Recovery of strength in locally versus globally thermally cracked freshwater ice produced in the laboratory and sea ice collected in the Beaufort Sea, 2022-2024

The vulnerability of ocean and lake ice covers to climate change-induced threats, such as decreased extent and increased thermal cracking, necessitates comprehensive investigation. Conducted at Dartmouth College's Ice Research Laboratory from 2022 to 2024, experiments introduced thermal shock to laboratory-grown freshwater ice and natural first-year sea ice using liquid nitrogen to either a narrow band or the entire surface of ice samples. This study explores the impact of thermal cracking on the flexural strength. Results indicate that while both types of ice initially experience strength reduction after thermal shock, full recovery occurs when a narrow region is shocked, whereas only partial recovery is observed when the entire surface is shocked in freshwater ice, contrasting with full recovery in sea ice. Repeated cycles of cracking and healing do not affect flexural strength recovery. Moreover, experiments involving creep reveal the influence of compressive stress on healing, highlighting its role in ice sintering and strength restoration. Application of a compressive stress of 1 MPa for 1 hour enhances strength recovery, with flexural strength almost completely restored. The disparity in behavior between cracking a narrow region versus the entire surface is attributed to residual compressive stresses during healing when a narrow region is shocked. Rapid healing in sea ice is observed, likely due to its porous structure and the presence of brine.This dataset contains the following data: Flexural strength of cracked freshwater ice when a narrow region cracked, Flexural strength of cracked freshwater ice when all surface is cracked, lexural strength of cracked sea ice when all surface is thermally shocked, Flexural strength of thermally cracked freshwater ice after 5 cycles of shock/healing, Flexural strength of laboratory-grown freshwater ice that was crept for 1 hr at 1MPa.