Amplifying optical fiber and optical amplifier

The invention claimed is: 1. An amplifying optical fiber comprising: a plurality of cores to which an active element is doped; a first cladding enclosing the plurality of cores with no gap; and a second cladding enclosing the first cladding, wherein: the plurality of cores is disposed around a center axis of the first cladding in a state in which an inter-core distance between cores adjacent to each other is equal; a refractive index of the core is provided higher than a refractive index of the first cladding; the refractive index of the first cladding is provided higher than a refractive index of the second cladding; and an expression below is satisfied: 5.8≦Λ/MFD(2λ c /(λ c+λop ))≦8 where the inter-core distance is defined as Λ, a mode field diameter of the core is defined as MFD, a cutoff wavelength is defined as λc, and a wavelength of communication light incident on the core is defined as λop. 2. The amplifying optical fiber according to claim 1 , wherein: the first cladding has a two-layer structure formed of a solid inner layer passed through the center axis of the first cladding and an outer layer enclosing the inner layer and the plurality of cores with no gap; and a refractive index of the inner layer is provided lower than a refractive index of the outer layer. 3. The amplifying optical fiber according to claim 2 , wherein an area other than the center axis of the first cladding on one end face of the first cladding is an incident point of pumping light. 4. The amplifying optical fiber according to claim 3 , wherein an outer layer area on one end face of the first cladding is an incident point of the pumping light. 5. The amplifying optical fiber according to claim 4 , wherein an area other than a inner layer area located on an inner side with respect to the plurality of cores is an incident point of pumping light in the outer layer area. 6. An optical amplifier comprising: an amplifying optical fiber including: a plurality of cores to which an active element is doped; a first cladding enclosing the plurality of cores with no gap; and a second cladding enclosing the first cladding; a pumping light source configured to emit pumping light for pumping the active element; a plurality of single core optical fibers to which communication light is entered; and an optical Fan-In configured to enter communication light incident on cores of the plurality of single core optical fibers to an end face of a core of the amplifying optical fiber corresponding to the core and to enter pumping light source emitted from the pumping light to a predetermined position on one end face of the amplifying optical fiber, wherein: the plurality of cores is disposed around a center axis of the first cladding in a state in which an inter-core distance between cores adjacent to each other is equal; a refractive index of the core is provided higher than a refractive index of the first cladding; the refractive index of the first cladding is provided higher than a refractive index of the second cladding; and an expression below is satisfied: 5.8≦Λ/MFD(2λ c /(λ c+λop ))≦8 where the inter-core distance is defined as Λ, a mode field diameter of the core is defined as MFD, a cutoff wavelength is defined as λc, and a wavelength of communication light incident on the core is defined as λop. 7. The optical amplifier according to claim 6 , wherein: the first cladding has a two-layer structure formed of a solid inner layer passed through the center axis of the first cladding and an outer layer enclosing the inner layer and the plurality of cores with no gap; a refractive index of the inner layer is provided lower than a refractive index of the outer layer; and the optical Fan-In enters the pumping light to an area other than the center axis of the first cladding on one end face of the first cladding. 8. The optical amplifier according to claim 7 , wherein the optical Fan-In enters the pumping light to an outer layer area on one end face of the first cladding. 9. The optical amplifier according to claim 8 , wherein the optical Fan-In enters the pumping light to an area other than a inner layer area on an inner side with respect to the plurality of cores in the outer layer area.