Multilayer ceramic capacitor

What is claimed is: 1. A multilayer ceramic capacitor comprising: a ceramic body including inner electrodes and ceramic dielectric layers alternatively stacked on each other in a stacking direction; and a pair of outer electrodes located on predetermined areas of the ceramic body; wherein the ceramic body includes first and second main surfaces opposing each other in the stacking direction, first and second end surfaces opposing each other in a length direction, and first and second side surfaces opposing each other in a width direction; the pair of outer electrodes include a first outer electrode covering at least the first end surface and a second outer electrode covering at least the second end surface; at least one first auxiliary electrode is located between the first main surface and one of the inner electrodes closest to the first main surface; and at least one second auxiliary electrode is located between the second main surface and one of the inner electrodes closest to the second main surface; some of the inner electrodes include a first effective portion and a first extension portion extending from the first effective portion toward the first end surface and electrically connecting to the first outer electrode, and others of the inner electrodes include a second effective portion and a second extension portion extending from the second effective portion toward the second end surface and electrically connecting to the second outer electrode; a thickness of each end portion of the first extension portion is larger than a thickness of each middle portion of the first extension portion, and a thickness of each end portion of the second extension portion is larger than a thickness of each middle portion of the second extension portion; a distance from the first main surface to the first auxiliary electrode closest to the first main surface is different from a distance from the second main surface to the second auxiliary electrode closest to the second main surface in the stacking direction; a dimension in the stacking direction of each of end portions of the first auxiliary electrode in a width direction of the first auxiliary electrode is larger than a dimension in the stacking direction of a middle portion of the first auxiliary electrode in the width direction of the first auxiliary electrode by about 1% or more of the dimension in the stacking direction of the middle portion of the first auxiliary electrode in the width direction of the first auxiliary electrode; and a dimension in the stacking direction of each of end portions of the second auxiliary electrode in a width direction of the second auxiliary electrode is larger than a dimension in the stacking direction of a middle portion of the second auxiliary electrode in the width direction of the second auxiliary electrode by about 1% or more of the dimension in the stacking direction of the middle portion of the second auxiliary electrode in the width direction of the second auxiliary electrode. 2. A multilayer ceramic capacitor comprising: a ceramic body including inner electrodes and ceramic dielectric layers alternatively stacked on each other in a stacking direction; and a pair of outer electrodes located on predetermined areas of the ceramic body; wherein the ceramic body includes first and second main surfaces opposing each other in the stacking direction, first and second end surfaces opposing each other in a length direction, and first and second side surfaces opposing each other in a width direction; the pair of outer electrodes include a first outer electrode covering at least the first end surface and a second outer electrode covering at least the second end surface; at least one first auxiliary electrode having a continuity in the width direction of about 60% or more is located between the first main surface and one of the inner electrodes closest to the first main surface; at least one second auxiliary electrode having a continuity in the width direction of about 60% or more is located between the second main surface and one of the inner electrodes closest to the second main surface; some of the inner electrodes include a first effective portion and a first extension portion extending from the first effective portion toward the first end surface and electrically connecting to the first outer electrode, and others of the inner electrodes include a second effective portion and a second extension portion extending from the second effective portion toward the second end surface and electrically connecting to the second outer electrode; a thickness of each end portion of the first extension portion is larger than a thickness of each middle portion of the first extension portion, and a thickness of each end portion of the second extension portion is larger than a thickness of each middle portion of the second extension portion; and a distance from the first main surface to the first auxiliary electrode closest to the first main surface is different from a distance from the second main surface to the first auxiliary electrode closest to the second main surface in the stacking direction; a first boundary layer including Mg and Mn and having a dimension of about 69% or more of a dimension of the first auxiliary electrode in the length direction is located between the first main surface and the first auxiliary electrode; a second boundary layer including Mg and Mn and having a dimension of about 69% or more of a dimension of the second auxiliary electrode in the length direction is located between the second main surface and the second auxiliary electrode; a dimension in the stacking direction of each of end portions of the first auxiliary electrode in a width direction of the first auxiliary electrode is larger than a dimension in the stacking direction of a middle portion of the first auxiliary electrode in the width direction of the first auxiliary electrode by about 1% or more of the dimension in the stacking direction of the middle portion of the first auxiliary electrode in the width direction of the first auxiliary electrode; and a dimension in the stacking direction of each of end portions of the second auxiliary electrode in a width direction of the second auxiliary electrode is larger than a dimension in the stacking direction of a middle portion of the second auxiliary electrode in the width direction of the second auxiliary electrode by about 1% or more of the dimension in the stacking direction of the middle portion of the second auxiliary electrode in the width direction of the second auxiliary electrode. 3. The multilayer ceramic capacitor according to claim 2 , wherein each molar ratio of a content of Mn to a content of Mg in the first boundary layer and the second boundary layer is in a range of about 0.015 to about 0.6. 4. The multilayer ceramic capacitor according to claim 3 , wherein each of the inner electrodes include an end portion and a middle portion extending in the width direction; a continuity of each of the end portions of the inner electrodes in the width direction is higher than a continuity of a corresponding one of the middle portion of the inner electrodes in the width direction. 5. The multilayer ceramic capacitor according to claim 4 , wherein a first outermost ceramic dielectric layer of the ceramic dielectric layers includes the first main surface; a second outermost ceramic dielectric layer of the ceramic dielectric layers includes the second main surface; wherein a thickness of an end portion of the first outermost ceramic dielectric layer facing the end portion of the one of the inner electrodes closest to the first main surface is smaller than a thickness of a middle portion of the first outermost ceramic dielectric layer facing the middle portion of the one of the inner electrodes clo