The reconstruction and energetics for a range of chalcopyrite (CuFeS2) surfaces have been investigated using hybrid-exchange density functional theory. The stable nonpolar surfaces in increasing order of surface energy are (110), (102), and (114). In addition, the polar (112)/(112) surface pair was found to be remarkably stable with a surface formation energy that is only slightly higher than that of the (110) surface. The stability of (112)/(112) can be attributed to a combination of geometric and electronic mechanisms that result in the suppression of the electrostatic dipole perpendicular to the surface. Defect formation is a third mechanism that can further stabilize the (112)/(112) surface pair to an extent that it is thermodynamically preferred over the (110) surface. The stability of (112)/(112) means that regardless of the growth conditions, (112) and (112) facets are expected to have a significant presence in the surface morphology of CuFeS2. [ABSTRACT FROM AUTHOR]