Abstract Supercritical carbon dioxide (SC–CO2) shows many advantages in the exploitation of shale gas and geothermal energy. This condition is mainly because pressure synergizes with temperature in rock-breaking. A computational model was established on the basis of an experimental setup and validated with experimental data to study the energy transformation and dissipation mechanism. The jet fields of water, SC-CO2 and nitrogen were studied. Result shows that the jet center pressure and temperature difference are in the following descending order: SC-CO2 > nitrogen > water, indicating that SC-CO2 jet can produce the maximum broken volume. The SC-CO2 and nitrogen temperature drops are induced by endothermic expansion, and the water temperature increment is caused by viscous heating. The total pressure underestimates the energy of SC-CO2 and nitrogen flows, which is harmful to safety risk control. The dissipation rate of flow energy is in the following ascending order: SC-CO2

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