Quasi-single-mode optical fiber with a large effective area

What is claimed is: 1. A quasi-single-mode (QSM) optical fiber, comprising: a core having a centerline and an outer edge, with a peak refractive index n 0 on the centerline and a refractive index n 1 at the outer edge; a cladding section surrounding the core, wherein the cladding section includes an inner annular moat region immediately adjacent the core; wherein the core and cladding section support a fundamental mode LP 01 and a higher-order mode LP 11 and define: i) for the fundamental mode LP 01 : an effective area A eff >170 μm 2 at a wavelength of 1530 nm and an attenuation of no greater than 0.17 dB/km at a wavelength of 1530 nm; ii) for the higher-order mode LP 11 : an attenuation of at least 1.0 dB/km at 1530 nm; and iii) a bending loss of BL<0.02 dB/turn at 1625 nm and for a bend diameter D B =60 mm. 2. The QSM optical fiber according to claim 1 , wherein the core has a radius that is greater than 5 μm. 3. The QSM optical fiber according to claim 2 , wherein the core radius is greater than 7 μm. 4. The QSM optical fiber according to claim 2 , further comprising a 2 m cutoff wavelength λc>1600 nm. 5. The QSM optical fiber according to claim 4 , wherein the first inner annular cladding region has a minimum refractive index n 2 , and wherein the cladding section further includes a moat immediately adjacent the inner annular cladding region and having minimum refractive index n 3 . 6. The QSM optical fiber according to claim 5 , wherein the cladding section further includes a ring immediately adjacent the moat, the ring having a refractive index n R , and wherein n R >n 3 >n 2 . 7. The QSM optical fiber according to claim 6 , wherein the ring includes an absorbing dopant that contribute to the attenuation of the higher-order mode. 8. The QSM optical fiber according to claim 1 , wherein the effective area A eff >200 μm 2 . 9. The QSM optical fiber according to claim 1 , wherein: i) the core is made of potassium-doped silica; ii) the cladding section is made of fluorine-doped silica; and iii) neither the core nor the cladding section includes germanium. 10. The QSM optical fiber according to claim 1 , wherein the attenuation of the fundamental mode LP 01 is no greater than 0.165 dB/km, and wherein for the fundamental mode LP 01 the bending loss BL<0.005 dB/turn at 1625 nm for the bend diameter D B =60 mm. 11. The QSM fiber according to claim 1 , further comprising an axial periodic refractive-index perturbation configured to contribute to the attenuation of the higher-order mode LP 11 while not substantially attenuating the fundamental mode LP 01 . 12. An optical transmission system, comprising: the QSM optical fiber of claim 1 ; an optical transmitter configured to emit light that defines an optical signal that carries information; an optical receiver optically coupled to the optical transmitter by the QSM fiber and configured to receive the light emitted by the optical transmitter and transmitted over the QSM optical fiber in the fundamental mode LP 01 and the higher-order mode LP 11 thereby giving rise to multipath interference (MPI), wherein the optical receiver generates an analog electrical signal from the received light; an analog-to-digital converter (ADC) that converts the analog electrical signal into a corresponding digital electrical signal; and a digital signal processor electrically connected to the ADC and configured to receive and process the digital electrical signal to mitigate the MPI and generate a processed digital signal representative of the optical signal from the optical transmitter. 13. A quasi-single-mode (QSM) optical fiber, comprising: a core having a centerline and a radius r 1 greater than 5 μm, with a peak refractive index n 0 on the centerline and a refractive index n 1 at the radius r 1 ; a cladding section surrounding the core, wherein the cladding section includes a first inner annular cladding region immediately adjacent the core with a minimum refractive index n 2 , a second inner annular cladding region immediately adjacent the first inner annular cladding region and having minimum refractive index n 3 , and a ring immediately adjacent the second inner annular cladding region and having a refractive index n R , wherein n 0 >n 1 >n 3 >n 2 and n R >n 3 >n 2 ; wherein the core and cladding section support a fundamental mode LP 01 and a higher-order mode LP 11 and define: i) for the fundamental mode LP 01 : an effective area A eff >150 μm 2 at a wavelength of 1530 nm and an attenuation of no greater than 0.17 dB/km at a wavelength of 1530 nm; ii) for the higher-order mode LP 11 : an attenuation of at least 1.0 dB/km for the wavelength of 1530 nm; and iii) a bending loss of BL<0.02 dB/turn when the wavelength is 1625 nm and for a bend diameter D B =60 mm. 14. The QSM optical fiber according to claim 13 , wherein the core radius is greater than 7 μm. 15. The QSM optical fiber according to claim 13 , further comprising a 2 m cutoff wavelength λc>1600 nm. 16. The QSM optical fiber according to claim 13 , wherein the effective area A eff >170 μm 2 . 17. The QSM optical fiber according to claim 13 , wherein the attenuation of the fundamental mode LPoi is no greater than 0.165 dB/km. 18. The QSM fiber according to claim 13 , further comprising an axial periodic refractive-index perturbation configured to contribute to the attenuation of the higher-order mode LP 11 while not substantially attenuating the fundamental mode LP 01 . 19. The QSM fiber according to claim 13 , further comprising an LP 01 -to-LP 11 coupling coefficient CC<0.002 km −1 at the wavelength of 1530 nm. 20. An optical transmission system, comprising: the QSM optical fiber of claim 13 ; an optical transmitter configured to emit light that defines an optical signal that carries information; an optical receiver optically coupled to the optical transmitter by the QSM fiber and configured to receive the light emitted by the optical transmitter and transmitted over the QSM optical fiber in the fundamental mode LP 01 and the higher-order mode LP 11 thereby giving rise to multipath interference (MPI), wherein the optical receiver generates an analog electrical signal from the received light; an analog-to-digital converter (ADC) that converts the analog electrical signal into a corresponding digital electrical signal; and a digital signal processor electrically connected to the ADC and configured to receive and process the digital electrical signal to mitigate the MPI and generate a processed digital signal representative of the optical signal from the optical transmitter.