Abstract: A single-mode optical device, including a first region, and a second region laterally disposed about the first region, and including an absorbing layer and an isolation layer between the absorbing layer and the first region, wherein the thickness of the isolation layer is selected to control optical loss from the first region to the absorbing layer in the second region and thereby to attenuate one or more high order lateral optical modes of the device. The one or more high order lateral optical modes are attenuated relative to the fundamental lateral mode to provide the device with a high kink power. The device can be a 980 nm ridge diode laser where the thickness of an oxide insulating layer around the ridge is selected to control optical losses into a gold contact layer and thereby attenuate the first order lateral mode, providing the laser with a kink power of at least about 250 mW.

Abstract: A diode laser formed by a plurality of layers including n-type layers and p-type layers, the plurality of layers having a substantially asymmetric refractive index profile with respect to the layer growth direction so as to generate an optical field distribution with a larger fraction in n-type layers than in p-type layers, and configured to generate a beam with a divergence of less than about 28° in the growth direction. The layers include an active layer for generating the optical field, a trap layer for attracting the optical field, and a separation layer between the active layer and the trap layer for repelling the optical field. The laser can be configured to have an internal loss of about 1.2 cm?1 or less, and to generate a laser beam with a spot size of at least about 1.1 ?m and a divergence of approximately 13° in the growth direction. If the length of the laser is at least about 1 mm, the threshold current density of the laser can be less than about 400 A cm?2.

Abstract: A single-mode optical device, including a first region, and a second region laterally disposed about the first region, and including an absorbing layer and an isolation layer between the absorbing layer and the first region, wherein the thickness of the isolation layer is selected to control optical loss from the first region to the absorbing layer in the second region and thereby to attenuate one or more high order lateral optical modes of the device. The one or more high order lateral optical modes are attenuated relative to the fundamental lateral mode to provide the device with a high kink power. The device can be a 980 nm ridge diode laser where the thickness of an oxide insulating layer around the ridge is selected to control optical losses into a gold contact layer and thereby attenuate the first order lateral mode, providing the laser with a kink power of at least about 250 mW.

Abstract: A diode laser formed by a plurality of layers including n-type layers and p-type layers, the plurality of layers having a substantially asymmetric refractive index profile with respect to the layer growth direction so as to generate an optical field distribution with a larger fraction in n-type layers than in p-type layers, and configured to generate a beam with a divergence of less than about 28° in the growth direction. The layers include an active layer for generating the optical field, a trap layer for attracting the optical field, and a separation layer between the active layer and the trap layer for repelling the optical field. The laser can be configured to have an internal loss of about 1.2 cm−1 or less, and to generate a laser beam with a spot size of at least about 1.1 &mgr;m and a divergence of approximately 13° in the growth direction. If the length of the laser is at least about 1 mm, the threshold current density of the laser can be less than about 400 A cm−2.