Optical element and radiation-emitting device comprising such an optical element

The invention claimed is: 1. An optical element comprising: an optical body forming a half-shell and comprising an inner face and an outer face; and a plurality of microstructures forming the outer face of the optical body, the inner face being free of microstructures, wherein the microstructures are light-scattering refractive structures, wherein the microstructures form an array of individual lenses and the microstructures, when viewed in plan view onto the outer face, have a base area, the base area of the microstructures declines continuously towards a point of intersection of an optical axis with the outer face, wherein the microstructures are formed by continuous grooves along continuous lines of latitude and by continuous degrees of longitude of the hemispherical shell-shaped outer face, and wherein the continuous grooves along the continuous lines of latitude are continuous for 360 degrees around the optical axis. 2. The optical element according to claim 1 , wherein the microstructures at least in part have different shapes. 3. The optical element according to claim 1 , wherein the microstructures are aspherical. 4. The optical element according to claim 1 , wherein the optical body forms a hemispherical shell. 5. A radiation-emitting device comprising: a radiation-emitting semiconductor component comprising an active layer configured to generate radiation; and an optical element according to claim 1 arranged downstream of the semiconductor component in an emission direction. 6. The radiation-emitting device according to claim 5 , wherein the device comprises a plurality of semiconductor components that emit monochromatic light. 7. The radiation-emitting device according to claim 5 , wherein the device comprises a plurality of semiconductor components that emit light which is at least in part of different colors. 8. An optical element comprising: an optical body forming a half-shell and comprising an inner face and an outer face; and a plurality of microstructures that form the inner and outer face of the optical body, wherein the microstructures are light-scattering refractive structures, wherein the microstructures of the outer face have annular shape about an axis of symmetry of the optical body, the annular shape of the microstructures becoming smaller towards the axis of symmetry, wherein the microstructures of the inner face have annular configuration, the annular configuration being rotated by 90° relative to the annular shape of the microstructures of the outer face so that the microstructures of the inner face are directed along the axis of symmetry, wherein the microstructures of the outer face form lines of latitude and the microstructures of the inner face form lines of longitude, wherein an emission profile of the optical element follows a Gaussian beam profile, wherein the emission profile does not have a plurality of intensity maxima delimited by a plurality of intensity minima, and wherein the emission profile comprises a uniform profile with just one central maximum. 9. The optical element according to claim 1 , wherein the microstructures shape a radiation only by refraction so that the microstructures are light-scattering refractive structures, wherein the individual lenses are arranged as an array in a manner of a matrix on the outer face of the optical body, and wherein the optical body and the individual lenses are of one-piece construction. 10. The optical element according to claim 1 , wherein the base area is a trapezoidal base area. 11. A radiation emitting device comprising: an array of red and white emitting LEDs; and an optical element, the optical element comprising: an optical body forming a hemispherical half-shell and comprising an inner face and an outer face; and a plurality of microstructures that form the inner and outer face of the optical body, wherein the microstructures are light-scattering refractive structures, wherein the microstructures of the outer face have annular shape about an axis of symmetry of the optical body, the annular shape of the microstructures becoming smaller towards the axis of symmetry, wherein the microstructures of the inner face have annular configuration, the annular configuration being rotated by 90° relative to the annular shape of the microstructures of the outer face so that the microstructures of the inner face are directed along the axis of symmetry, and wherein the microstructures of the outer face form lines of latitude and the microstructures of the inner face form lines of longitude, wherein the inner and outer face microstructures have a curvature for which the following applies: d max /(2* r microstructure )≦1.2, wherein d max is the maximum height of the microstructures and r microstructure is the curvature of the microstructures seen in a cross-section perpendicular with the respective annular shape, wherein the microstructures shape the radiation by refraction only so that the microstructures are light-scattering refractive structures, wherein a center point of the red and white emitting LESs is a center point of the optical hemispherical half-shell, and wherein the individual microstructures on the outer face and on the inner face along a spatial direction in each case have an extent of at least 5° and at most 14°. 12. The radiation emitting device according to claim 11 , wherein an emission profile of the optical element follows a Gaussian beam profile, wherein the emission profile does not have a plurality of intensity maxima delimited by a plurality of intensity minima, and wherein the emission profile comprises a uniform profile with just one central maximum.