Manufacturing method of blazed diffraction grating and mold for making a blazed difraction grating

What is claimed is: 1. A diffraction grating having a plurality of gratings, the diffraction grating comprising: a first surface; and a second surface shorter than the first surface in a cross section, wherein the grating is a Blazed type, wherein a protruded step is formed between two adjacent gratings, wherein the protruded step has a surface adjacent to the second surface, wherein the surface adjacent to the second surface of the protruded step is shorter than the second surface in the cross section, wherein an extension of the surface adjacent to the second surface of the protruded step does not cross the first surface, wherein the plurality of gratings generate a diffracted light by diffracting an incident light having a predetermined incident angle to the plurality of gratings from a blazed direction of the diffraction grating, and wherein the protruded step is shaped so that the incident light having the predetermined incident angle does not reach the protruded step and does not generate the diffracted light. 2. A diffraction method using a diffraction grating having a plurality of gratings, the method comprising: making light incident to the plurality of gratings; and diffracting the incident light by the plurality of gratings, wherein the diffraction grating comprises a first surface; and a second surface shorter than the first surface in a cross section, wherein the grating is a Blazed type, wherein a protruded step is formed between two adjacent gratings, wherein the protruded step has a surface adjacent to the second surface, wherein the surface adjacent to the second surface of the protruded step is shorter than the second surface in the cross section, wherein an extension of the surface adjacent to the second surface of the protruded step does not cross the first surface, wherein, in the diffracting, the plurality of gratings generate a diffracted light by diffracting the incident light on a predetermined incident angle to the plurality of gratings from a blazed direction of the diffraction grating, and wherein the protruded step is shaped so that the incident light having the predetermined incident angle does not reach the protruded step and does not generate the diffracted light. 3. The diffraction grating according to claim 1 , wherein the diffraction grating is an Echelle diffraction grating. 4. The diffraction grating according to claim 1 , wherein a specific high propagating diffraction order in laser light is Blazed for each wavelength, and a Blazed order is higher than a 50 th order. 5. The diffraction grating according to claim 1 , wherein the step is formed by, after forming the first surface through cutting processing using a blade of a cutting tool, forming the second surface through cutting processing using a blade of the cutting tool so that the cutting tool does not contact the first surface. 6. The diffraction grating according to claim 1 , wherein the step is formed by, after forming the first surface through cutting processing using a first blade of a cutting tool having the first blade and a second blade, forming the second surface through cutting processing using the second blade of the cutting tool so that the first blade does not contact the first surface. 7. The diffraction grating according to claim 1 , wherein the incident light on the second surface of the grating is diffracted. 8. The diffraction grating according to claim 1 , wherein the protruded step is formed by cutting processing of the second surface using a blade of a cutting tool. 9. The diffraction grating according to claim 4 , wherein the laser light is emitted from an ArF excimer laser, and the Blazed order is higher than a 90 h order. 10. The diffraction grating according to claim 4 , wherein the laser light is emitted from a KrF excimer laser, and the Blazed order is higher than a 60 h order.