Increasing attentions have been paid to mineral concentration decrease in milled rice grains caused by CO2 enrichment, but the mechanisms still remain unclear. Therefore, mineral(Ca, Mg, Fe, Zn and Mn) translocation in plant-soil system with a FACE(Free-air CO2 enrichment) experiment were investigated in Eastern China after 4-yr operation. Results mainly showed that:(1) elevated CO2 significantly increased the biomass of stem and panicle by 21.9 and 24.0%, respectively, but did not affect the leaf biomass.(2) Elevated CO2 significantly increased the contents of Ca, Mg, Fe, Zn, and Mn in panicle by 61.2, 28.9, 87.0, 36.7, and 66.0%, respectively, and in stem by 13.2, 21.3, 47.2, 91.8, and 25.2%, respectively, but did not affect them in leaf.(3) Elevated CO2 had positive effects on the weight ratio of mineral/biomass in stem and panicle. Our results suggest that elevated CO2 can favor the translocation of Ca, Mg, Fe, Zn, and Mn from soil to stem and panicle. The CO2-led mineral decline in milled rice grains may mainly attribute to the CO2-led unbalanced stimulations on the translocations of minerals and carbohydrates from vegetative parts(e.g., leaf, stem, branch and husk) to the grains. Increasing attentions have been paid to mineral concentration decrease in milled rice grains caused by CO2 enrichment, but the mechanisms still remain unclear. Thus, mineral (Ca, Mg, Fe, Zn and Mn) translocation in plant-soil system with a FACE -air CO2 enrichment) experiment were investigated in Eastern China after 4-yr operation. Results are showed that: (1) elevated CO2 significantly increased the biomass of stem and panicles by 21.9 and 24.0%, respectively, but did not affect the leaf biomass (2) Elevated CO2 significantly increased the contents of Ca, Mg, Fe, Zn, and Mn in panicles by 61.2, 28.9, 87.0, 36.7 and 66.0% respectively, and in stem by 13.2, 21.3, 47.2, 91.8, (3) Elevated CO2 had positive effects on the weight ratio of mineral / biomass in stem and panicle. Our results suggest that elevated CO2 can favor the translocation of Ca, Mg, 25.2%, respectively, but did not affect them in leaf. Fe, Zn, and Mn from soil to stem and panicle. The CO2-led mineral degradation i n milled rice grains may mainly attribute to the CO2-led unbalanced stimulations on the translocations of minerals and carbohydrates from vegetative parts (eg., leaf, stem, branch and husk) to the grains.