Your first confusion: Lo vs. L I have indeed made it very confusing by mixing symbols L (instantaneous or final length) and Lo (initial length). Engineering strain eE should be defined eE=DL/Lo where DL=L-Lo is the change in length. However, in the slide I have written it as DL/L. I have added to the confusion by labelling the initial length in my sketch as L and not as Lo. Thanks for pointing this out and sorry for the confusion it has created. Your second doubt: And how a true strain can be equal to =0 after full iteration... During the compression stage from 2Lo to Lo the true strain eT=ln L/Lo is negative as L

Which Class ??

Engg stress

The difference between engineering and true stresses and strains becomes negligible for small elastic deformation. Thus Hooke's law is valid for both and will give the same modulus.

This is good question. I think we can say that this is an experimental observation. The atomic mechanisms of plastic deformation are consistent with this fact. So in slip one part of the crystal slides over the other part and so the volume remains constant. In twinning, the crystal reorients itself, again keeping the volume constant.

So this is how you can do it. you know e(true)=F/A and e(eng) = F/A0...................................................... Divide e(true) by e(eng)............ u should get the following....... e(true)/e(eng= F*Ao/A*F............ both forces will cancel each other and you will have will end up with e(true)=e(eng)*(Ao/A)

just multiply and divide by A0

I extend from L to 2L and then compress it back to L again. Obviously, the net strain is zero. It comes out to be zero if we calculate true strain. But it is not so if we use engineering strain.

@@introductiontomaterialsscience Sir, here the initial condition starts with Lo. "so engineering strain denominator should be always Lo and not 2Lo". please Correct me Sir,if the statement is wrong.

@@bs143The idea is that if you consider tension and compression steps separately. So during tension, the initial length is Lo but during compression the initial length is 2Lo.

Stress can be a scalar, a vector, or a tensor depending on the context. When we discuss the results of a uniaxial tensile test we are thinking of a single tensile force acting along the longitudinal axis of the sample on the transverse plane. Here we simply divide the magnitude of the force by the transverse area and treat it as a scalar. The scalar stress here is the division of two scalars. This is the context in which I have used stress in this course. But when you think of a vector force acting on a plane of a specific area then you can divide the force vector by the scalar area. This is a well-defined vector quantity and is called a TRACTION vector. Here we are dividing the vector by a scalar to obtain another vector, which is fine. So in the example of the uniaxial tensile test mentioned in the previous paragraph, you can treat the tensile stress also as a tensile traction vector of the magnitude force/ area acting in the direction of the longitudinal axis. If one wishes to describe stress at a point in material then one uses stress tensor, a symmetric second-rank tensor having nine components of which six are independent. If you know this tensor sigma then you can find the traction vector T on any plane passing through the point with an outward plane normal vector n. This relation is given as T= sigma n So sigma can be thought of as a second rank tensor that relates the plane normal vector n to the traction vector T acting on that plane. Since the above is a tensor relation, you CANNOT invert it to write sigma=T/n and think of sigma as a division of two vectors, an operation that is not defined in vector algebra.

@@rajeshprasadlectures thanks for your detailed reply

Sorry, I am not able to get your question. Could you please express it differently.

In the strength of materials we usually confine ourselves to elastic regime. In the small strains corresponding to elasticity there is not much difference between true and engineering stress. The difference becomes significant only when the strains are large, like in plastic deformation.

Mathematically they would be same only at zero strain. Beyond that, they are rather close upto yield point in metals.

I agree with you. I am rather slow. If ever, I do a second edition, I will try to be faster. thanks for the feedback rajesh prasad

That's right. Both engineering strain and true strain depend only on the Initial and final lengths.