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I have a rank 2 tensor obtained by acting with the grad operator twice successively on a function [Psi], so let's call this tensor [Psi]2. I then simply want to contract it over its two indices with a vector f such that I obtain a new vector, but cannot get it to work for some reason, so not sure if I am doing the wrong syntax.

I've tried to change a code slightly which works when contracting a rank 2 tensor with another rank 2 tensor to get a scalar.

This is the code I am trying:

Sum[f[[i]]*[Psi]2[[i, j]], {i, 1, 3}, {j, 1, 3}]

Compare this with the code I have written which enables me to contract a rank 2 tensor with another rank 2 tensor to get a scalar

Gddrr = Sum[GG[[i, j]]*rr[[i, j]], {i, 1, 3}, {j, 1, 3}];

where GG and rr are both rank 2. However, although I am expecting to obtain a vector from this contraction, I am getting a scalar instead.

[Psi] = R/(8*pi)

f = {f1, f2, f3}

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    I don't know a lot of Mathematica, but presumably Sum will always give you a scalar. You need a way of splitting up the sum into the different vector/tensor components, like assigning the partial sums to that index. @Tom – Tyberius Jul 4 at 1:18
  • Yes, so it's like if I have f_i and g_ij, I just need to sum over the first index of the rank 2 tensor somehow but not sure how to do it. – Tom Jul 4 at 1:21
  • Can you provide an example of Psi and f? Sounds like you need to use a Dot product? – Rohit Namjoshi Jul 4 at 2:50
  • I've added the examples as requested, bear in mind f is a general vector, then psi is a scalar which becomes a rank 2 tensor after I act on it twice with the grad operator. – Tom Jul 4 at 2:58
  • What's the term [Psi]2 supposed to be ? What kind of Mathematica entity or thing is it ?. Yes, I see you want to use it as the name of a tensor, but Mathematica has it's own ideas about names and other forms. If I try to evaluate your first expression (ie Sum[f[[i]]*[Psi]2...) Mathematica raises an error. – High Performance Mark Jul 4 at 7:26

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