Stabilizer and method for manufacturing stabilizer

The invention claimed is: 1. A stabilizer comprising: a main body cylinder portion which is elastically deformable; and a pair of connection plate portions respectively connected to a pair of left and right suspension devices, wherein each connection plate portion of the pair of connection plate portions includes a pair of base material portions located on both sides in the connection plate portion in a plate thickness direction and an alloy oxide region which is disposed between the pair of base material portions and in which alloy oxides are scattered, wherein crystal grains constituting the pair of base material portions straddle the alloy oxide region in the plate thickness direction and the pair of base material portions are joined, wherein the connection plate portion is made of a Fe alloy containing an easily oxidizable element that is more easily oxidized than Fe, and wherein the alloy oxides are made by combining oxygen, which is obtained by reducing Fe oxides present on an inner peripheral surface of the base material portions prior to joining, and the easily oxidizable element. 2. The stabilizer according to claim 1 , wherein the Fe alloy contains at least one of Si, Mn, and Cr. 3. A method for manufacturing the stabilizer according to claim 1 , the method comprising: a heating step of heating both end portions of a steel pipe; and a forging step of radially crushing both end portions of the heated steel pipe to form the pair of connection plate portions, wherein in the heating step, both end portions of the steel pipe are simultaneously heated, wherein the steel pipe is made of an Fe alloy containing an easily oxidizable element that is more easily oxidized than Fe, and wherein the heating step includes an oxygen reduction step of forming Fe oxides on inner peripheral surfaces of both end portions of the steel pipe and reducing the amount of oxygen contained in air inside both end portions of the steel pipe and a reduction step of causing a reduction reaction in the Fe oxides by using the easily oxidizable element as a reducing agent and removing oxygen from the Fe oxides. 4. The method for manufacturing a stabilizer according to claim 3 , wherein in the heating step, both end portions of the steel pipe are heated while the steel pipe is positioned such that a portion of the steel pipe located on a center side in a longitudinal direction in relation to both end portions of the steel pipe and including at least a center portion of the steel pipe in the longitudinal direction is substantially horizontal. 5. The method for manufacturing a stabilizer according to claim 3 , wherein both end portions of the steel pipe are located at the lowest position in the steel pipe in the heating step. 6. The method for manufacturing a stabilizer according to claim 4 , wherein both end portions of the steel pipe are located at the lowest position in the steel pipe in the heating step.