MAT E 273: Exam #2

Hooke's Law

(stress)=E(strain)

Types of Loading

*Tension (Pull) *Compression (Press) Shear (Shift) Torsion (Twisting)

HCP Slip System

1 distinct {001} planes in an HCP crystal. x 3 independent <1120> directions per {001} plane. ------------------------------------------------------ =3 independent slip systems

Dislocation Generation

1.) Generation of a surface step due to shear stress. 2.) Splitting of existing dislocations

Earth's 8 Big Elements Ranked By wt%

1.) Oxygen (O)- 46% 2.) Silicon (Si)- 27% 3.) Aluminum (Al)- 8% 4.) Iron (Fe)- 6% 5.) Calcium (Ca)- 5% 6.) Magnesium (Mg)- 2.9% 7.) Sodium (Na)- 2.3% 8.) Potassium (K)- 1.5%

Factors That Influence Fatigue

1.) Stress Amplitude 2.) Mean Stress

FCC Slip System

4 distinct {111} planes in an FCC crystal. x 3 distinct <110> directions per {111} plane. --------------------------------------------- =12 independent slip systems

BCC Slip System

6 distinct {110} planes in an BCC crystal. x 2 independent <111> directions per {110} plane. ---------------------------------------------------- =12 independent slip systems

Aluminum (Al)

8% of Earth's crust (most abundant metal in crust) Lighter than steel Great for casting (low melting temp, good fluidity) Soft/high ductility Good conductor of heat and electricity Relatively inexpensive Excellent corrosion resistance Aluminum alloys are superior to pure aluminum in terms of yield strength Pure aluminum is most ductile Prized for corrosion resistance Highly reflective

Sterling Silver

92.5 wt% Ag - 7.5 wt% Cu

Flaw Orientation

A flaw whose major axis is parallel with an applied tensile stress is likely to be inactive and possibly"healed" while the stress is applied. A flaw whose major axis is perpendicular to an applied tensile stress is likely to grow (propagate). Opposite for compression

Toughness

A measure of how much energy a material can absorb before fracture. Proportional to the area under the stress-strain curve up to fracture.

Ductility

A measure of how much plastic deformation a material can sustain before fracture. Higher the strain = higher ductility

Hardness

A measure of how well a material resists local indentation, abrasion, wear, etc. Given by σy or scratch / indention measures (Moh's Scale, Brinell, Rockwell, Vickers).

Stainless Steel

A metal alloy of steel, chromium(> 11 wt% Cr), and sometimes Ni and Mo which is used in casket construction; noted for its ability to resist rust. Hard to repair Work hardens

Magnesium (Mg)

A metal that is quite similar to aluminum, but is less ductile and highly susceptible to corrosion. Impurities such as Fe further reduce corrosion resistance 1/2 of Mg produced is alloyed with Aluminum

Bainite

A microstructure that consists of the ferrite and cementite phases ( α and Fe3C).

Titanium (Ti)

A relatively low-density but high-strength metal that has excellent corrosion resistance as a cool solid, but not as a very hot solid or liquid. The thermal conductivity of this metal is very low, making it difficult to machine since it doesn't effectively dissipate the heat produced at the cutting tool location. It's oxide is more commonly produced (approximately 60x more by weight). The identity of this oxide mineral is rutile.

Chromium (Cr)

A shiny metal that is completely brittle below 300 degrees C.It is added to steels to drastically improve their corrosion resistance. Austenite de-stabilizer.

Eutectic Point

A specific composition associated with a minimum melting temperature and useful solidification pathway

Fatigue

A specimen is subjected to dynamic or cyclic stresses. Cause: Localized pile-up of dislocations during cyclic straining. Effect: Local embrittlement as the cyclic loading proceeds.

Secondary Phase Strengthening

Additional phases (more crystallographic boundaries) will also impede dislocation motion.

Tensile Testing

Applies constant force to a material and measures the specimen's response to the stress.

IT Diagram

Applies to one composition and describes the time dependence of a phase transformation.

Ductile-to-Brittle Temperature Dependency

As temperature decreases, ductility and toughness decrease because bonds "seem" stronger since thermal energy doesn't act to weaken / break the bonds.

Yield Point

Beyond this point, some strain will be permanent in the material

Tempered Martensite

Briefly annealing martensite converting it from ultra-fine needles of BCT ferrite to very small spheres of cementite in BCC ferrite. A less brittle and ultra-fine spheroidite-like structure formed by annealing martensite to reduce internal stress / strain.

Alkali Metal Compound Applications

CO2 Scrubbers, Sode-Lime Glass, Lithium Ion Batteries, Chemical Strengthening of Glass - Ion Exchange, Na-K Eutectic Alloy Composition (Thermal Conductivity, High* Boiling Point, Low* Vapor Pressure *compared to water)

Slip System

Combination of slip plane and slip direction For systems that offer close-packed planes and close-packed directions, these will be preferred

Martensite

Diffusionless transformation. Transformation only depends of temperature. Any austenite that is quenched to room temperature transforms to martensite. Forms BCT phase, very brittle but strong. Formation of martensite is more difficult for higher carbon content steel

Dislocation and Strength Trade off

Dislocation motion needs to be easy for metals to be ductile, but strength is derived making dislocation motion difficult.

Slip

Dislocation movement/motion Slip allows a material to deform through incremental breaking of bonds (inch worm) Easy is metals, difficult in covalent/ionic systems

Steel Designations/Grades

Ex: 1045 Steel 10- Plain Carbon Steel 45- 0.45wt% C

Silver (Ag)

Excellent thermal and electrical conductivity Liquid Ag extremely soluble of oxygen Second most ductile metal behind Au Higher cost

Ductile Failure

Extensive gross plastic deformation or strain prior to failure. Crack growth is slow and non-catastrophic. Preferred over brittle failure.

Predicting Failure

Failure=cycles/time

Engineering Stress

Force divided by the original cross sectional area

Strain Hardening (Cold-working or work-hardening)

Generation of dislocations (and their subsequent interactions). The yield strength and tensile strength increase and ductility decreases.

Alkali Metals

Group 1 From Na on, a filled p shell shields the single valence electron very well, resulting in a weakly bound valence electron and extreme behavior: Easily ionized (reactive), Low melting / boiling points, Extremely soft & ductile The largest atoms of the elements

Alkaline Metals

Group 2, Be & MG-Lowest density structural metals Ca, Sr, Ba, Ra- Weaker and reactive in normal air. Useful as alloying elements.

Solid Solution Strengthening

Hardening and strengthening of metals that result from alloying in which a solid solution is formed. The increased presence of impurity atoms restricts dislocation mobility. Cause stress strain in host lattice.

Annealing

Heating enhances atomic diffusion in order to remove local dislocations/strain and certain grains will grow and "consume" surrounding grains (recrystallization).

Coarse Pearlite

High Temperatures. Diffusion is fast so the carbon diffuses further in a given amount of time. Therefore, the carbon-rich cementite plates form further apart.

Alkali Metal Thermal Conductivity

High reactivity and low melting points preclude their use as room temperature conductors, but liquid alkali metals are useful as coolants in nuclear reactors.

Alkali Metals Corrosion Properties

High-purity Li, Na, and K form a thin protective oxide in ultradry high purity O2 In normal air they react with, H2O, O2, CO2, and N2 to form a complicated mixture of hydrides, oxides, carbonates, bicarbonates (and for Li a nitride) that are non-protective. Exhibit very low electronegativities and therefore highly reactive and must be stored in mineral oil or inert gas. Thick specimens of Na and K corrode to nonmetallic compounds within days. Alkali metals can even attack glass, reducing SiO2 to pure Si. The reactivity increases down the group, as the ionization energy decreases.

Gold (Au)

Highest electronegativity (2.4 Paulings) Can be purified by bubbling 02 through molten Au, oxidizes impurities which rise to top Most ductile metal

Microstructure Development Near Eutectoid Temperature(Fe-Fe3C

Hypoeutectoid- Proeutectoid Ferrite & Pearlite Eutectoid- Pearlite Hypereutectoid- Proeutectoid Cementite & Pearlite

Mechanical Properties of Steels

Increasing hardness, strength, brittleness Decreasing ductility Spherodite, Pearlite (+pro-eutectoid), Bainite, Tempered Martensite, Martensite

An equation that relates the stress required for crack propagation and the size of a flaw to a material property that describes resistance to brittle failure:

KIC=Yσc(πa)^(1/2) KIC - Plane Strain (Mode I) Fracture Toughness a - Half of the major axis of the elliptical flaw Y - A parameter describing the specimen geometry. (given or solvable)

Brittle Failure

Little to no plastic deformation prior to fracture. Crack growth is rapid, unstable and catastrophic.

Fine Pearlite

Low Temperatures. Diffusion is slow so the carbon diffuses less in a given amount of time. Therefore, the carbon-rich cementite plates form closer together.

Hardness Test

Measuring the depth of indentation

Compressive Stresses

Negative stress

Athermal (Diffusionless) Phase Transformation

No change in composition. (No diffusion required.) Cooperative and local rearrangement to form a new crystal structure. The extent of transformation is temperature dependent. Relatively fast upon activation. Ex: γ→α' (martensite)

Copper (Cu)

One of few elements found in metallic state in Earth's crust About as dense as Fe Excellent conductor of heat and electricity Relatively low cost Great ductility Work hardens very easily as room temp Used in electrical parts (wires) Forms non-protective layer above 200*C Forms protective layer below 200*C (green tarnish) Brass= Cu+Zn (Higher strength) Bronze= Cu+Sn (Low melting, easy to cast, brittle)

Tensile Stresses

Positive stress

Diffusion Controlled Phase Transformation

Product phase(s) are a different composition, and likely a different crystal structure. Thermally activated, meaning the transformation rate is temperature dependent. Ex: γ→α + Fe3C

Platinum Group Metals

Ru, Os, Rh, Ir, Pd, Pt 6 of the 10 most rare elements Extremely corrosion resistant Don't rely on protective oxide layers Large number of unpaired d electrons available for bonding, resulting in high moduli, high melting points, low thermal expansion, and short bond lengths (high densities). Low electrical conductivities

Failure/Fracture

Separation of a material to generate new and undesirable surfaces.

Nickel (Ni)

Similar properties as Fe Austenite stabilizer Nickel-based superalloys feature remarkable strength and corrosion resistance up to 1100*C Susceptible to corrosion when it contains chromium impurities or is exposed to environments with sulfur. >0.01wt% Ni in Earth's crust, mainly in core

Magnified Stress

Small and sharp flaws amplify/concentrate stress. σm=2(σo)(a/ρt)^(1/2) σm = magnified stress σo = original stress ρt = Crack tip radius a = Half of the major axis of the ellipse

Grain Size Reduction

Smaller grains (larger grain count) means more barriers to dislocation motion means harder / stronger (less ductile). Grain boundaries act as a "fence" for dislocations.

Spherodite

Spheroidite forms when a eutectoid steel (pearlite, bainite, or martensite) is held near eutectoid temperature for a very long time (> 100 hours for typical sized parts).

Martensite Application

Surface hardening of steel. Obtaining a high-carbon martensitic case (hard) on a tough low-carbon steel core (ductile) through carburization.

Elastic Region

The area of a stress-strain curve before the yield point. All strain in reversible. Atomic bonds are stretched.

Non-Uniform Plastic Region

The area of a stress-strain curve between the tensile strength point and the point of failure. Some strain is non-reversible and occurs locally in the specimen (at the necked cross section).Atomic bonds are broken/reformed. Dislocation is becoming difficult.

Uniform Plastic Region

The area of a stress-strain curve between the yield point and tensile strength point. Some strain is non-reversible and occurs throughout the specimen. Atomic bonds are broken/reformed. Dislocations begin to move.

Slip Direction

The crystallographic direction along which a dislocation moves

Slip Plane

The crystallographic plane along which a dislocation moves

Tungsten (W)

The highest melting point pure metal. 7th most dense metal (19.25g/cm^3). A metal that forms a very hard ceramic carbide for cutting tools and wear resistant coatings. Most of the annual extraction of this metal from the earth is utilized to form its carbide.

Elastic Deformation

The material will return to its original shape when the load is removed. Slope is the "spring constant", called the Young's Modulus, E

Tensile Strength

The maximum force that a specimen will endure. Necking begins to occur if more force is applied.

Failure/Fracture Point

The point at which the material breaks

Lever Law

The weight fraction of a phase is given by the length of the *OPPOSITE* lever arm over the entire length of both arms.

Creep

Time-dependent plastic deformation of a material subjected to a load at elevated temperatures

Hypoeutectic

To the left of the eutectic point

Hypereutectic

To the right of the eutectic point

Beryllium (Be)

Toxic, rare in Earth's crust, great for x-ray windows

Brittle

Very strong materials but not very ductile. Doesn't have a prominent yield point. Fail under elastic load after little to no plastic deformation.

Twinning

When separate crystals share a common set of lattice points. Can manifest during crystallization and during mechanical deformation. Mechanical twinning produces audible acoustic waves

Hot Working

Working or shaping a metal above its recrystallization temperature. Dislocations anneal out / heal as they form. Material does not strain harden and remains fairly ductile. Saves energy / allows for extreme deformations without fracture.

Cold Working

Working or shaping a metal below its recrystallization temperature. Material strain hardens, so strength and hardness increase. Limits shaping. Often requires post process annealing.

Dislocations and their purposes

[1] Crystalline materials generally feature many dislocations. [2] Dislocations can move (slip) in response to local shear stress. This is a good thing, since it makes deformation of metals relatively easy. [3] Dislocations can interact with each other and other defects(grain / phase boundaries, free surfaces, impurities, etc.)These interactions form the basis of strengthening mechanisms in metals. [4] Dislocations can be generated / multiplied in a number of ways in the material. More dislocations means more interactions ... means a stronger material. [5] Dislocation mobility typically* dictates mechanical properties of metals. Easy dislocation motion allows deformation to occur with fairly low stress. Dislocation pinning (or blocking) means a higher stress is required for deformation. aka. the material is stronger.

Engineering Strain

the change in length of sample divided by the original length of the sample

Poisson's Ratio

v= -(lateral strain)/(axial strain)

Fe-Fe3C Phase Diagram Classifications

wt%C < 0.022 = (Irons) Pure Iron or single phase α 0.022 < wt%C < 2.14 = (Steels) Often a two-phase mixture of α and Fe3C 2.14 < wt%C < 6.7 = (Cast Irons) Two or three-phase mixtures of α, Fe3C, and/or graphite.

Mean Stress

σ(m) = (σ(max) + σ(min))/2

Stress Amplitude

σa=abs[(σmax−σmin)/2]

An equation that relates the stress required for crack propagation to the "energy cost" associated with creating exposed surfaces during crack growth:

σc=(2Eγs/πa) σc= Stress required for crack propagation a - Half of the major axis of the elliptical flaw E - Young's modulus γs - Surface Energy = energy required to form free (unbonded) surfaces

An equation that relates the theoretical strength of a material to the magnified stress at a flaw.

σth=σm=2(σo)(a/ρt)^(1/2) σth = theoretical strength σm = magnified stress σo = original stress ρt = Crack tip radius a = Half of the major axis of the ellipse

Resolved Shear Stress

τR=σ(cosφcosλ) φ- Angle between the normal vector of the plane of interest (often the slip plane) and the loading axis. λ- Angle between the direction of interest on the plane (often the slip direction) and the axis of loading.