Cutting Edge Optronics works closely with each customer to provide the best possible high power laser diode array for specialized application requirements.
Laser Diodes
Our vertically integrated business model allow us to provide a unique set of products and services:
LASER DIODES DESIGNED TO MATCH YOUR SPECIFICATIONS
CEO’s line of high power laser diode packages is available on a variety of conductively-cooled and water-cooled heat sink designs with output powers exceeding 100W CW and 200W QCW per laser diode bar.
With over 400 standard packages and three decades of experience, CEO’s laser diodes have been used for a wide range of applications in the industrial, military, and aerospace sectors.
We offer a wide variety of wavelengths from 780 nm-980 nm including: 808 nm, 885 nm, and 940 nm. CEO’s diode engineers are highly experienced in custom designs for specialized pumping and direct diode applications.
We can match your specifications to our standard products or design the complete package.
Consult us to match your specifications to our standard products or create a custom-built solution for your project.
Our Most Popular Product Offerings
Explore Laser Diode Arrays Specifications
| wdt_ID | Operation | Cooling Method | Laser Diode Package | Total Output Power (W) |
|---|---|---|---|---|
| 1 | CW | Conductively Cooled | A | 20 |
| 2 | CW | Conductively Cooled | A | 40 |
| 3 | CW | Conductively Cooled | A | 80 |
| 4 | CW | Conductively Cooled | A | 120 |
| 5 | CW | Conductively Cooled | A | 160 |
| 6 | CW | Conductively Cooled | G | 20 |
| 7 | CW | Conductively Cooled | G | 40 |
| 8 | CW | Water Cooled | Derringer | 60 |
| 9 | CW | Water Cooled | Derringer | 80 |
| 10 | CW | Water Cooled | Derringer | 100 |
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Frequently Asked Questions
How do I select the right laser diode wavelength for DPSS pumping?
For efficient DPSS laser pumping, you should choose a laser diode wavelength that aligns with a strong absorption peak of your laser crystal.
For example, Nd:YAG has strong absorption lines near 808nm and 885nm, Er:YAG is frequently pumped with diodes near 970nm, and Yb:YAG is typically pumped at 940nm or 970nm. Matching the pump wavelength to the crystal's absorption band maximizes efficiency, reduces thermal load, and improves overall system performance. Cutting Edge Optronics offers high-power laser diode bars and arrays at standard and custom pump wavelengths to support industrial, medical, and defense DPSS laser systems.
What are the key specifications for high-power laser diode bars?
When selecting high-power laser diode bars, the most important specifications are wavelength, optical power, efficiency, and beam divergence.
Key parameters to evaluate include the center wavelength and spectral width (to match your DPSS crystal or direct-diode application), continuous-wave or pulsed output power, and electrical-to-optical efficiency, which impacts system size, SWaP, and cooling requirements. Beam divergence and available fast-axis/slow-axis collimation options determine how easily the output can be coupled into your optics. Package type and cooling interface (conductively cooled, water-cooled, or microchannel) will guide how the laser diode integrates into your laser head or OEM module. Cutting Edge Optronics manufactures high-power laser diode bars and arrays in a wide range of power levels and packages to fit these requirements.
How to manage thermal cooling and lifetime in laser diode stacks for continuous operation?
Effective thermal management is critical to maintaining efficiency, wavelength stability, and long lifetime in high-power laser diode stacks running in CW or high-duty-cycle operation. Maintaining the proper operating temperature helps keep the junction temperature low, which in turn supports higher efficiency and longer diode lifetime.
Many high-power systems utilize water cooling via connection to a chiller, heat exchanger, or facility water supply. Other platforms avoid water by using conduction-cooled designs, often combined with thermoelectric coolers (TECs) for precise temperature control in compact OEM laser diode modules. For applications requiring extremely high output power density, microchannel-cooled laser diode arrays bring the cooling water within hundreds of microns of the diode bar to maximize heat extraction. Cutting Edge Optronics designs and manufactures diode stacks compatible with all of these cooling approaches to support industrial, medical, and defense laser systems.
What packaging options are best for OEM laser diode integration?
The best packaging option for OEM laser diode integration depends on your required power level, cooling method, mechanical constraints, and target application.
Cutting Edge Optronics manufactures laser diode bars and arrays in numerous standard form factors, including conductively cooled packages for SWaP-constrained OEM modules, water-cooled stacks for high-average-power industrial and defense lasers, microchannel-cooled arrays for maximum power density, and custom side-pumping or end-pumping geometries for DPSS laser modules. These packages are fielded in industrial manufacturing, medical, and aerospace and defense platforms worldwide. In addition to our extensive catalog, we develop custom diode array solutions tailored to specific footprints, electrical interfaces, and thermal environments, ensuring a tight fit within your overall laser system design. Contact our sales team.
How temperature-sensitive is laser diode wavelength, and how is it stabilized for precise DPSS laser pumping?
Laser diode wavelength is temperature-dependent, so tight temperature control is essential for precise DPSS pumping and stable interaction with narrow absorption bands.
For a given material set and wavelength, the change in wavelength with temperature (Δλ/ΔT) is nearly constant; for example, laser diodes operating around 808 nm for Nd:YAG pumping typically shift by about 0.25 nm per °C. This means that even a small temperature drift can move the wavelength enough to reduce pump efficiency. To stabilize wavelength, the laser diode temperature must be held within a narrow range using appropriate cooling methods. Common approaches include thermoelectric coolers (TECs) for fine, closed-loop temperature control in OEM modules, water-cooled cold plates and chillers for high-power diode stacks, and forced-air convection for lower-power or cost-sensitive systems. Cutting Edge Optronics designs its high-power diode arrays to work seamlessly with these temperature control strategies to maintain wavelength alignment and system stability.
How do I select the right diode array for a military application?
For military and aerospace laser systems, selecting the right diode array requires careful attention to wide operating temperature ranges, environmental stress, and long-term reliability.
It is common for military laser diode arrays to operate from -40 °C to +70 °C or beyond, which drives requirements on the semiconductor material and device design to maintain high efficiency across the full temperature range. The materials used in the array, including solders and submounts, must be chosen so that the solder hierarchy remains robust well above the maximum operating temperature. Expected mechanical shock and vibration profiles must also be considered, especially when the array incorporates micro-optics or complex stack geometries. Cutting Edge Optronics maintains in-house environmental test capabilities, including thermal chambers for temperature and humidity cycling and a vibration table for shock and vibration testing, allowing our engineers to qualify diode arrays for demanding mission environments such as airborne and naval defense platforms.
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