Laser Ablation Cutting Based Metal Patterning Technique Enabling 3D-Printed Broadband Antennas for Sub-6 GHz Wireless Communications Applications

Recent developments in microfluidics have opened up new interest in rapid prototyping with features on the microscale. Microfluidic devices are traditionally fabricated using photolithography, however this process can be time consuming and challenging. Laser ablation has emerged as the preferred solution for rapid prototyping of these devices. This paper explores the state of rapid prototyping for microfluidic devices by comparing laser ablation to micromilling and 3D printing. A microfluidic sample part was fabricated using these three methods. Accuracy of the features and surface roughness were measured using a surface profilometer, scanning electron microscope, and optical microscope. Micromilling was found to produce the most accurate features and best surface finish down to ∼100 μm, however it did not achieve the small feature sizes produced by laser ablation. 3D printed parts, though easily manufactured, were inadequate for most microfluidics applications. While laser ablation created somewhat rough and erratic channels, the process was within typical dimensions for microfluidic channels and should remain the default for microfluidic rapid prototyping.

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Preparation of Line Patterned Mesoporous DAM-1 Thin Films via Pulsed Laser Deposition

MRS Proceedings ◽

10.1557/proc-704-w10.11.1 ◽

2001 ◽

Vol 704 ◽

Author(s):

Decio Coutinho ◽

Kenneth J. Balkus

Keyword(s):

Thin Films ◽

Laser Ablation ◽

Pulsed Laser Deposition ◽

Pulsed Laser ◽

Laser Deposition ◽

Laser Printer ◽

Transparent Film ◽

Patterned Substrate ◽

Mesoporous Film ◽

Patterning Technique

AbstractPatterned mesoporous DAM-1 thin films were prepared on flexible transparent film utilizing the pulsed laser deposition and a line patterning technique. The patterned lines are transferred to the transparent film using a laser printer or copy machine. Laser ablation of DAM-1 onto the patterned substrate followed by a hydrothermal treatment resulted in a densely packed mesoporous film. Upon removal of the patterned lines (i.e. the underlying toner) by ultrasonic treatment in toluene, patterned DAM-1 films were produced.

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Microfluidic devices manufacturing combining stereolithography and pulsed laser ablation

EPJ Web of Conferences ◽

10.1051/epjconf/202125512009 ◽

2021 ◽

Vol 255 ◽

pp. 12009

Author(s):

Bastián Carnero ◽

Carmen Bao-Varela ◽

Ana Isabel Gómez-Varela ◽

María Teresa Flores-Arias

Keyword(s):

Laser Ablation ◽

3D Printing ◽

Pulsed Laser ◽

Pulsed Laser Ablation ◽

Microfluidic Devices ◽

Hybrid Technique ◽

Detailed Surface ◽

3D Printed ◽

The One ◽

User Friendly

3D printing has revolutionized the field of microfluidics manufacturing by simplifying the typical processes offering a considerable accuracy and user-friendly procedures. For its part, laser ablation proves to be a versatile technology to perform detailed surface micropatterning. A hybrid technique that combines both technologies is proposed, employing them in their most suitable range of dimensions. This technique allows to manufacture accurate microfluidics devices as the one proposed: a microchannel, obtained using a stereolithographic printer, coupled with an array of microlenses, obtained by pulsed laser ablation of a 3D printed master.

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Comparison of Microscale Rapid Prototyping Techniques

Journal of Micro and Nano-Manufacturing ◽

10.1115/1.4027810 ◽

2014 ◽

Vol 2 (3) ◽

Cited By ~ 9

Author(s):

Gordon D. Hoople ◽

David A. Rolfe ◽

Katherine C. McKinstry ◽

Joanna R. Noble ◽

David A. Dornfeld ◽

...

Keyword(s):

Laser Ablation ◽

Rapid Prototyping ◽

Optical Microscope ◽

Research Community ◽

The Other ◽

Test Part ◽

3D Printed ◽

Small Feature ◽

Manufacturing Techniques ◽

Scanning Electron

Recent advances in manufacturing techniques have opened up new interest in rapid prototyping at the microscale. Traditionally microscale devices are fabricated using photolithography, however this process can be time consuming, challenging, and expensive. This paper focuses on three promising rapid prototyping techniques: laser ablation, micromilling, and 3D printing. Emphasis is given to rapid prototyping tools that are commercially available to the research community rather those only used in manufacturing research. Due to the interest in rapid prototyping within the microfluidics community a test part was designed with microfluidic features. This test part was then manufactured using the three different rapid prototyping methods. Accuracy of the features and surface roughness were measured using a surface profilometer, scanning electron microscope (SEM), and optical microscope. Micromilling was found to produce the most accurate features and best surface finish down to ∼100 μm, however it did not achieve the small feature sizes produced by laser ablation. The 3D printed part, though easily manufactured, did not achieve feature sizes small enough for most microfluidic applications. Laser ablation created somewhat rough and erratic channels, however the process was faster and achieved features smaller than either of the other two methods.

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Observations on the growth of YBa2Cu3O7-δ thin films on MgO by pulsed-laser ablation

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100089652 ◽

1991 ◽

Vol 49 ◽

pp. 1068-1069

Author(s):

M. Grant Norton ◽

C. Barry Carter

Keyword(s):

Thin Film ◽

Thin Films ◽

Laser Ablation ◽

Substrate Surface ◽

Pulsed Laser ◽

Pulsed Laser Ablation ◽

Thin Film Deposition ◽

Film Deposition ◽

Laser Ablation Process ◽

Deposition Parameters

Pulsed-laser ablation has been widely used to produce high-quality thin films of YBa2Cu3O7-δ on a range of substrate materials. The nonequilibrium nature of the process allows congruent deposition of oxides with complex stoichiometrics. In the high power density regime produced by the UV excimer lasers the ablated species includes a mixture of neutral atoms, molecules and ions. All these species play an important role in thin-film deposition. However, changes in the deposition parameters have been shown to affect the microstructure of thin YBa2Cu3O7-δ films. The formation of metastable configurations is possible because at the low substrate temperatures used, only shortrange rearrangement on the substrate surface can occur. The parameters associated directly with the laser ablation process, those determining the nature of the process, e g. thermal or nonthermal volatilization, have been classified as ‘primary parameters'. Other parameters may also affect the microstructure of the thin film. In this paper, the effects of these ‘secondary parameters' on the microstructure of YBa2Cu3O7-δ films will be discussed. Examples of 'secondary parameters' include the substrate temperature and the oxygen partial pressure during deposition.

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