Sold photonic band gap fiber, fiber module using sold photonic band gap fiber, fiber amplifier, and fiber laser

What is claimed is: 1. A solid photonic band gap fiber comprising: a core area located at a central portion of a cross-section with respect to a longitudinal direction of the fiber, the core area being formed of a solid substance having a low refractive index; cladding areas having base portions formed of a solid substance having a low refractive index, the cladding areas surrounding the core area; and a plurality of fine high refractive index scatterers provided in the cladding areas, and disposed in a dispersed manner so as to surround the core area, the fine high refractive index scatterers being formed of a solid substance having a high refractive index, wherein in a state that the solid photonic band gap fiber is held at a predetermined bending radius, propagation in a high-order mode is suppressed by using a difference in a bending loss between a fundamental mode and the high-order mode, and only the fundamental mode is substantially propagated, the fundamental mode and the high-order mode being caused by bending, the high refractive index scatterers are periodically disposed in a triangular grid shape in the cladding areas surrounding the core area, at least four or more layers of the high refractive index scatterers in the periodic structure are provided in a radius direction of the fiber, when the high refractive index scatterers are assumed to be periodically disposed in a triangular grid shape toward a direction other than the radius direction from a central location of a transverse cross-section of the fiber, the core area has an area that corresponds to an area in which two or more layers of the high refractive index scatterers are removed from the central location of the transverse cross-section of the fiber, a triangular grid-shaped periodic gap between the high refractive index scatterers is in a range of 10 μm to 16 μm, and a relative refractive index difference between the high refractive index scatterers and a parent material of the cladding areas is in a range of 1.3% to 3.0%, and a predetermined bending radius is in a range of 90 mm to 200 mm, and an effective core cross-sectional area is 450 μm 2 or more. 2. A solid photonic band gap fiber comprising: a core area located at a central portion of a cross-section with respect to a longitudinal direction of the fiber, the core area being formed of a solid substance having a low refractive index; cladding areas having base portions formed of a solid substance having a low refractive index, the cladding areas surrounding the core area; and a number of fine high refractive index scatterers provided in the cladding areas, and disposed in a dispersed manner so as to surround the core area, the number of fine high refractive index scatterers being formed of a solid substance having a high refractive index, wherein in a state that the solid photonic band gap fiber is held at a predetermined bending radius, propagation in a high-order mode is suppressed by using a difference in a bending loss between a fundamental mode and the high-order mode, and only the fundamental mode is substantially propagated, the fundamental mode and the high-order mode being caused by bending, the high refractive index scatterers are periodically disposed in a triangular grid shape in the cladding areas surrounding the core area, at least four or more layers of the high refractive index scatterers in the periodic structure are provided in a radius direction of the fiber, when the high refractive index scatterers are assumed to be periodically disposed in a triangular grid shape toward a radial-outer direction from a central location of a transverse cross-section of the fiber, the core area has an area that corresponds to an area in which two or more layers of the high refractive index scatterers are removed from the central location of the transverse cross-section of the fiber, a triangular grid-shaped periodic gap between the high refractive index scatterers is in a range of 8 μm to 11 μm, and a relative refractive index difference between the high refractive index scatterers and the base portions of the cladding areas is in a range of 1.5% to 3.0%, and the predetermined bending radius is in a range of 40 mm to 90 mm, and an effective core cross-sectional area is 350 μm 2 or more. 3. The solid photonic band gap fiber according to claim 1 , wherein the core area and the base portions of the cladding areas are constituted by a substance mainly including silica glass, and the high refractive index scatterers are constituted by silica glass to which germanium is added. 4. The solid photonic band gap fiber according to claim 1 , wherein a bending loss of the fundamental mode in a state that the solid photonic band gap fiber is held at the predetermined bending radius is 0.1 dB/m or less, and the bending loss of the high-order mode is 3 dB/m or more. 5. The solid photonic band gap fiber according to claim 1 , wherein an operating waveband is set in a first permeation band of the solid photonic band gap fiber. 6. The solid photonic band gap fiber according to claim 1 , wherein the bending loss of the fundamental mode is 0.1 dB/m or less, and the bending loss of the high-order mode is 10 dB/m or more by holding the bending radius in a range of 40 mm to 200 mm. 7. The solid photonic band gap fiber according to claim 5 , wherein a normalized frequency is used at a wavelength in a range of 1.2 to 2.0. 8. The solid photonic band gap fiber according to claim 1 , further comprising: an outside cladding layer having a low refractive index, the outside cladding layer being provided at an outside of the cladding areas. 9. The solid photonic band gap fiber according to claim 8 , wherein the outside cladding layer is formed of a polymer cladding. 10. The solid photonic band gap fiber according to claim 8 , wherein the outside cladding layer is formed of an air cladding or a holey cladding. 11. The solid photonic band gap fiber according to claim 1 , wherein a material of the core area includes a fluorescent element. 12. The solid photonic band gap fiber according to claim 11 , wherein the fluorescent element is a rare earth element. 13. The solid photonic band gap fiber according to claim 12 , wherein the rare earth fluorescent element is ytterbium. 14. An optical fiber module, wherein at least some of the solid photonic band gap fiber of claim 1 is held at a predetermined bending radius. 15. An optical fiber module, wherein the solid photonic band gap fiber of claim 1 is wound at a predetermined radius into a coil shape. 16. An optical fiber laser or a fiber amplifier comprising: a component which is the solid photonic band gap fiber according to claim 1 or an optical fiber module, the optical fiber module being the solid photonic band gap fiber according to claim 1 in which at least some of the solid photonic band gap fiber is held at a predetermined bending radius or the solid photonic band gap fiber of claim 1 wound at a predetermined radius into a coil shape.