Passively Q-switched element and passively Q-switched laser device

The invention claimed is: 1. A planar waveguide type passively Q-switched element, comprising: an additive-free transparent material having a planar shape; two saturable absorbers having a planar shape with a refractive index larger than a refractive index of the additive-free transparent material; and two cladding films having a refractive index smaller than the refractive index of the two saturable absorbers, wherein surfaces of the two saturable absorbers are respectively bonded optically to two surfaces of the additive-free transparent material, and wherein the two cladding films are respectively bonded optically to surfaces of the two saturable absorbers opposed to the surfaces bonded to the additive-free transparent material. 2. A passively Q-switched element configured to suppress high-order lasing modes, comprising: an optical material having an end surface through which laser light propagates along an optical axis that extends through the end surface, and a plurality of side surfaces extending in a direction that is along the optical axis; and a first pair of saturable absorbers having an end surface and configured to absorb the laser light transmitted along the optical axis through the end surface and having a refractive index larger than a refractive index of the optical material, wherein each saturable absorber of the first pair of saturable absorbers is optically bonded to a one of the side surfaces such that each saturable absorber of the first pair of saturable absorbers is disposed on opposite sides of the optical material, and wherein the high-order modes are suppressed by the saturable absorbers causing a greater loss to the high-order modes as compared to a loss of low-order modes. 3. The passively Q-switch element of claim 2 , wherein the optical material is a transparent material having a planar shape, and each saturable absorber has a planar shape. 4. The passively Q-switch element of claim 2 , further comprising a pair of cladding films, each of the cladding films having a refractive index smaller than the refractive index of the first pair of saturable absorbers, wherein each of the pair of cladding films are respectively bonded optically to side surfaces of the two saturable absorbers opposed to the side surfaces bonded to the optical material side surfaces. 5. The passively Q-switch element of claim 4 , wherein the optical material has a planar shape, and each saturable absorber has a planar shape. 6. The passively Q-switched element according to claim 2 , wherein the optical material comprises a host material for the saturable absorber. 7. The passively Q-switched element according to claim 2 , wherein the optical material and the saturable absorber are integrally sintered with a ceramics material, integrally bonded through diffusion bonding, or integrally bonded through surface-activated bonding. 8. The passively Q-switched element according to claim 2 , wherein the optical material is cubic shaped. 9. The passively Q-switched element according to claim 2 , wherein the optical material is a laser material. 10. The passively Q-switched element according to claim 9 , wherein the laser material is formed of one of Nd:YAG and Yb:YAG, and the saturable absorber is formed of one of Cr 4+ :YAG and V 3+ :YAG. 11. The passively Q-switched element according to claim 9 , wherein the laser material is formed of one of Er:glass, Er:YAG, and Er:YVO4, and the saturable absorber is formed of one of Co:SPINEL, Co2+:ZnSe, Co2+:ZnS, Cr2+:ZnSe, and Cr2+:ZnS. 12. The passively Q-switched element according to claim 2 , wherein the optical material is a transparent material having a cubic shape. 13. The passively Q-switched element according to claim 12 , further including: a cladding film having a refractive index smaller than the refractive index of the saturable absorber; and a second pair of saturable absorbers having an end surface and configured to absorb the laser light transmitted along the optical axis through the end surface and a refractive index that is approximately equal to refractive index of the first pair of saturable absorbers, each of the second pair of saturable absorbers bonded to the optical material side surface, such that the first pair and the second pair of saturable absorbers extend about a periphery of the optical material; wherein the cladding film is bonded optically to side surfaces of the first and the second pair of saturable absorbers opposed to the optical material side surfaces bonded to the transparent material side surfaces.