\nThe wavelength determines which materials will absorb the energy and which will reflect it.<\/li>\n<\/ol>\n
1070nm (Fiber Lasers): This near-infrared wavelength is the gold standard for metals. It is absorbed highly by steel, titanium, and even reflective brass.<\/p>\n
10.6\u00b5m (CO2 Lasers): A much longer wavelength, ideal for non-metals like wood, acrylic, and glass (Article #38).<\/p>\n
355nm (UV Lasers): The “Cold” wavelength used for high-contrast marking on sensitive plastics without thermal damage.<\/p>\n
Choosing the wrong wavelength is like trying to cut wood with a flashlight; the energy simply won’t “sink” into the material.<\/p>\n
- \n
- Pulse Frequency: The Heartbeat of the Process
\nMost industrial lasers (especially for marking and cleaning) do not fire a continuous stream. Instead, they fire in rapid pulses. Frequency, measured in Kilohertz (kHz), is the number of pulses delivered per second.<\/li>\n<\/ol>\nHigh Frequency (e.g., 100kHz+): Delivers many small “bites” of energy. This is perfect for laser cleaning (Article #40) or high-speed marking where you want a smooth surface finish.<\/p>\n
Low Frequency (e.g., 20kHz): Delivers fewer, but much more powerful “punches.” This is necessary for deep laser engraving (Article #38) or heavy-duty rust removal.<\/p>\n
- \n
- The Pulse Energy Equation
\nTo optimize a process, you must calculate how much energy is actually hitting the part in a single pulse.<\/li>\n<\/ol>\nThe Pulse Energy Equation
\nPulse Energy (J) = Average Power (W) \/ Pulse Frequency (Hz)
\nBy lowering the frequency while keeping the power constant, you significantly increase the “punch” of each individual pulse.<\/p>\n- \n
- Pulse Duration: The “Contact Time”
\nPulse duration (or pulse width) is the amount of time the laser is actually “ON” during a single pulse, usually measured in nanoseconds (ns).<\/li>\n<\/ol>\nShort Pulses: Minimize the Heat Affected Zone (HAZ), ensuring the noble precision of the surrounding material.<\/p>\n
Long Pulses: Allow more heat to soak into the material, which can be beneficial for certain laser welding (Article #39) applications where a deeper melt pool is required.<\/p>\n
Conclusion: The Foundation of Tuning
\nWavelength and Frequency are the “DNA” of your laser process. By mastering these, you ensure that your CNC and PLC integration (Article #34) is delivering the exact amount of energy required for the task. In Article #42, we will look at how these wave characteristics interact with the two most visible parameters: Laser Power and Travel Speed.<\/p>\n\nImage Attachment<\/h3>\n
\n![\"Technical](\"https:\/\/www.intouchray.com\/wp-content\/uploads\/2026\/03\/decoding-the-pulse-wavelength-and-frequency-in-laser-processing.jpg\")
\n Technical schematic diagram (1024\u00d7559px)
\n <\/figcaption><\/figure>\n<\/div>\nSpecification Comparison<\/h2>\n
\n\n
\n \nSpecification<\/th>\n CO2 Laser<\/th>\n Fiber Laser<\/th>\n<\/tr>\n<\/thead>\n \n Wavelength (nm)<\/td>\n 10,600<\/td>\n 1,064<\/td>\n<\/tr>\n \n Frequency (THz)<\/td>\n 28.3<\/td>\n 282<\/td>\n<\/tr>\n \n Average Power Output (W)<\/td>\n 100\u2013500<\/td>\n 1,000\u20135,000<\/td>\n<\/tr>\n \n Pulse Duration (ns)<\/td>\n 100\u2013200<\/td>\n 10\u201350<\/td>\n<\/tr>\n \n Beam Quality (M\u00b2)<\/td>\n 1.5\u20132.5<\/td>\n 1.0\u20131.2<\/td>\n<\/tr>\n \n Electrical Efficiency (%)<\/td>\n 3\u20135<\/td>\n 25\u201330<\/td>\n<\/tr>\n \n Cost of Operation (USD\/hour)<\/td>\n 10\u201315<\/td>\n 5\u201310<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n Frequently Asked Questions<\/h2>\n
What is the typical wavelength range for CO2 lasers used in laser processing?<\/h3>\n
The typical wavelength range for CO2 lasers used in laser processing is around 10.6 micrometers (\u03bcm).<\/p>\n
How does the frequency of a laser affect its power output, and what is an example of a high-frequency laser’s power rating?<\/h3>\n
A higher frequency generally allows for a more precise and controlled energy delivery. For instance, a high-frequency fiber laser can have a power rating of up to 10,000 watts (W).<\/p>\n
What is the minimum tolerance for wavelength stability in industrial laser systems?<\/h3>\n
The minimum tolerance for wavelength stability in industrial laser systems is typically within \u00b10.5 nanometers (nm) to ensure consistent performance.<\/h3>\n
Can you provide an example of a laser system that operates at a specific frequency, and what is its cost?<\/h3>\n
A Nd:YAG laser, which operates at a frequency of 1,064 nanometers (nm), can be purchased for approximately $50,000, depending on the specific model and features.<\/p>\n
What is the maximum pulse repetition rate for a diode-pumped solid-state (DPSS) laser, and how does it impact processing speed?<\/h3>\n
The maximum pulse repetition rate for a DPSS laser can be as high as 100,000 pulses per second (pps). This high repetition rate significantly increases the processing speed, making it ideal for high-throughput applications.<\/p>\n
How does the wavelength of a laser affect material absorption, and what is the optimal wavelength for processing stainless steel?<\/h3>\n
The wavelength of a laser affects material absorption because different materials absorb light at different wavelengths. For stainless steel, the optimal wavelength is around 1,070 nanometers (nm), which is commonly provided by fiber lasers.<\/p>\n
- Pulse Duration: The “Contact Time”
- The Pulse Energy Equation