Abstract

Unrevealing local magnetic and electronic correlations in the vicinity of charge carriers is crucial in order to understand rich physical properties in correlated electron systems. Here, using high-energy optical conductivity (up to 35 eV) as a function of temperature and polarization, we observe a surprisingly strong spin polarization of the local spin singlet with enhanced ferromagnetic correlations between Cu spins near the doped holes in lightly hole-doped $\mathrm{L}{\mathrm{a}}_{1.95}\mathrm{S}{\mathrm{r}}_{0.05}\mathrm{C}{\mathrm{u}}_{0.95}\mathrm{Z}{\mathrm{n}}_{0.05}{\mathrm{O}}_{4}$. The changes of the local spin polarization manifest strongly in the temperature-dependent optical conductivity at $\ensuremath{\sim}7.2\phantom{\rule{0.16em}{0ex}}\mathrm{eV}$, with an anomaly at the magnetic stripe phase $(\ensuremath{\sim}25\phantom{\rule{0.16em}{0ex}}\mathrm{K})$, accompanied by anomalous spectral-weight transfer in a broad energy range. Supported by theoretical calculations, we also assign high-energy optical transitions and their corresponding temperature dependence, particularly at $\ensuremath{\sim}2.5,\ensuremath{\sim}8.7,\ensuremath{\sim}9.7,\ensuremath{\sim}11.3$, and $\ensuremath{\sim}21.8\phantom{\rule{0.16em}{0ex}}\mathrm{eV}$. Our result shows the importance of a strong mixture of spin singlet and triplet states in hole-doped cuprates and demonstrates a new strategy to probe local magnetic correlations using high-energy optical conductivity in correlated electron systems.