Laser Micro and Nano Processing of Metals , Ceramics , and Polymers

Pfleging, Wilhelm; Kohler, Robert Ε.; Südmeyer, I.; Rohde, Magnus

doi:10.1007/978-3-642-28359-8_8

Cited by 16 publications

(7 citation statements)

References 142 publications

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“…Powder-based additive manufacturing (AM) methods like powder bed fusion of polymers or metals by laser sintering (LS) or selective laser melting (SLM) are of great interest for prototyping and the "custom-made" small-scale production of technically sophisticated components, in particular for the automotive, aerospace, and electronics industries (Pfleging et al 2013). The currently available range of basic powder materials is, however, limited and poses a major drawback for the further development of the field (Schmid et al 2014).…”

Section: Laser-generated Nanoparticles In Laser Additive Manufacturingmentioning

confidence: 99%

Laser Synthesis of Colloids: Applications

Gökce¹,

Rehbock²,

Ramesh³

et al. 2020

Handbook of Laser Micro- And Nano-Engineering

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In recent years, laser synthesis and processing of colloids (LSPC) has become a method for the scalable and continuous synthesis of size-controlled nanomaterials. Within this section of the book, the utilization of LSPC-generated nanoparticles in applications will be summarized. The most important features of laser-generated nanoparticles are their high-purity, surfactant-free surface and homogenous alloy formation with the former enabling a large potential as toxicity reference material, while the latter allows gradual compositional studies of catalytic activity. Here, the high purity surface and solely electrostatic colloidal stabilization guarantees high adsorption efficiency and hence independent tunability of particle size, load, and composition. This flexibility concerning

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Section: Laser-generated Nanoparticles In Laser Additive Manufacturingmentioning

confidence: 99%

Laser Synthesis of Colloids: Applications

Gökce¹,

Rehbock²,

Ramesh³

et al. 2020

Handbook of Laser Micro- And Nano-Engineering

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“…Laser structuring was performed with a wavelength λ = 248 nm in ambient air. [90] with permission of Springer. electrolyte interphase).…”

Section: Laser Structuring (Ls) Of Licoo2 Thin Filmsmentioning

confidence: 99%

Laser Materials Processing for Energy Storage Applications

Kim¹,

Smyrek²,

Zheng³

et al. 2018

Pulsed Laser Ablation

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This chapter will review the use of laser-based material processing techniques, such as pulsed laser deposition (PLD), laser-induced-forward transfer (LIFT), and materials processing via 3D laser structuring (LS) and laser annealing (LA) techniques for energy storage applications. PLD is a powerful tool for fabricating high-quality layers of materials for cathodes, anodes and solid electrolytes for thin-film microbatteries. LIFT is a versatile technique for printing complex materials with highly porous structures for the fabrication of micropower sources, such as ultracapacitors and thick-film batteries. LS is a recently developed technique for modifying the active material by forming advanced 3D electrode architectures and increasing the overall active surface area. LA is a rapid technology for adjusting the crystalline battery phase and for controlling the grain size on micro and nano scale. This chapter will review recent work using these laser-processing techniques for the fabrication of micropower sources and lessons learned from the characterization of their electrochemical properties.

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“…Those polymers show a high laser beam absorption in the ultraviolet (UV) (248 nm, 193 nm) as well as in the infrared (IR) (10.6µm). From previous studies it is known that a high optical absorption at UV wavelengths leads to low material removal rate, which in turn enables a precise control of the achieved ablation depth and a good surface quality [9]. With UV laser structuring lateral resolutions in the sub-micrometer range via direct writing or direct optical imaging of complex mask structures can be achieved.…”

Section: Structuring Technologiesmentioning

confidence: 99%

The SMARTLAM 3D-I Concept: Design of Microsystems from Functional Elements Fabricated by Generative Manufacturing Technologies

Dickerhof

Kimmig

Adamietz

et al. 2014

Precision Assembly Technologies and Systems

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Generative manufacturing technologies are gaining more and more of importance as key enabling technologies in future manufacturing, especially when a flexible scalable manufacturing of small medium series of customized parts is required. The paper describes a new approach for design and manufacturing of complex three dimensional components building on a combination of additive manufacturing and e-printing technologies, where the micro component is made up of stacks of functionalized layers of polymer films. Special attention will be paid to the "3-d" modeling approach, requested to support the applicaton developer through provision of design rules for this integrated manufacturing concept. Both, the application concept as well as the related equipment and manufacturing integration currently are currently developed further in the project SMARTLAM, funded by the European Commission.

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Laser Micro and Nano Processing of Metals , Ceramics , and Polymers

Cited by 16 publications

References 142 publications

Laser Synthesis of Colloids: Applications

Laser Synthesis of Colloids: Applications

Laser Materials Processing for Energy Storage Applications

The SMARTLAM 3D-I Concept: Design of Microsystems from Functional Elements Fabricated by Generative Manufacturing Technologies

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