1. Insulators: Higher energy states NOT ACCESSIBLE due to gap 2. Semiconductors: Higher energy states separated by a smaller gap.
Two kinds of Reflection
Incident Light
Energy States: Insulators and Semiconductors
Heat Capacity

19. 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
Impact - Toughness
Iron-Silicon Alloy in Transformer Cores
Fourier's Law
Slip Bands

20. These materials are "attracted" to magnetic fields.
Shear and Tensile Stress
Not severe
Domains in Ferromagnetic & Ferrimagnetic Materials
Paramagnetic Materials

21. Elastic means reversible! This is not a permanent deformation.
Coherent
Hardness
Elastic Deformation
IC Devices: P-N Rectifying Junction

22. Transmitted light distorts electron clouds - The velocity of light in a material is lower than in a vacuum - Adding large ions to glass decreases the speed of light in the glass - Light can be "bent" (or refracted) as it passes through a transparent
Refraction
Elastic Deformation
Internal magnetic moments
Influence of Temperature on Magnetic Behavior

23. Second phase particles with n > glass.
How to gage the extent of plastic deformation
LASER
Brittle Fracture
Opacifiers

24. Impurities added to the semiconductor that contribute to excess electrons or holes. Doping = intentional impurities.
Incoherent
Extrinsic Semiconductors
The three modes of crack surface displacement
Not severe

25. 1. Stress-strain behavior is not usually determined via tensile tests 2. Material fails before it yields 3. Bend/flexure tests are often used instead.
Brittle Ceramics
Color
Soft Magnetic Materials
Opacifiers

26. 1. Fluorescent Lamp - tungstate or silicate coating on inside of tube emits white light due to UV light generated inside the tube. 2. TV screen - emits light as electron beam is scanned back and forth.
Hardness
Refraction
Luminescence examples
Stress Intensity Factor

27. Heat capacity.....- increases with temperature -for solids it reaches a limiting value of 3R
Opaque
Superconductivity
Where does DBTT occur?
Dependence of Heat Capacity on Temperature

28. 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)
Refraction
To improve fatigue life
Diamagnetic Materials
Rockwell

29. 1. Imperfections increase resistivity - grain boundaries - dislocations - impurity atoms - vacancies 2. Resistivity - increases with temperature - wt% impurity - and %CW
4 Types of Magnetism
Electrical Conduction
Metals: Resistivity vs. T - Impurities
Linewidth

30. Sigma=ln(li/lo)
True Strain
Lithography
True Stress
Opacifiers

31. A high index of refraction (n value) allows for multiple internal reactions.
Sparkle of Diamonds
High impact energy
Incident Light
Luminescence examples

32. Allows flow of electrons in one direction only (useful to convert alternating current to direct current) - Result: no net current flow
Work Hardening
IC Devices: P-N Rectifying Junction
Soft Magnetic Materials
Superconductivity

33. Occur when lots of dislocations move.
Slip Bands
How to gage the extent of plastic deformation
Oxidation
There is no perfect material?

34. Is reflected - absorbed - scattered - and/or transmitted: Io=It+Ia+Ir+Is
Two kinds of Reflection
Incident Light
Opaque
Insulators

35. Measures Hardness 1. psia = 500 x HB 2. MPa = 3.45 x HB
Diamagnetic Materials
Dependence of Heat Capacity on Temperature
HB (Brinell Hardness)
The Transistor

36. The Magnetization of the material - and is essentially the dipole moment per unit volume. It is proportional to the applied field. Xm is the magnetic susceptibility.
Ductile Materials
Thermal Expansion: Asymmetric curve
M is known as what?
Luminescence examples

37. Digitalized data in the form of electrical signals are transferred to and recorded digitally on a magnetic medium (tape or disk) - This transference is accomplished by a recording system that consists of a read/write head - "write" or record data by
Specific Heat
Refraction
Magnetic Storage
Heat Capacity from an Atomic Prospective

38. Ohms Law: voltage drop = current * resistance
High impact energy
LASER
Engineering Fracture Performance
Electrical Conduction

39. # of thermally generated electrons = # of holes (broken bonds)
Intrinsic Semiconductors
Heat Capacity from an Atomic Prospective
Paramagnetic Materials
Generation of a Magnetic Field - Within a Solid Material

40. - A magnetic field is induced in the material B= Magnetic Induction (tesla) inside the material mu= permeability of a solid
Thermal expansion
Generation of a Magnetic Field - Within a Solid Material
To improve fatigue life
Large Hardness

41. 1. Metals: Thermal energy puts many electrons into a higher energy state. 2. Energy States: Nearby energy states are accessible by thermal fluctuations.
Stress Intensity values
Linewidth
Intergranular Fracture
Conduction & Electron Transport

42. Becomes harder (more strain) to stretch (elongate)
Work Hardening
Fatigue
Iron-Silicon Alloy in Transformer Cores
Incident Light

43. Rho=F/A - tau=G/A . Depending on what angle the force is applied - and what angle the crystal is at - it takes different amounts of force to induce plastic deformation.
What do magnetic moments arise from?
Shear and Tensile Stress
Refraction
Impact energy

44. heat flux = -(thermal conductivity)(temperature gradient) - Defines heat transfer by CONDUCTION

45. 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
Why do ceramics have larger bonding energy?
Oxidation
Why materials fail in service
Internal magnetic moments

46. - Metals that exhibit high ductility - exhibit high toughness. Ceramics are very strong - but have low ductility and low toughness - Polymers are very ductile but are not generally very strong in shear (compared to metals and ceramics). They have low
Stress Intensity values
Opacity
Transgranular Fracture
Not severe

47. Cracks pass through grains - often along specific crystal planes.
LASER
Specific Heat
Reflection of Light for Metals
Transgranular Fracture

48. - 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
Thermal expansion
Color
Thermal Conductivity
Luminescence

49. Stress concentration at a crack tips
Hysteresis and Permanent Magnetization
Griffith Crack Model
Thermal expansion
The three modes of crack surface displacement

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