COLOR: rgb(0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">In recent years, CO0,0,0); FONT-SIZE: 5.08pt; mso-spacerun: 'yes'">2 0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">phase transition jet (CPTJ) coal-breaking technology has been reported to increase coal 0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">seam permeability. However, the structural evolution e0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">ffff0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">ect of coal subjected to CPTJ technology is unclear, 0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">which restricts widespread CPTJ technology application. In this study, a laboratory experimental system and 0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">fifi0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">eld technical equipment were developed, and coal-breaking experiments under di0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">ffff0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">erent CPTJ pressure con0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">ditions were conducted. We investigated pore structure changes by combining scanning electron microscopy 0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">(SEM) and mercury intrusion porosimetry (MIP) to better understand the coal pore structure evolution char0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">acteristics under di0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">ffff0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">erent CPTJ pressures. Furthermore, an enhanced coalbed methane (ECBM) recovery ex0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">periment using CPTJ coal-breaking technology was conducted with the self-developed technical equipment. The 0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">results show that notable damage occurs in the coal body in0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">flfl0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">uenced by CPTJ, and the damage area increases 0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">with increasing jet pressure. The SEM results revealed that more pores and cracks are produced due to liquid CO0,0,0); FONT-SIZE: 5.08pt; mso-spacerun: 'yes'">2 0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">CPTJ, and the porosity and crack size increase with increasing jet pressure. MIP analysis indicates that the pore 0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">structure of the breaking coal samples mainly includes macropores, and coal sample macroporosity increases 0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">signi0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">fifi0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">cantly with increasing jet pressure. The 0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">fifi0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">eld ECBM experiment showed that CPTJ technology can reduce 0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">the coalbed methane (CBM) drainage decay coe0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">ffiffiffi0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">cient and increase the CBM extraction pure 0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">flfl0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">ow rate and 0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">recovery e0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">ffiffiffi0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">ciency 8.30; COLOR: rgb(0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">–0,0,0); FONT-SIZE: 7.173pt; mso-spacerun: 'yes'">10.4 and 20.4 times, respectively.