Fully ceramic capsulated nuclear fuel composition containing three-layer-structured isotropic nuclear fuel particles with coating layer having higher shrinkage than matrix, material thereof and method for preparing the same

What is claimed is: 1. A fully ceramic capsulated nuclear fuel composition including three-layer-structured isotropic nuclear fuel particles with a coating layer, comprising: three-layer-structured isotropic nuclear fuel particles, a coating layer cladding the nuclear fuel particles, and a matrix phase enveloping the three-layer-structured isotropic nuclear fuel particles having the coating layer, wherein the coating layer is configured to include a silicon carbide precursor, first silicon carbide, and a first sintering additive, wherein the matrix phase is configured to include second silicon carbide and a second sintering additive, and wherein, when a shrinkage of the coating layer of the three-layer-structured isotropic nuclear fuel particles during a pressureless sintering process is given as ΔL C , and when a shrinkage of the matrix phase during the sintering process is given as ΔL m , a condition of ΔL C >ΔL m is satisfied when performing pressure sintering, wherein the silicon carbide precursor is shifted to third silicon carbide in order to densify the coating layer during the pressureless sintering process such that the shrinkage of the coating layer is greater than the shrinkage of the silicon carbide matrix phase. 2. The nuclear fuel composition of claim 1 , wherein an amount of the three-layer-structured isotropic nuclear fuel particles without the coating layer is in the range of 5˜40 volume %. 3. The nuclear fuel composition of claim 1 , wherein the coating layer and the silicon carbide matrix phase are prepared by the pressureless sintering process. 4. The nuclear fuel composition of claim 1 , wherein, when a total composition is given as 100 parts by weight, the coating layer includes the silicon carbide precursor corresponding to 50.0˜90.0 parts by weight, the first silicon carbide used as a filler corresponding to 5.0˜30.0 parts by weight, and the first sintering additive corresponding to 5.0˜20.0 parts by weight. 5. The nuclear fuel composition of claim 4 , wherein the first sintering additive comprises Al 2 O 3 and Y 2 O 3 and at least one member selected from the group consisting of CaO and materials producing CaO by heat treatment. 6. The nuclear fuel composition of claim 1 , wherein the silicon carbide precursor is selected from at least one of polycarbosilane, a mixture of polysiloxane and phenolic resin, or a mixture of polysiloxane and xylene resin, and, wherein, in case of using the mixture of polysiloxane and phenolic resin or the mixture of polysiloxane and xylene resin, a mole ratio of Si:C in thermal decomposition remnants is within a range of 1:1˜1:1.1. 7. The nuclear fuel composition of claim 4 , wherein, when a total composition is given as 100 parts by weight, the composition includes the silicon carbide matrix phase silicon carbide particles corresponding to 85.0˜96.0 parts by weight, and a sintering additive corresponding to 4.0˜15.0 parts by weight. 8. The nuclear fuel composition of claim 7 , wherein the sintering additive corresponds to a structural material including Al 2 O 3 and Y 2 O 3 , further including at least two or more materials selected from CaO and materials being produced by heat treatment of CaO, and including two different positive ions. 9. The nuclear fuel composition of claim 1 , wherein each of the first silicon carbide and the second silicon carbide has a particle size within a range of 0.1˜1 μm.