Sprung, DetlevDetlevSprungGrossmann, PeterPeterGrossmannSucher, ErikErikSucherWeiss-Wrana, KarinKarinWeiss-WranaStein, KarinKarinStein2022-03-112022-03-112011https://publica.fraunhofer.de/handle/publica/37282510.1117/12.897720Operation and design of electro-optical systems are affected by atmospheric optical turbulence quantified by the refractive index parameter Cn². Regarding wave propagation in the visible and infrared (IR), Cn² is a function of height, dependant on temperature, pressure, and the structure temperature function parameter CT². The long-term experiment VerTurM (vertical turbulence measurements) was designed to characterize the vertical variations of optical turbulence up to 250 m in the lower atmospheric boundary layer for a moderate typical central European climate. Since May 2009 three atmospheric surface layer at a tall tower sonic anemometer measurements are performed on four discrete heights between 4 and 64 m providing information about atmospheric stability and turbulence. CT² is derived. From 30 to 250 m a SODAR-RASS system (Sound Detection and Ranging - Radio acoustic sounding system) yields every half an hour profiles of CT². Additional direct measurements of Cn² have been performed near the ground using a scintillometer. First results of the three measurement systems are presented. Vertical profiles and stability dependence are analysed in respect of Monin-Obukhov-similarity theory (MOST). Differences in the measurement systems and the expected height variations are discussed.enoptical turbulencelower atmospheric boundary layer004670conference paper