Prove that the determinant of skew-symmetric matrices of odd order is zero

linear-algebra matrices

I have to prove that determinant of skew- symmetric matrix of odd order is zero and also that its adjoint doesnt exist. I am sorry if the question is duplicate or already exists.I am not getting any start.I study in Class 11 so please give the proof accordingly. Thanks!


$A$ is skew-symmetric means $A^t=-A$. Taking determinant both sides $$\det(A^t)=\det(-A)\implies \det A =(-1)^n\det A \implies \det A =-\det A\implies \det A=0$$

I don't understand what do you mean by adjoint does not exist.

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