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I found out that there exist positive definite matrices that are non-symmetric, and I know that symmetric positive definite matrices have positive eigenvalues.

Does this hold for non-symmetric matrices as well?

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    There is a nice explanation about non-hermitian positive definite matrices. Please have a look into http://www.math.technion.ac.il/iic/ela/ela-articles/articles/vol20_pp621-639.pdf2015-03-22

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Let $A \in M_{n}(\mathbb{R})$ be any non-symmetric $n\times n$ matrix but "positive definite" in the sense that:

$\forall x \in \mathbb{R}^n, x \ne 0 \implies x^T A x > 0$ The eigenvalues of $A$ need not be positive. For an example, the matrix in David's comment:

$\begin{pmatrix}1&1\\-1&1\end{pmatrix}$

has eigenvalue $1 \pm i$. However, the real part of any eigenvalue $\lambda$ of $A$ is always positive.

Let $\lambda = \mu + i\nu\in\mathbb C $ where $\mu, \nu \in \mathbb{R}$ be an eigenvalue of $A$. Let $z \in \mathbb{C}^n$ be a right eigenvector associated with $\lambda$. Decompose $z$ as $x + iy$ where $x, y \in \mathbb{R}^n$.

$(A - \lambda) z = 0 \implies \left((A - \mu) - i\nu\right)(x + iy) = 0 \implies \begin{cases}(A-\mu) x + \nu y = 0\\(A - \mu) y - \nu x = 0\end{cases}$ This implies

$x^T(A-\mu)x + y^T(A-\mu)y = \nu (y^T x - x^T y) = 0$

and hence $\mu = \frac{x^TA x + y^TAy}{x^Tx + y^Ty} > 0$

In particular, this means any real eigenvalue $\lambda$ of $A$ is positive.