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Metals and alloys

The use of technology for the laser marking of metals has become a benchmark for doing extremely accurate and perfectly legible jobs in increasingly shorter times. This system is increasingly common in many sectors: electronics, mechanics, automotive industry, jewellery, medical technologies.
It is not just on soft metals, like aluminium, that laser marking can be done, but also on steel and hard alloys. The list of metals that can be processed includes: copper, iron, ferrous metals, brass, gold, silver, platinum, palladium, and titanium. Depending on the customer’s requirements, laser marking systems can be developed for processing every kind of metal.
Whether we are talking about laser marking for identifying a product or deep laser engraving, surface blackening (annealing) or 3D engraving, the laser process for marking metals has considerable advantages: it is an extremely accurate and clean method, carried out by a no-contact process that requires no prior or subsequent processing ; it guarantees the identification and traceability of the products with a high resolution finish, it ensures long-lasting jobs, resistant to acids, chemicals and corrosion, without damaging the surface of the material.
Our laser systems for marking metals include the innovative fibre sources technology, which is extremely reliable for processing different metals. Since they adapt to the specific properties of the material to be marked, Lasit markers offer the best combination of marking safety, speed and quality.

 LASIT recommends:


MicroMark GN


TowerMark X



Laser marking of metals and alloys


When laser marking oxidizes the surface of ferrous metals (iron, steel and stainless steel) and titanium via the localized heating of the material, we call that annealing (surface blackening via the laser). The oxide layer is typically black, but it can also come in other hues (yellow, red or green, for example). With annealing, the surface of the materials remains unchanged. The color change occurs not via ablation but due to the localized heating of the material. On metal surfaces, the color usually reaches a depth of between 20 and 30 micrometers.


When engraving is carried out with a laser marker, a bit of the material is ablated from the surface of the component being treated. This marking effect can be obtained on almost all materials. Laser engraving is used especially with metals, plastics and ceramics. The laser beam penetrates the surface and removes a part of it, creating a depression in the area. Because the material is heated as it reacts to the air in the environment, there is often discoloration in the area that has been engraved and this makes the marked area all the more evident.

Deep Marking

Deep laser engraving is a highly specialized procedure that involves engraving at a precise depth. The result is very similar to mechanical engraving. However, the laser process has many advantages which make it more suitable for the industry. During deep laser engraving, the material is removed in layers in order to engrave in an area as small as a few millimeters in diameter, which is something that is difficult to achieve with mechanical methods. Another advantage of the laser is the fact that even materials that are particularly difficult to work with can be marked without issue.

Video laser marking metals

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    VIN Code

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    Turbo Charger

  • sospensioni-laser-marcatura-incisione-macchina-incisore-automotive

    Arm Triangle

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    Engine Block

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  • cuscinetti-laser-marcatura-incisione-macchina-incisore-automotive


  • bilanciamento-laser-marcatura-incisione-macchina-incisore-automotive

    Balance shafts

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  • alluminio-anodizzato-laser-marcatura-incisione-macchina-incisore-automotive

    Anodized aluminum

  • alluminio-verniciato-laser-marcatura-incisione-macchina-incisore-automotive

    Painted aluminum

Which are the main applications of laser marking on metals?

Typical industry solutions for metal laser marking and engraving include all the sectors where accuracy and precision are required, such as Automotive, product labelling and coding (serial numbers, codes and logos), Cutting tool industry and  Medical Industry.

Can a laser engraving machine for metals mark all kinds of metals and alloys?

All types of metal can undergo laser marking or laser engraving. The list of metals that can be laser marked or engraved includes all types of steel (stainless, high quality, or carbon steel, etc.), but also copper, iron, ferrous metals, magnesium, aluminum, gold, silver, platinum, titanium and more.

Which is the best laser source to mark, or engrave or cut metals and alloys?

The fiber laser is the best laser source to process metals and alloys. LASIT produces the FiberFly laser that uses the most innovative technology with active fiber doped with Ytterbium. It is the ideal laser solution for precision laser engraving, marking, micro-machining and cutting of metal materials.

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    Since 1990 we have been designing and building
    innovative machines for marking and laser engraving,
    with the quality and excellence Made in italy
  • T. +39 081 536 88 55 |sales@lasitlaser.com
    Via Solferino n° 4, 80058 Torre Annunziata (NA) - Italy

    T. 508 528 2542 |robinb@primenetworks.biz
    623 Old West Central St, Franklin 02038 Stati Uniti