Spin excitations in a single La2CuO4 layer

Abstract

The dynamics of S=1/2 quantum spins on a 2D square lattice lie at the heart of the mystery of the cuprates Hayden2004,Vignolle2007,Li2010,LeTacon2011,Coldea2001,Headings2010,Braicovich2010. In bulk cuprates such as , the presence of a weak interlayer coupling stabilizes 3D N\'eel order up to high temperatures. In a truly 2D system however, thermal spin fluctuations melt long range order at any finite temperature Mermin1966. Further, quantum spin fluctuations transfer magnetic spectral weight out of a well-defined magnon excitation into a magnetic continuum, the nature of which remains controversial Sandvik2001,Ho2001,Christensen2007,Headings2010. Here, we measure the spin response of isolated one-unit-cell thick layers of . We show that coherent magnons persist even in a single layer of despite the loss of magnetic order, with no evidence for resonating valence bond (RVB)-like spin correlations Anderson1987,Hsu1990,Christensen2007. Thus these excitations are well described by linear spin wave theory (LSWT). We also observe a high-energy magnetic continuum in the isotropic magnetic response. This high-energy continuum is not well described by 2 magnon LSWT, or indeed any existing theories.