Thanks. Your feedback is welcome.

@@introductiontomaterialsscience sir why does cross slip or climb takes place in precipitate hardening

@@letslearnmechanicalengineering if the precipitate is coherent, then the phase boundary is uniform enough (to the main lattice) to facilitate slipping of planes

Most teachers in India are also nothing compared to him. Good teachers are rare, everywhere.

When a dislocation negotiates a precipitate distribution it can bow between two nearby precipitates. The stress required for bowing is inversely proportional to the distance between the precipitates During aging, as more precipitates form, this distance between the precipitates decreases so the stress required for bowing increases. During overaging, the no new precipitates are forming. The existing fine distribution of precipitates changes to a coarse distribution with the same volume but less number of precipitates. This increases the distance between the precipitates thus reducing the stress.

@@rajeshprasadlectures Thanks for the explanation !

@@syamukrishnan @34:04 it's mentioned loops increases hardness in coarse ppt, but when u refer formula it seems contradicting, but both statements are correct in their place.This is how I think it to be: 1. Loops increase hardness, so overaged alloys must have hardness higher than pure Al 2. But when u refer to formula, u are basically comparing stress required for fine ppt and coarse ppt

Thanks for suggestion. A challenging task.

After some time all precipitates have already formed. Thus no new precipitates can form. But the existing fine distribution of precipitates start to become coarse with time. This increases the interparticle distance, thus reducing the resistance to the dislocation motion and reduction of hardness.

It all depends on the scale of observation of the microstructure. The size of precipitated causing increase in hardness is very small and cannot be observed at the optical microscopy level. So for the initial investigators, like Wilm, no change in the microstructure was observed although there was change in the hardness. This was the surprise element. But later, with help of more powerful electron microscope fine precipitated were indeed observed. So, as you state, property is indeed a function of microstructure.

The two terms are synonymous. Age hardening refers to the fact that hardness increases with time(age). Precipitation hardening refers to the fact that the hardness increases due to the formation of second phase precipitates.

@@rajeshprasadlectures thank you very much professor

Yes. Dispersion hardening (say thoria-dispersed Ni) and hardening due to reinforcement in metal matrix composites can be explained similarly. Of course, in these cases there will be no time-dependence.

@@introductiontomaterialsscience thank you sir, your answer is helping my project....

No you can not apply... They are two different mechanisms.

Please address GP zones vis-a-vis hardening

For the same volume fraction of precipitates the fine precipitates will give higher strength.

Precipitation at grain boundaries require less driving force and thus can happen even at higher temperature in comparison to precipitation inside the grains. Thus in slow cooling precipitates can form, but as the transformation temperature is high, most precipitates will form at gb. This is not good for hardening. This is the reason why quenching is required. Quenching, followed by ageing allows precipitation to happen at much lower temperature. Due to higher driving force available at low temperatures, precipitate form inside the grains as well, leading to more effective hardening.

Hardeness and strength are interconnected. Whenever hardness increases strength also increases.

The right hand side is around Al2Cu, so about 33 atomic % Cu.

The way it is done in industry that peak hardness is attained by artificial aging at a higher temperature. Once this hardness is obtained the product is used at room temperature. At room temperature, although averaging will eventually take place, but the rate is rather low. So the component will maintain its hardness for the expected product life.

Hardness test is usually done after cooling down to room temperature.

No, it is not really a nucleation problem, as the product phase is already present as fine particles. Only the average size of the particle increases. Thus in overaging the entire driving force comes from the surface energy. In heterogeneous nucleation, surface energy is a part of the driving force. The other part is the volume energy.