Abstract This paper presents experimental data on the change of volume and relative density in a cohesionless soil mass due to static vertical load and cyclic torsional shearing compaction. A cyclic torsional shearing compactor was with a 0.45 m-diameter circular shearing disc was designed and constructed at National Chiao Tung University. Air-dry Ottawa sand was used as fill material. The initial relative density of the fill was 36 %. The static vertical load and cyclic torsional shearing were applied on the surface of a 1.5 m-thick lift, and then on another specimen with five 0.3 m-thick lifts, with the rotation angles be +5°. Surface settlement of the fill was measured with a laser distance meter. Soil density cups were buried in the cohesionless specimen to monitor the distribution of relative density of with depth soil. Based on the test results, the following conclusions were drawn. In the first 5 cycles of cyclic torsional shearing application, the surface settlement increased significantly. However, after 20 cycles, the major part of settlement was accomplished, soil particle were sheared and reached a densely-packed condition. As a result, it was difficult to increase the surface settlement any further with more cyclic shear application. For shearing compaction on five 0.3 m-thick lifts, after 20 cycles of torsional shearing with the torsional angle of =±5˚, the average volumetric strain for the lift 1, 2, 3, 4, and 5 was 9.77, 10.53, 10.37, 10.05 and 10.32 %, respectively. It was clear that the cyclic torsional shearing compaction in each lift was relatively uniform. Most of the relative density measured in compacted fill were greater than 70 %. The entire soil body was successfully compacted with cyclic torsional shearing compaction. For five compacted lifts, the mean relative density was 76.3 % with a standard deviation of 6.2 %. It was obvious that the entire soil body was successfully compacted with this ground improvement technique.