Ceramic electronic component and method of manufacturing the same

What is claimed is: 1 . A ceramic electronic component comprising: a multilayer chip having a substantially rectangular parallelepiped shape and including dielectric layers and internal electrode layers that are alternately stacked, the internal electrode layers being alternately exposed to two edge faces of the multilayer chip facing each other; and a pair of external electrodes respectively formed on the two edge faces so as to be connected to the internal electrode layers exposed on the respective edge faces, each external electrode extending to at least one side face of the multilayer chip, wherein in the multilayer chip, oxides including Zn and Ni are present around the internal electrode layer in a vicinity of a connection part connecting the internal electrode layer to the external electrode. 2 . The ceramic electronic component according to claim 1 , wherein: the external electrodes each includes a base conductive layer and a plated layer thereon, and in the internal electrode layer, a diffusion length of a main component of the base conductive layer, as measured along the internal electrode layer inwardly from the edge face is 5 μm or less. 3 . The ceramic electronic component according to claim 1 , wherein the internal electrode layer has an average thickness of 0.5 μm or less. 4 . A method of manufacturing a ceramic electronic component, comprising: alternately stacking green sheets for ceramic dielectric layers and first conductive pastes for internal electrode layers so that the internal electrode layers are alternately exposed to two edge faces facing each other so as to form a ceramic multilayer structure having a substantially rectangular parallelepiped shape, the first conductive pastes being mainly composed of Ni; firing the ceramic multilayer structure to form a multilayer chip; subjecting the multilayer chip to heat treatment; disposing a second conductive paste on each of the two edge faces of the multilayer chip such that the second conductive paste is in contact with the internal electrode layers exposed to the corresponding edge face, the second conductive paste containing metal powder and a glass component including 20 to 30 weight % of ZnO; and baking the second conductive paste to form oxides including Zn and Ni around each of the internal electrode layers in a vicinity of a connection part between the internal electrode layer and the second conductive paste. 5 . A method of manufacturing a ceramic electronic component, comprising: alternately stacking green sheets for ceramic dielectric layers and first conductive pastes for internal electrode layers so that the internal electrode layers are alternately exposed to two edge faces facing each other so as to form a ceramic multilayer structure having a substantially rectangular parallelepiped shape, the first conductive pastes being mainly composed of Ni; firing the ceramic multilayer structure to form a multilayer chip; disposing a second conductive paste on each of the two edge faces of the multilayer chip such that the second conductive paste is in contact with the internal electrode layers exposed to the corresponding edge face, the second conductive paste containing metal powder and a glass component including 20 to 30 weight % of ZnO; and baking the second conductive paste while an oxygen concentration in a temperature rising region is made to be 10 ppm or greater, to form oxides including Zn and Ni around each of the internal electrode layers in a vicinity of a connection part between the internal electrode layer and the second conductive paste. 6 . A method of manufacturing a ceramic electronic component, comprising: alternately stacking green sheets for ceramic dielectric layers and first conductive pastes for internal electrode layers so that the internal electrode layers are alternately exposed to two edge faces facing each other so as to form a ceramic multilayer structure having a substantially rectangular parallelepiped shape, the first conductive pastes being mainly composed of Ni; firing the ceramic multilayer structure to form a multilayer chip; applying a glass paste containing 20 to 30 weight % of ZnO to each of the two edge faces of the multilayer chip; baking the glass paste to form oxides including Zn and Ni around each of the internal electrode layers adjacent to the two edge faces; disposing a second conductive paste on each of the two edge faces of the multilayer chip such that the second conductive paste is in contact with the internal electrode layers exposed to the corresponding edge face, the second conductive paste containing metal powder and a glass component; and baking the second conductive paste.