Optical amplifier and multi-core optical fiber

What is claimed is: 1. An optical amplifier comprising: an amplifying multi-core optical fiber including a plurality of first cores each extending along a first center axis and made of silica glass with a rare-earth element added to the silica glass, and first cladding surrounding the individual first cores and made of silica glass having a lower refractive index than all of the first cores, the amplifying multi-core optical fiber having an absorption coefficient of 1 dB/m or greater at a pump wavelength at which the rare-earth element is pumped, and a length such that an inter-core crosstalk of the amplifying multi-core optical fiber is 17 dB or greater at an amplifying wavelength at which the rare-earth element amplifies light; a connecting multi-core optical fiber including a plurality of second cores each extending along a second center axis and optically connected to a corresponding one of the plurality of first cores, the second cores being made of silica glass, and second cladding surrounding the individual second cores and made of silica glass having a lower refractive index than all of the second cores; and a pump light source that supplies pump light at the pump wavelength to the rare-earth element in the plurality of first cores through the connecting multi-core optical fiber, wherein each of the first cores has a diameter of 2 μm to 16 μm, and an interval between centers of adjacent ones of the first cores is 30 μm or smaller. 2. The optical amplifier according to claim 1 , wherein the connecting multi-core optical fiber has a length such that an inter-core crosstalk of the connecting multi-core optical fiber is 17 dB or greater at the pump wavelength, and wherein the pump light supplied from the pump light source pumps the rare-earth element after the pump light is coupled to at least one of the plurality of second cores, is further coupled to remaining ones of the plurality of second cores, and is further coupled from each of the plurality of second cores to a corresponding one of the plurality of first cores that is optically connected to that second core. 3. The optical amplifier according to claim 1 , wherein, in a section of the amplifying multi-core optical fiber that is taken orthogonally to the first center axis, one of the plurality of first cores is positioned on the first center axis, wherein, in a section of the connecting multi-core optical fiber that is taken orthogonally to the second center axis, one of the plurality of second cores is positioned on the second center axis, wherein the pump light source includes a single-core single-mode optical fiber including a third core containing and extending along a third center axis, and third cladding surrounding the third core, and wherein the single-core single-mode optical fiber and the connecting multi-core optical fiber are arranged such that the third core and the second core that is positioned on the second center axis are optically connected to each other, and the pump light is coupled to the remaining cores excluding the second core while being propagated through the connecting multi-core optical fiber. 4. The optical amplifier according to claim 2 , wherein, in a section of the amplifying multi-core optical fiber that is taken orthogonally to the first center axis, one of the plurality of first cores is positioned on the first center axis, wherein, in a section of the connecting multi-core optical fiber that is taken orthogonally to the second center axis, one of the plurality of second cores is positioned on the second center axis, wherein the pump light source includes a single-core single-mode optical fiber including a third core containing and extending along a third center axis, and third cladding surrounding the third core, and wherein the single-core single-mode optical fiber and the connecting multi-core optical fiber are arranged such that the third core and the second core that is positioned on the second center axis are optically connected to each other, and the pump light is coupled to the remaining cores excluding the second core while being propagated through the connecting multi-core optical fiber. 5. The optical amplifier according to any of claim 1 , wherein the amplifying multi-core optical fiber further includes a first resin layer surrounding the first cladding and having a lower refractive index than the first cladding, wherein the connecting multi-core optical fiber further includes a second resin layer surrounding the second cladding and having a lower refractive index than the second cladding, the second cladding being optically connected to the first cladding, and wherein the pump light that is supplied from the pump light source is coupled to the second cladding, is further coupled from the second cladding to the first cladding, and pumps the rare-earth element in the plurality of first cores surrounded by the first cladding. 6. The optical amplifier according to claim 1 , wherein the rare-earth element includes erbium, and wherein the pump wavelength is 980 nm, and the amplifying wavelength is 1550 nm. 7. A multi-core optical fiber comprising: a plurality of cores each extending along a predetermined center axis and made of silica glass with a rare-earth element added to the silica glass; cladding surrounding the individual cores and made of silica glass having a lower refractive index than all of the plurality of cores; and a resin coating surrounding an outer peripheral surface of the cladding, wherein the multi-core optical fiber has a length such that an inter-core crosstalk as an index representing a state of coupling between adjacent ones of the plurality of cores is −17 dB or greater at a wavelength of 1550 nm, each of the cores has a diameter of 2 μm to 16 μm, and an interval between centers of adjacent ones of the plurality of cores is 30 μm or smaller. 8. The multi-core optical fiber according to claim 7 , wherein the plurality of cores include one core extending spirally around and along the center axis.