Angled facet broad-ridge quantum cascade laser

What is claimed is: 1. A quantum cascade laser comprising: a ridge-guide comprising: an angled facet that extends across a width of the ridge-guide; and a flat facet that extends across the width of the ridge-guide, wherein a first distance between the flat facet and the angled facet along a first side of the ridge-guide is different than a second distance between the flat facet and the angled facet along a second side of the ridge-guide; wherein the angled facet is configured to emit output light in response to current injection into the ridge-guide; and wherein the output light forms a single lobe in a farfield. 2. The quantum cascade laser of claim 1 , wherein the output light corresponds to an optical standing wave that extends between the angled facet and the flat facet. 3. The quantum cascade laser of claim 1 , wherein the single lobe is formed in a direction that extends across the width of the ridge-guide. 4. The quantum cascade laser of claim 1 , further comprising a substrate coupled to a surface of the ridge-guide perpendicular to the width of the ridge-guide and perpendicular to a direction corresponding to the first distance. 5. The quantum cascade laser of claim 4 , wherein a surface of the ridge-guide opposite the substrate is gold plated. 6. The quantum cascade laser of claim 1 , wherein the flat facet, the first side, and the second side are coated with a high-reflection coating. 7. The quantum cascade laser of claim 1 , wherein the angled facet is formed by removing a portion of the ridge-guide. 8. The quantum cascade laser of claim 7 , wherein the portion of the ridge-guide is removed using a focused ion-milling process, an etching process, or a combination thereof. 9. A method comprising: receiving current at a ridge-guide of a quantum cascade laser, wherein the ridge-guide comprises a flat facet that extends across a width of the ridge-guide and an angled facet that extends across the width of the ridge-guide, and wherein a first distance between the flat facet and the angled facet along a first side of the ridge-guide is different than a second distance between the flat facet and the angled facet along a second side of the ridge-guide; emitting output light from the angled facet of the ridge-guide in response to receiving the current; and wherein the output light corresponds to an optical standing wave that extends between the angled facet and the flat facet and reflects off the first side and reflects off the second side. 10. The method of claim 9 , wherein the output light forms a single lobe in a farfield. 11. The method of claim 10 , wherein the single lobe is formed in a direction that extends across the width of the ridge-guide. 12. The method of claim 9 , wherein the output light forms multiple lobes in a farfield. 13. The method of claim 9 , wherein the optical standing wave intersects with the angled facet at a position between the first side and the second side. 14. The method of claim 13 , wherein the position is halfway between a midpoint of the width of the ridge-guide and the first side. 15. The method of claim 9 , wherein the optical standing wave intersects with the angled facet at a right angle. 16. An infrared countermeasure (IRCM) system comprising: a warning sensor configured to detect a threat; a tracking sensor configured, in response to receiving a threat indicator from the warning sensor, to acquire a position of the threat and to track the position of the threat; and an angled facet quantum cascade laser (AF-QCL) configured to transmit output light energy to the position of the threat based on a tracking signal received from the tracking sensor, the AF-QCL comprising: a ridge-guide comprising: an angled facet that extends across a width of the ridge-guide; and a flat facet that extends across the width of the ridge-guide, wherein a first distance between the flat facet and the angled facet along a first side of the ridge-guide is different than a second distance between the flat facet and the angled facet along a second side of the ridge-guide; and wherein the flat facet, the first side, and the second side are coated with a high-reflection coating. 17. The IRCM system of claim 16 , further comprising an aircraft that comprises the warning sensor, the tracking sensor, and the AF-QCL. 18. The IRCM system of claim 16 , wherein the output light energy is configured to jam a targeting system of the threat. 19. The IRCM system of claim 16 , wherein the threat comprises a heat-seeking missile. 20. A quantum cascade laser comprising: a ridge-guide comprising: an angled facet that extends across a width of the ridge-guide; and a flat facet that extends across the width of the ridge-guide, wherein a first distance between the flat facet and the angled facet along a first side of the ridge-guide is different than a second distance between the flat facet and the angled facet along a second side of the ridge-guide; and a substrate coupled to a surface of the ridge-guide perpendicular to the width of the ridge-guide and perpendicular to a direction corresponding to the first distance; wherein a surface of the ridge-guide opposite the substrate is gold plated. 21. A quantum cascade laser comprising: a ridge-guide comprising: an angled facet that extends across a width of the ridge-guide; and a flat facet that extends across the width of the ridge-guide, wherein a first distance between the flat facet and the angled facet along a first side of the ridge-guide is different than a second distance between the flat facet and the angled facet along a second side of the ridge-guide; and wherein the flat facet, the first side, and the second side are coated with a high-reflection coating. 22. A method comprising: receiving current at a ridge-guide of a quantum cascade laser, wherein the ridge-guide comprises a flat facet that extends across a width of the ridge-guide and an angled facet that extends across the width of the ridge-guide, and wherein a first distance between the flat facet and the angled facet along a first side of the ridge-guide is different than a second distance between the flat facet and the angled facet along a second side of the ridge-guide; and emitting output light from the angled facet of the ridge-guide in response to receiving the current; wherein the output light forms a single lobe in a farfield.