We have computed static and dynamic properties of an electron coupled to hard-core-boson (HCB) degrees of freedom in one spatial dimension. The polaron, an electron dressed with HCB excitations, remains light even in the strong-coupling limit as its effective mass remains of the order of the free-electron mass. This result is in a sharp contrast to the Holstein model where the electron effective mass increases exponentially with the electron-phonon coupling. HCB degrees of freedom mediate the attractive potential between two electrons that form a bound singlet bipolaron state at any nonzero coupling strength. In the low-frequency regime of the electron spectral function we observe a quasiparticle (QP) band that is separated from the continuum of states only in the central part of the Brillouin zone. The quasiparticle weight approaches zero as the QP band enters the continuum where it obtains a finite lifetime. At finite temperature an electron can annihilate thermally excited HCBs. Such thermally activated processes lead to a buildup of the spectral weight below the QP band. While the investigated model bears a resemblance with the Holstein model, we point out many important differences that originate from the binary HCB excitation spectrum, which in turn mimics spin-$\frac{1}{2}$ degrees of freedom.

• Received 18 February 2020
• Revised 8 July 2020
• Accepted 8 July 2020

DOI:https://doi.org/10.1103/PhysRevB.102.035135