Laser device and method for operating laser device

What is claimed is: 1 . A laser device comprising: a traveling wave type resonator comprising a first mirror and a second mirror; and a laser medium disposed between the first mirror and the second mirror, wherein: the first mirror and the second mirror are disposed such that round-trip light that travels in round trips in the resonator has a focus inside the laser medium; the laser device is configured such that: excitation light incident on the resonator is superimposed on the round-trip light at the focus and narrowed to be thinner than the round-trip light, Z R ×α<0.5 is satisfied, where Z R is a Rayleigh length of the excitation light and a is an absorption coefficient of the laser medium with respect to the excitation light, and a round-trip Gouy phase shift of the resonator has a value excluding 2π×n/m where m is an integer of less than 15 and n is an integer of equal to or less than m. 2 . The laser device according to claim 1 , wherein: L×α>1.89 is satisfied where L is an effective length of the laser medium with respect to the excitation light. 3 . The laser device according to claim 1 , wherein: the laser device comprises a temperature control mechanism configured to control a temperature of the laser medium. 4 . The laser device according to claim 3 , wherein: the temperature control mechanism includes a holder configured to hold the laser medium, and a temperature adjuster configured to adjust a temperature of the holder. 5 . The laser device according to claim 3 , wherein: the temperature control mechanism is configured to cause, by absorption of the excitation light, recovery of a multi-mode of the round-trip light that passes through the laser medium. 6 . The laser device according to claim 1 , wherein: the laser device further comprises a seed light source configured to cause seed light to be incident on the resonator; and a longitudinal mode adjustment circuit configured to control a resonator length of the resonator to be integer times a wavelength of the seed light. 7 . The laser device according to claim 1 , wherein: a slope efficiency of the laser device, represented by a ratio of an output light power increment with respect to an excitation light power increment, is higher in a second power region in which an excitation light power is higher than a predetermined level compared to a first power region in which the excitation light power is equal to or less than the predetermined level. 8 . The laser device according to claim 7 , wherein: the slope efficiency in the first power region is equal to or greater than 30% and less than 40%. 9 . The laser device according to claim 7 , wherein: the slope efficiency in the second power region is in a range of 45% to 60%. 10 . A method for operating a laser device, the method comprising: providing a traveling wave type resonator comprising a first mirror and a second mirror, and a laser medium between the first mirror and the second mirror, wherein the first mirror and the second mirror are disposed such that round-trip light that travels in round trips in the resonator has a focus inside the laser medium; causing excitation light to be incident on the resonator such that the excitation light is superimposed on the round-trip light at the focus and narrowed to be thinner than the round-trip light; and performing control such that: a round-trip Gouy phase shift of the resonator has a value excluding 2π×n/m, where m is an integer of less than 15 and n is an integer of equal to or less than m, and Z R ×α<0.5 is satisfied where a Rayleigh length of the excitation light is Z R and an absorption coefficient of the laser medium with respect to the excitation light is α. 11 . The method for operating a laser device according to claim 10 , wherein: the laser device operates under a condition of L×α>1.89, where L is an effective length of the laser medium with respect to the excitation light. 12 . The method for operating a laser device according to claim 10 , further comprising: condensing the excitation light by a thermal lens generated in the laser medium. 13 . The method for operating a laser device according to claim 12 , further comprising: increasing power of the excitation light, shortening a focal length of the thermal lens, and setting a round-trip Gouy phase shift of the resonator closer to 3π/2; and further increasing the power of the excitation light, shortening the focal length of the thermal lens, and further increasing the round-trip Gouy phase shift from 3π/2.