Sliding member and method for producing same

The invention claimed is: 1. A sliding member, comprising an iron and steel-based sintered compact containing chromium, molybdenum, and carbon and having a content of chromium of 5 mass % or less, wherein the sintered compact comprises: a compound layer which has a sliding surface and is formed mainly of an iron and steel nitride; and a diffusion layer which is adjacent to the compound layer and has an iron and steel structure into which nitrogen and carbon diffuse, wherein concentrations of carbon and nitrogen in the diffusion layer of the sintered compact are gradually reduced with increasing depth from the sliding surface, wherein a hardness of the compound layer is from 850 HV to 1,000 HV, and wherein the sintered compact has a relative density of 90% or more. 2. The sliding member according to claim 1 , wherein a concentration of carbon at an interface between the compound layer and the diffusion layer is 0.6 mass % or more. 3. A sliding member, comprising an iron and steel-based sintered compact containing chromium, molybdenum, and carbon and having a content of chromium of 5 mass % or less, wherein the sintered compact comprises: a compound layer which has a sliding surface and is formed mainly of an iron and steel nitride; and a diffusion layer which is adjacent to the compound layer and has an iron and steel structure into which nitrogen and carbon diffuse, wherein a hardness of the sintered compact is gradually reduced with increasing depth from the sliding surface, wherein a curve representing the hardness of the sintered compact as a function of a depth from the sliding surface has, in a region in a depth direction of the diffusion layer, a region having a lower gradient than regions on both sides thereof in the depth direction, wherein a hardness of the compound layer is from 850 HV to 1,000 HV, and wherein the sintered compact has a relative density of 90% or more. 4. A production method for a sliding member, comprising the steps of: forming a green compact through use of raw material powder containing chromium-molybdenum-based alloy steel powder having a content of chromium of 5 mass % or less and carbon powder; sintering the green compact to provide a sintered compact; subjecting the sintered compact to carburizing treatment to allow carbon to penetrate and diffuse into a surface layer of the sintered compact, followed by subjecting the sintered compact to quenching; and subjecting the sintered compact to nitriding treatment to allow nitrogen to penetrate and diffuse into the surface layer of the sintered compact so as to form a compound layer which has a sliding surface and is formed mainly of an iron and steel nitride, in the stated order, wherein a hardness of the compound layer is from 850 HV to 1,000 HV, and wherein the sintered compact has a relative density of 90% or more. 5. The production method for a sliding member according to claim 4 , wherein the nitriding treatment comprises salt-bath nitrocarburizing treatment. 6. The production method for a sliding member according to claim 4 , further comprising, before the subjecting the sintered compact to nitriding treatment, subjecting the sintered compact to grinding work to form a sliding surface. 7. A production method for a sliding member, comprising the steps of: forming a green compact through use of raw material powder containing chromium-molybdenum-based alloy steel powder having a content of chromium of 5 mass % or less and carbon powder; sintering the green compact to provide a sintered compact, and at the same time, subjecting the sintered compact to carburizing treatment to allow carbon to penetrate and diffuse into a surface layer of the sintered compact, followed by subjecting the sintered compact to quenching; and subjecting the sintered compact to nitriding treatment to allow nitrogen to penetrate and diffuse into the surface layer of the sintered compact so as to form a compound layer which has a sliding surface and is formed mainly of an iron and steel nitride, in the stated order, wherein a hardness of the compound layer is from 850 HV to 1,000 HV, and wherein the sintered compact has a relative density of 90% or more.