We compare 22 temperature height profiles derived from falling sphere experiments with simultaneous 50-MHz mesospheric radar echoes obtained during the Middle Atmosphere Co-operation/Summer in Northern Europe campaign in the summer of 1987 above Andenes, Norway. Common features of these observations are as follows: (1) More than 80% of the echoes occur at temperatures below 140 K and more than two thirds of the bottommost echo maxima appear at temperatures that deviate less than 5¿ from 140 K. (2) We can find no significant correlation between the echo strength or the echo occurrence probability and the local temperature once it is below 140 K. (4) The echoes are not symmetrically distributed around the mesospheric temperature minimum, but there are clearly more echoes below than above the temperature minimum. Equivalently, while the local temperature at the height of the bottommost echoes is about 140 K, it is much lower at the height of the topmost echoes. We compare the height range of the observed polar mesospheric summer echo returns with the height range that can be inferred for an ice cloud from the observed temperature profile by means of a simple stationary nucleation/sedimentation model. For reasonable values of the height-integrated ice particle nucleation rate of about 3¿107 m-2 s-1 and for a water molecule mixing ratio at the bottom of the ice cloud of 0.1 to 1.0 ppmv, we find excellent agreement between the height range within which the ice particles may exist and the height range from which mesospheric echoes are seen. For example, in 17 out of the 22 individual observations, reasonable values for the water vapor mixing ratio can be found such that the height of the strong bottommost echo corresponds to within the resolution of the radar to the bottom height of our model ice cloud. If our height estimates are correct and the observations are representative, our results yield a somewhat smaller water vapor mixing ratio in the summer mesosphere at high latitudes compared to what has been measured at midlatitudes. ¿ American Geophysical Union 1994