We report on the substantial advancement of long wavelength InAs-based interband cascade lasers (ICLs) utilizing advanced waveguides formed from hybrid cladding layers and targeting the 10-12 µm wavelength region. Modifications in the hole injector have improved carrier transport in these ICLs, resulting in significantly reduced threshold voltages as low as 3.62 V at 80 K. Consequently, much higher voltage efficiencies were observed, peaking at about 73% at 10.3 µm and allowing for large output powers of more than 100 mW/facet. Also, low threshold current densities of 8.8 A/cm 2 in cw mode and 7.6 A/cm 2 in pulsed mode near 10 µm were observed. Furthermore, ICLs from the second wafer lased beyond 12 µm in both cw and pulsed modes, representing a new milestone for ICLs with the standard W-QW active region. The demonstrated ICLs can help to develop efficient instruments for many applications such as chemical sensing and medical diagnostics.

We report on the substantial advancement of long wavelength InAs-based interband cascade lasers (ICLs) utilizing advanced waveguides formed from hybrid cladding layers and targeting the 10- $12~\mu \text{m}$ wavelength region. Modifications in the hole injector have improved carrier transport in these ICLs, resulting in significantly reduced threshold voltages ( $\text{V}_{\text {th}}$ ) as low as 3.62 V at 80 K. Consequently, much higher voltage efficiencies were observed, peaking at about 73% at $10.3~\mu \text{m}$ and allowing for large output powers of more than 100 mW/facet. Also, low threshold current densities ( $\text{J}_{\text {th}}$ ) of 8.8 A/cm2 in cw mode and 7.6 A/cm2 in pulsed mode near $10~\mu \text{m}$ were observed; a result of adjustments in the GaInSb hole well composition intended to reduce the overall strain accumulation in the ICL. Furthermore, an ICL from the second wafer operating at a longer wavelength achieved a peak voltage efficiency of 57% at $11.7~\...