We investigated experimentally the motion of elongated finite-length cylinders (length L, diameter d) freely falling under the effect of buoyancy in a low-viscosity fluid otherwise at rest. For cylinders with densities Pc close to the density PJ of the fluid (75 = PelPJ '.:::::'. 1.16), we explored the effect of the body volume by varying the Archimedes number Ar (based on the body equivalent diameter) between 200 and 1100, as well as the effect of their length-to-diameter ratios L/d ranging from 2 to 20. A shadowgraphy technique involving two cameras mounted on a travelling cart was used to track the cylinders along their fall over a distance longer than 30L. A dedicated image processing algorithrn was further implemented to properly reconstruct the position and orientation of the cylinders in the three-dimensional space. ln the range of parameters explored, we identified three main types of paths, matching regimes known to exist for three-dimensional bodies (short-length cylinders, disks and spheres). Two of these are stationary, namely, the rectilinear motion and the large-amplitude oscillatory motion (also referred to as fluttering or zigzag motion), and their characterization is the focus of the present paper. Furthermore, in the transitional region between these two regimes, we observed irregular low-amplitude oscillatory motions, that may be assirnilated to the A-regimes or quasi-vertical regimes of the literature. Flow visualization using dye released from the bodies uncovered the existence of different types of vortex shedding in the wake of the cylinders, according to the style of path. The detailed analysis of the body kinematics in the fluttering regime brought to light a series of remarkable properties. ln particular, when normalized with the characteristic velocity scale uo = .J(p - l)gd and the characteristic length scale lo = ,Jdf,, the mean vertical velocity Uz and the frequency f of the oscillations become almost independent of L/ d and Ar. The use of the length scale lo and of the gravitational velocity scale to build the Strouhal number St*= fto/uo allowed us to generalize to short (0.1 ⩽ L/d ⩽ 0.5) and elongated cylinders (2 ⩽ L/d ⩽ 12), the result St*'.:::::'. 0.1. An interpretation of Lo as a characteristic length scale associated with the oscillatory recirculation thickness generated near the body ends is proposed. In addition, the rotation rate of the cylinders scales with u0/L, for all L/d and Ar investigated. Furthermore, the phase difference between the oscillations of the velocity component u along the cylinder axis and of the inclination angle 0t of the cylinder is approximately constant, whatever the elongation ratio L/d and the Archimedes number Ar.