Light scattering in spin orbit coupling dominated systems

Strong spin-orbit coupling (SOC) in solids has recently been identified as leading to novel electronic states with unconventional phases. Examples are topological insulators and unconventional magnets. Sr2IrO4, Sr3Ir2O7, BaIrO3, and Na4Ir3O8 are candidates and model systems for such phases. Recent Resonant X-Ray and IR absorption studies on Sr2IrO4 show anomalies that are related to the proximity of charge and spin modes. This proximity is further investigated in the following thesis based on Raman scattering with different incident Laser energies (Resonant Raman scattering). Pronounced resonances show up in intensity and linewidths of phonon and magnetic scattering. Sr3Ir2O7 is another interesting case of spin orbit physics. Despite the similar crystal structure to Sr2IrO4, the electronic structure and magnetic structure of Sr3Ir2O7 differs significantly from Sr2IrO4 which is evident in our magnetic Raman scattering data. BaIrO3 is a quasi-1D system which exhibits peculiar transitions. A charge density wave (CDW) formation accompanied by structural distortions is evident in our Raman scattering data in terms of electronic scattering and phonon anomalies. Another novel case of spin-orbit physics is given in Na4Ir3O8 which is reported to be a spin liquid. First Raman data of this special compound are discussed.