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Effects of irradiation on nano-pore phenol-formaldehyde resin infiltrated IG-110 graphite
Iso-molded nuclear graphite (IG-110) was infiltrated with phenol–formaldehyde (PF) resin to get the densified isostatic graphite with different bulk density (IG-110-PF, 1.86 g/cm3 and IG-110-PF-D, 1.91 g/cm3). The IG-110-PF and IG-110-PF-D samples were irradiated with 7 MeV Xe26+ to study their surface topography and microstructure evolution. The impregnation process of PF resin affects the initial graphitization degree of graphite, which lead to the difference in irradiation behavior. Due to the irradiation-induced graphitization, the PF filler (carbonized products of PF resin infiltrated into pores) in pores of IG-110 shrinks after irradiation, which confirmed by the smaller change ratio of crystallite size along the a-axis direction (La) in IG-110-PF and IG-110-PF-D after irradiation than IG-110. La of IG-110-PF-D decreased with the dose increase, resulting from the introduction of irradiation-induced in-plane defects, which is similar to IG-110.The increase in La of PF filler in IG-110-PF and decrease of increase rate in dislocation density after irradiation with surface irradiation dose of 0.02–0.11dpa, provide supporting evidence for the change of PF filler. The difference in irradiation behavior confirms that disordered structure of PF filler and initial crystallinity play an important role in microstructure evolution.
Effects of irradiation on nano-pore phenol-formaldehyde resin infiltrated IG-110 graphite
Iso-molded nuclear graphite (IG-110) was infiltrated with phenol–formaldehyde (PF) resin to get the densified isostatic graphite with different bulk density (IG-110-PF, 1.86 g/cm3 and IG-110-PF-D, 1.91 g/cm3). The IG-110-PF and IG-110-PF-D samples were irradiated with 7 MeV Xe26+ to study their surface topography and microstructure evolution. The impregnation process of PF resin affects the initial graphitization degree of graphite, which lead to the difference in irradiation behavior. Due to the irradiation-induced graphitization, the PF filler (carbonized products of PF resin infiltrated into pores) in pores of IG-110 shrinks after irradiation, which confirmed by the smaller change ratio of crystallite size along the a-axis direction (La) in IG-110-PF and IG-110-PF-D after irradiation than IG-110. La of IG-110-PF-D decreased with the dose increase, resulting from the introduction of irradiation-induced in-plane defects, which is similar to IG-110.The increase in La of PF filler in IG-110-PF and decrease of increase rate in dislocation density after irradiation with surface irradiation dose of 0.02–0.11dpa, provide supporting evidence for the change of PF filler. The difference in irradiation behavior confirms that disordered structure of PF filler and initial crystallinity play an important role in microstructure evolution.
Effects of irradiation on nano-pore phenol-formaldehyde resin infiltrated IG-110 graphite
Heyao Zhang (author) / Jinxing Cheng (author) / Pengfei Lian (author) / Zhao He (author) / Qingbo Wang (author) / Ai Yu (author) / Jinliang Song (author) / zhongfeng Tang (author) / Zhanjun Liu (author)
2022
Article (Journal)
Electronic Resource
Unknown
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