298. Flux level effects on irradiation damage in graphite

The changes in dimensions and lattice parameters produced by irradiation in two reactors with very different dose rate have been studied over the temperature range 400-700°C. In this range it is found that the activation energy associated with the equivalent temperature concept is not constant. It i

Ah&net-Samples of highly oriented pyrolytic graphite doped substitutionally with B" to concentrations of 1100, 35,s and S2 ppm have been irradiated to doses of I,2 and 3 x lOI n/cm\* (Ni5\* (n, p) CoS8) at a temperature of 60°C. It is observed that the crystallite growth parallel to the hexagonal ax

The changes in the physical properties of British reactor grade graphite induced by highflux fast-neutron irradiation, under closely controlled conditions of temperature and flux, llave been studied to higher doses than those previously published. Irradiation-induced changes in thermal conductivity

kinematical theory of diffraction contrast has been applied to distinguish between vacancy and interstitial clusters. Interstitial clusters are the only ones which have been positively identified. The annealing of the clusters of defects has been studied in detail and activation energies derived. Th

## Samples of Pile Grade A and Gilsocarbon nuclear graphites as used in the United Kingdom Gas-cooled Reactors have been heat-treated to a final temperature of 34OO"C, compared to the normal values of -2800°C. The behaviour of these materials has been compared with standard material under neutron

part of a joint (Dragon/KFA/Euratom/RCN) irradiation programme in the HFR Petten, The Netherlands, extensive data were obtained on the irradiation behaviour at 8 temperature levels between 400 and 1400°C of 10 different Gilsocarbon graphites. A computer technique was used to systematize and compare