Consinder a smooth manifold $M$ and $\omega$ a smooth $1$-form on $M$. Assume that there is an open set $U\subset M$ such that $\omega$ never vanishes on $U$. One can define a smooth distribution $\cal F$ on $TU$ via the kernel of $\omega$. Frobenius theorem tells us that such distribution promotes a foliation on $M$ provided if $d\omega\wedge\omega =0$, that happens to be equivalent to the existence of a smooth $1$-form $\alpha$ such that $d\omega = \alpha\wedge \omega.$

My questions are, can one assume that $\omega$ is closed in some case? If yes, what can one conclude something else about the smooth distribution? How restrictive is this condition?

I am particularly interested on this question because this can provide simple proofs for Calabi-Honda theorems of intrinsically harmonic 1-forms.

Consinder a smooth manifold $M$ and $\omega$ a smooth $1$-form on $M$. Assume that there is an open set $U\subset M$ such that $\omega$ never vanishes on $U$. One can define a smooth distribution $\cal F$ on $TU$ via the kernel of $\omega$. Frobenius theorem tells us that such distribution promotes a foliation on $M$ provided if $d\omega\wedge\omega =0$, that happens to be equivalent to the existence of a smooth $1$-form $\alpha$ such that $d\omega = \alpha\wedge \omega.$

My questions are, can one assume that $\alpha$ is closed in some case? If yes, what can one conclude something else about the smooth distribution? How restrictive is this condition?

I am particularly interested on this question because this can provide simple proofs for Calabi-Honda theorems of intrinsically harmonic 1-forms.