The profit function of the firm is given by $\Pi = PQ-TC = PQ - VC - FC = P(40L - L^2) - 20L - 10 = 40PL-PL^2-20L-10$
So our optimization problem is
$\max_L \Pi = 40PL-PL^2-20L-10$
This is a single variable unconstrained optimization problem with a concave objective function, so we simply set $\frac{d\Pi}{dL} = 0$.
$\frac{d\Pi}{dL} = 40P-2PL-20=0 \implies 40P - 20 = 2PL \implies L^\star = \frac{40P-20}{2P} = \frac{20P-10}{P} = 10 \cdot \frac{2P-1}{P}$
Plugging the optimal labor into the production function,
$Q^s = 40L^\star - (L^\star)^2 = 40 \cdot 10 \cdot \frac{2P-1}{P} - (10 \cdot \frac{2P-1}{P})^2 = 400 \cdot \frac{2P-1}{P} - 100 \frac{(2P-1)^2}{P^2} = \frac{400P(2P-1)-100(2P-1)^2}{P^2} = \frac{800P^2-400P-100(4P^2-4P+1)}{P^2} = \frac{800P^2-400P-400P^2+400P-100}{P^2} = \frac{400P^2-100}{P^2}= 100 \cdot \frac{4P^2-1}{P^2}$
Therefore, the supply curve of the firm is given by
$Q^s(P) = 100 \cdot \frac{4P^2-1}{P^2}$
Note this expression can be negative when $P<\frac{1}{2}$, in which case the actual supply would be $0$$Q^s = 0$.
Taking into account this caveat, the supply curve is given by
$$ Q^s(P)= \begin{cases} 100 \cdot \frac{4P^2-1}{P^2}, P \geq \frac{1}{2}\\ 0, P < \frac{1}{2}\\ \end{cases} $$