+{\color{red} This can be employed to create 3C layers with reduced density of APB defects.}
+
+Lower growth temperatures, a clean growth ambient, in situ control of the growth process, layer-by-layer deposition and the possibility to achieve dopant profiles within atomic dimensions due to the reduced diffusion at low growth temperatures reveal MBE as a promising technique to produce SiC epitaxial layers.
+gas source ... 3C on 6H
+3C on 3C homoepitaxy by ALE
+6H on 6H ...
+Problem of gas source ... strong adsorption and incorporation of atomic decomposited hydrogen of the gas phase reactants at low temperatures.
+Growth rate lower than desorption rate of hydrogen ...
+Solid source MBE may be the key to avoid such problems ...
+Realized on and off-axis 3C on 4H and ... \cite{fissel95,fissel95_apl} ...
+Nonstoichiometric reconstruction plays a relevenat role ... handled by Si/C flux ratio ... \cite{fissel96,righi03} ...
+change in adlayer thickness and, consequently, in the surface super structure leading to growth of another polytype \cite{fissel95} ...
+Possibility to grow heterostructures (band gap engineering) by careful control of the Si/C ratio and Si excess.
+
+To summarize ... remaining obstacles are ... APB in 3C ... and micropipes in hexagonal SiC?