Is it true that $\mathit{MA}(\omega_1)$ iff $\omega_1<\mathfrak{p}$?

Question

Recall that

$\mathfrak{p}=\min\{|F|: F$ is a subfamily of $[\omega]^{\omega}$ with the sfip which has no infinite pseudo-intersection $\}$.

The cardinal $\mathfrak{q}_0$ defined as the smallest cardinality of a subset of $\mathbf{R}$ which is not a $Q$-space.

Q1. Is it true that $\mathit{MA}(\omega_1)$ iff $\omega_1<\mathfrak{p}$ ?

Q2. Is there a model of set theory in which $\omega_1=\mathfrak{q}_0$ and a non-$\mathit{MA}(\omega_1)$ ?

Answer 1

Q1: No, see Between Martin's Axiom and Souslin's Hypothesis by Kunen and Tall. Note: Bell proved in The combinatorial principle $P(\mathfrak{c})$ that $\mathfrak{p}>\aleph_1$ is equivalent to $\mathsf{MA}(\aleph_1)$ for $\sigma$-centered partial orders.

Q2: $\mathsf{MA}(\aleph_1)$, even $\mathfrak{p}>\aleph_1$, implies $\mathfrak{q_0}>\aleph_1$, see page 162 of Internal Cohen Extensions by Martin and Solovay. The principle $\mathsf{S}_\aleph$ is proved on page 154, using a $\sigma$-centered partial order. So, every model with $\mathfrak{q}_0=\aleph_1$ satisfies $\neg\mathsf{MA}(\aleph_1)$ as well, for example every model of $\mathsf{CH}$ will do.