United States

Laser Processing at the micrometer and below resolution is becoming more and more prominent driving the requirements of the equipment used for these processes to achieve more demanding specifications. Two-photon polymerization (2PP), selective laser etching of glass, and laser micromachining are several emerging processes that fall into this category. They rely on ultrafast lasers in the femtosecond pulse width regime focused with high numerical or high N/A focusing optics to achieve sub-micrometer spot size. The small spot size enables impressive processing resolution on the order of 150 cubic nanometers but it also creates real challenges for positioning a beam so small and allowing that beam to make large enough parts for practical applications.&lt;br&gt;
&lt;br&gt;
This challenge can be overcome by the use of high-dynamic laser scan heads that leverage galvanometer servo motors and precision linear motors to extend the scanning range beyond a fixed field of view. Combining the motion of the scanner motors and physical linear motors in a seamless fashion where the processing speed of the laser on the linear axes is shared between the scanner and the linear motor involves advanced motion control features to execute properly. Controller features known as Infinite Field of View (IFOV) combined with Position Synchronized Output (PSO) allow for large parts with nanometer precision to be created. A detailed technical overview of how these features work within a motion controller and what benefit they have on the aforementioned processes will be discussed. Additionally, application examples will be shared.

ICALEO 2023

Laser Processing Macro Size Components With Sub-Micrometer Feature SIze &amp; Precision

two photon polymerization

ultrafast laser processing

laser microprocessing

laser micromachining

Laser Processing at the micrometer and below resolution is becoming more and more prominent driving the requirements of the equipment used for these processes to achieve more demanding specifications. Two-photon polymerization (2PP), selective laser etching of glass, and laser micromachining are several emerging processes that fall into this category. They rely on ultrafast lasers in the femtosecond pulse width regime focused with high numerical or high N/A focusing optics to achieve sub-micrometer spot size. The small spot size enables impressive processing resolution on the order of 150 cubic nanometers but it also creates real challenges for positioning a beam so small and allowing that beam to make large enough parts for practical applications. 
 
This challenge can be overcome by the use of high-dynamic laser scan heads that leverage galvanometer servo motors and precision linear motors to extend the scanning range beyond a fixed field of view. Combining the motion of the scanner motors and physical linear motors in a seamless fashion where the processing speed of the laser on the linear axes is shared between the scanner and the linear motor involves advanced motion control features to execute properly. Controller features known as Infinite Field of View (IFOV) combined with Position Synchronized Output (PSO) allow for large parts with nanometer precision to be created. A detailed technical overview of how these features work within a motion controller and what benefit they have on the aforementioned processes will be discussed. Additionally, application examples will be shared.

Laser Processing Macro Size Components With Sub-Micrometer Feature SIze & Precision

technical paper

**General Chair Welcome**

![](https://assets.underline.io/markdown_image/1/image/d6e6dddc08bf2371b9136ea9c18dc5ab.png)              

Welcome to ICALEO® 2023!
	
We were excited to host the world’s leading international conference on Lasers and Electro-Optics in Chicago. The Laser has been shown to have the potential to revolutionize solutions for major global challenges like energy usage and supply, global warming, and CO2 footprint. Even the fusion energy breakthrough is based on laser technology. The conference, with peer-reviewed scientific and technical presentations, focused on the newest results in Micro Applications, Macro Applications, Additive Manufacturing, Beam Shaping and Frontiers in Laser Applications. Additionally, the Battery-Manufacturing Track gave an overview of the process combined with the newest advances in laser application results. 

The Business Session brought the business aspect and environment of the laser to the audience and the possibility to discuss with seasoned industry leaders from around the world. 

Whether this is the first time you are hearing about ICALEO or you are a longtime attendee, you will find something of interest, new ideas, and an excellent opportunity to network with other laser specialists worldwide. 

**Klaus Löffler **  
ICALEO General Chair   
Managing Director, Precitec GmbH

**What is ICALEO?**

ICALEO® brings together the brightest minds, seasoned professionals, and pioneering researchers from around the world. With a laser-focused agenda, ICALEO offers an exceptional platform to delve into the cutting-edge advancements, diverse applications, and transformative research that define lasers and electro-optics.

Participants will be immersed in a dynamic environment that fosters collaborative learning, networking, and idea exchange. Through engaging plenary presentations, technical sessions, an industry business panel, and networking events, attendees gain insights into the forefront of laser technology. From industrial applications to medical breakthroughs, additive manufacturing to materials processing, ICALEO covers the entire spectrum of laser-related disciplines. Moreover, the event serves as a launching pad for synergistic partnerships, paving the way for professionals to forge connections that shape the future of our industry.

Join us in Chicago and be part of an unparalleled gathering that challenges the boundaries of possibility within lasers and electro-optics. As we convene to share knowledge, explore innovations, and cultivate collaborations, ICALEO stands as a pivotal force driving the evolution of this transformative technology.

**Who attended?**

ICALEO is tailor-made for professionals, researchers, academics, and enthusiasts who are deeply passionate about the world of lasers and electro-optics. If you're an industry trailblazer, an academic luminary, an aspiring expert, or a postgraduate student looking to dive into the latest developments and trends, this is an event you won't want to miss.

Industrial leaders seeking to stay ahead of the curve in their fields, engineers working on laser applications, and manufacturing experts interested in additive manufacturing and materials processing will find ICALEO to be an invaluable platform. Researchers and scientists exploring the forefront of laser technology, from fundamental principles to groundbreaking applications, will also discover a wealth of knowledge and networking opportunities.

Medical professionals investigating laser-based medical advancements, entrepreneurs seeking to innovate with lasers, educators aiming to stay updated with the latest in laser education, and policy makers shaping the industry's landscape are all essential attendees. Whether you're an established expert or a rising star, the 42nd annual ICALEO promises to offer a diverse ecosystem of expertise, connections, and knowledge sharing that caters to the laser and electro-optics communities.

**Fields Represented:**

* Entrepreneurs and Innovators
* Manufacturing Experts
* Students and Graduates
* Policy Makers and Regulators
* Consultants and Advisors
* Technology Enthusiasts
* Suppliers and Manufacturers
* Startups and Innovators
* Researchers in Laser Education

**[View All Proceedings Here](https://icaleo.conferencespot.org/event-data)**

### **Program Tracks & Chairs**

To access the site please register [**here**](https://icaleo.org/attend). 

Please register for the ICALEO 2023 Conference to join the event.

ICALEO® brings together the brightest minds, seasoned professionals, and pioneering researchers from around the world. With a laser-focused agenda, ICALEO offers an exceptional platform to delve into the cutting-edge advancements, diverse applications, and transformative research that define lasers and electro-optics.

Laser-assisted double wire welding with nontransferred arc uses an electric arc to melt two welding wires fed towards each other. The molten material drips onto the substrate, where it is joined to the substrate without undercuts by means of oscillated laser radiation. The process offers the possibility of creating structures with high deposition rates (8,4&nbsp;kg/h), but faces challenges fulfilling the requirements for surface properties and geometric accuracy. One approach to meet the requirements is to confine the final seam geometry by applying the melt into a mold. Such a confinement can be a wall previously applied by a process with higher geometric accuracy. An investigation of this approach was carried out by studying the deposition of mild steel weld beads within two confining structures, in this case a groove. A particular interest in the evaluation is the connection of the weld bead to the base material in the corners, the bottom surface and the side surface of the groove. In a first step, weld beads are deposited in 12&nbsp;mm wide grooves in a mild steel substrate with variable laser beam oscillation amplitudes of 10&nbsp;mm to 13&nbsp;mm. In a second step, several layers are deposited with variable welding speeds. The oscillation amplitude that generates the best connection in the corners is 13&nbsp;mm. Bonding on the bottom and side surfaces could be achieved with all parameter sets. When applying several layers, the best lateral connection in the groove was produced with a welding speed of 200&nbsp;mm/min.

Welding Between Confinements as a New approach for high deposition rate Additive Manufacturing with laser-assised double-wire welding with nontransferred arc

Additive Manufacturing (AM) has become widely adopted in various industries with Laser AM being the most popular technology for metallic materials. Laser-wire DED (Directed Energy Deposition) is becoming an interesting additive manufacturing method for building large freeform structures that are not constrained by the printing machine dimensions. However, the WAAM process (Wire Arc Additive Manufacturing) is currently more widely used with several high-profile applications, such as bridges, pressure vessels, tanks, and barrels, due to its basic origins in MIG welding. The opportunities for these wire-DED process variants are immense in terms of reduced manufacturing complexity, costs, lead times, and tooling requirements, with more design flexibility. This conference paper discusses feature development testing for 3D printing 30in diameter compressor casings, comparing the advantages and disadvantages between the wire-arc and wire-laser process variants of wire-DED. Using aluminum 5XXX series alloy wire, demonstration test pieces were produced with features including stiffening ribs and local reinforcements. The quality of the printed development test pieces was assessed by radiographic inspections, metallurgical assessments, and dimensional scans. Further demonstrations could include split casings, ports, lugs, and other features that can be integrated as one single part instead of many, simplifying the supply chain with potentially significant gains in productivity.

A comparison of Wire-Laser and Wire-arc Directed Energy Deposition Processes

Laser welding is crucial in the manufacturing of e-mobility components, especially for parts made of copper and aluminum. However, welding these materials poses significant challenges due to their high reflectivity and thermal conductivity, leading to insufficient penetration depth and reduced mechanical properties. Beam shaping offers a promising solution to overcome these challenges by modifying the laser beam's spatial intensity distribution. The use of beam-shaping optics can significantly enhance the welding process by controlling the energy distribution and improving the weld's quality. 
In this study, we demonstrate the successful welding of aluminum battery cases and copper busbars using beam shaping with multi-plane light conversion. Multi-plane light conversion is a novel technique that enables the creation of complex intensity profiles by redirecting the laser beam through multiple planes of phase modulators. Our results show that beam shaping significantly improves the weld quality by reducing spatters and pores, and enhances the mechanical properties of the weld. The multi-plane light conversion technique offers an additional degree of freedom in shaping the intensity profile, enabling further optimization of the weld's quality, and present a higher depth of field enabling a more robust process. 
The successful welding of copper and aluminum components using beam shaping offers a promising solution for the reliable and efficient manufacturing of e-mobility components.

E-mobility Laser Welding Thanks to Beam Shaping Based on Multy-Plane Light Conversion

Pure copper is widely used for various industrial products due to its high thermal conductivity, electrical conductivity, and friction properties. However, high-quality and high-efficiency connections of copper materials remain a challenge for industrial applications because pure copper has a low absorption rate of near-infrared light and is difficult to weld stably with a near-infrared laser. The light absorption rate for pure copper increases with shorter wavelengths. As such, visible light lasers should realize high-efficiency laser welding of pure copper. However, there are few reports comparing the laser wavelength dependence of welding efficiency for pure copper. In this study, bead-on-plate welding were performed on pure copper plates of 2 mm thickness using a 16 kW IR disk laser (1030 nm), a 3 kW green disk laser (515 nm), and a 1.5 kW blue diode laser (450 nm) to investigate the effect of laser wavelength on welding. Bead-on-plate welding of pure copper was performed in thermal conduction mode or keyhole mode by varying the laser spot diameter and power, and the amount of melting was measured from cross-sectional observations. As a result, compared to the IR laser, the blue and green lasers showed higher melting efficiency in both thermal conduction mode and keyhole mode, and the melting behavior was more stable.

Comparison of Melting Efficiency Between Blue, Green, and IR Lasers in Pure Copper Welding

Aluminum is becoming increasingly important in automotive vehicle construction. On the one hand, its use leads to a reduction in vehicle weight, and on the other hand it offers advantages over fiber composites in terms of recycling, i.e. reusability. Die-casting alloys are used when complex components are required at low costs. Furthermore, the use of high-strength wrought aluminum alloys (6XXX and 7XXX) is increasing in crash-relevant structures, for example the battery tray. However, during laser welding of these material combinations, there is a high risk of pore formation (die casting alloys) and hot cracks initiation (high-strength wrought alloys). 
At Fraunhofer IWS, a novel process technological approach is under development, using laser beam welding with dynamic beam shaping. This welding technology significantly controls the formation of the melt pool and the stress situation during solidification and cooling of the melt. Through the defined selection of process parameters, on the one hand the porosity of the die-cast welds can be significantly reduced. On the other hand, hot cracking of critical materials can be reliably avoided even without the use of filler metal. 
The object of this presentation is to demonstrate the potential of laser welding with high-frequency beam oscillation for aluminum battery tray manufacturing. Set-up and parameter field of the welding process are presented and results of the process development for typical joint geometries in combination of cast and wrought aluminum are discussed. Initial results from the preliminary tests for final component manufacturing are presented too.

Laser Welding Without Filler Material of Aluminum Die-cast and Extruded Profiles for Battery Trays

SLAM - Is Femtosecond Machnining During Additive Manufacturing Beneficial ?

Laser bioprinting techniques are emerging as an ideal tool for cell printing due to their excellent cell viability, close to 100%, and high spatial resolution. In this paper, we discuss a special adaptation of the Blister-Actuated Laser Induced Forward Transfer (BA-LIFT) technique for cell printing, performed at the Laser Center UPM. BA-LIFT is a well-known laser direct writing technique and has been used for biological material transfer before. However, in our case we use a thick polyimide layer (30 microns) for blister generation, which provides exceptional protection of the cells from the incoming laser beam. Due to the transparency of this material in the VIS range, we can implement both fluorescence and conventional vision systems coaxial with the laser path to identify the cells to be transferred, opening up the possibility of cell sorting and even cell survival tracking in both donor and acceptor substrates. Negative and positive selection of cells is possible with this setup, with the possibility of leaving the cells to be transferred completely unaltered in the case of negative selection. &nbsp;We present some recent applications of this technique developed in our laboratory, including single-cell isolation for single-cell sequencing in translational medical applications and current studies for applications in tissue engineering. In addition, we present a high-speed imaging study of the transfer process to discuss the dynamics of jet generation and cell deposition mechanisms in the acceptor substrate using our approach.

Laser Bioprinting Using BA-LIFT: From Single Cell Isolation to Tissue Engineering

Ultra-fast Beam Shaping Using Coherent Beam Combining

While conventional vehicle design disciplines such as car body design are established, electromobility-specific disciplines are in the technological orientation and ramp-up phase. 
In particular, the demand for components like batteries, e-motors and power electronics is growing continuously. Aluminum alloys are chosen for parts like casted power electronics housings and heat exchangers made of sheet metal or extrusion profiles. Next to the material-specific challenges and mentioned requirements, the focus is on the gas-tight welding of the aluminum alloys. 
This paper offers an insight into the requirements of these parts as well as the innovative optics approach with a novel MultiFocus solution and multi core fiber technologies. The material-specific challenges, especially for helium-tight welding of aluminum casted housings with forging alloys are characterized. This analysis is conducted using gas-tightness measurements, CT-scans, micrographs and high-speed recordings in order to elaborate the fundamental laser-material-process interdependencies and the correlation between process and resulting quality in terms of tightness. 
Furthermore, high speed synchrotron recordings are conducted at the DESY and based on that a detailed evaluation of the laser and material interaction is conducted. This allows an explanation of the interactions for the prevention of pore formation in aluminum alloys and thus the characterization of the boundary conditions for a reliable process of gas-tight welding on aluminum alloys.

Welding of Cast Aluminum Alloys for Power Electronics: In-Situ Synchrotron X-Ray Analysis of Different Laser Beam Shaping Technologies for the Prevention of Defects

Brass represents a large part in the production of components within the copper alloy group. Laser beam welding of this alloy offers great potential for many applications in terms of achievable seam quality and productivity. However, there is a very high tendency of the process to produce irregular seam surfaces, ejection of the molten metal and pore formation. These are due, among other things, to instabilities of the keyhole, which is favored by the evaporation of the alloy component zinc. Furthermore, near-infrared laser beam wavelength can couple poorly into the material due to the low absorption level of brass, whereas absorption jumps during the melt transition. In recent years, high-brilliance near-infrared laser beam sources with adjustable beam profiles have been developed that can lead to keyhole stabilization. 
The experimental process investigations are on deep penetration welding of different brass alloys (CuZn37 and CuZn39Pb3). A multi-kW laser beam source with combined core and ring beam is used for this purpose. Main process parameters are identified and systematically varied. The produced seams are analyzed and evaluated using different methods (including micrograph analysis and topography images). The results are correlated with the process parameters. Line Energy per unit length, spot size and process gas supply have a significant effect on the weld seam resulting. Process parameters were found to produce high quality bead on plate and butt welds for sheet thicknesses of 2 mm.

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Laser Processing Macro Size Components With Sub-Micrometer Feature SIze & Precision

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Welding Between Confinements as a New approach for high deposition rate Additive Manufacturing with laser-assised double-wire welding with nontransferred arc

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