Your search keyword '"Laser engraving"' showing total 1,883 results

1. Fabrication of diamond drum resonators via laser engraving and Si wet etching for high precision temperature sensing

Author

Du, Yunchao, Zhao, Zhixin, Li, Haoran, Yan, Biao, and Liu, Duo

Published

2025

2. Modeling and experiment of femtosecond laser processing of micro-holes arrays in quartz.

Author

Shangguan, Duansen, Liu, Yuhui, Chen, Liping, Su, Chang, and Liu, Jing

Subjects

*LASER engraving, *ARRAY processing, *DRUDE theory, *ELECTRON density, *FEMTOSECOND lasers, *LASER pulses, *QUARTZ

Abstract

Quartz material irradiated by femtosecond laser has increasingly attracted widespread attention for the micro-fabrication of photonic devices. Mechanism exploration is beneficial for accelerating the digital progress of laser processing. However, the mechanism between femtosecond laser and quartz is complicated and needs further theoretical investigation. This paper established the theoretical model based on the ionization model with the Drude equation to study the space–time evolution of free electron density and its influence on the absorption coefficient, reflectivity, and ablation depth. In addition, we achieved a 10 × 10 micro-holes array with a pore size less than 10 μm, cone angle less than 2° in a 0.25 mm thick quartz on the condition of a laser pulse energy Ep = 3 μJ, scanning velocity v = 0.1 mm/s, and defocusing distance Δf = −0.3 mm via the bottom-up femtosecond laser processing. The work gives a new insight into further understanding the ablation mechanism of transparent materials etching by the femtosecond laser. It provides a practical technical scheme for preparing commercial quartz photonic devices. [ABSTRACT FROM AUTHOR]

Published

2024

3. A facile and efficient nitrite electrochemical sensor based on N, O co-doped porous graphene film

Author

Yuan, Xiaoming, Chen, Jianyue, Ling, Yunhan, Yu, Shaoqiu, Li, Shilin, Wu, Xiuwen, and Zhang, Zhengjun

Published

2022

4. Microstructural Investigation of Laser Engraving of Jalore Pink Granite

Author

Sinha, Antash K., Joshi, Shrikrishna N., Chaari, Fakher, Series Editor, Gherardini, Francesco, Series Editor, Ivanov, Vitalii, Series Editor, Haddar, Mohamed, Series Editor, Cavas-Martínez, Francisco, Editorial Board Member, di Mare, Francesca, Editorial Board Member, Kwon, Young W., Editorial Board Member, Tolio, Tullio A. M., Editorial Board Member, Trojanowska, Justyna, Editorial Board Member, Schmitt, Robert, Editorial Board Member, Xu, Jinyang, Editorial Board Member, Sahoo, Prasanta, editor, and Barman, Tapan Kumar, editor

Published

2025

5. Fabrication of multi-purpose 3D printer (3D printer, CNC & laser engraving).

Author

Kannaki, S., Sooraj, S., Vijeth, R., Selvalakshmi, S. U., Sharmietha, S. P., and Sruthi, S.

Subjects

*LASER engraving, *THREE-dimensional printing, *WOOD carving, *MANUFACTURING processes, *JEWELRY design, *3-D printers

Abstract

In a leap forward for manufacturing versatility, we introduce a cutting-edge multipurpose 3D printer that harmoniously integrates three distinct manufacturing technologies: 3D printing, CNC engraving, and laser engraving. This groundbreaking device is not merely a printer; it's a transformative tool that revolutionizes the landscape of prototyping, fabrication, and customization. At its core, the 3D printing capability of this device transcends mere replication, serving as a conduit for the materialization of intricate designs and complex structures, layer by layer. Simultaneously, the CNC engraving feature empowers users to sculpt with precision, elevating the printer to the realm of traditional subtractive manufacturing processes. From intricate wood carvings to precise metal etchings, the possibilities are limitless. Adding a stroke of finesse, the laser engraving functionality bestows upon users the power to embellish their creations with unrivaled precision and detail. Whether etching intricate designs on jewelry or engraving serial numbers on industrial components, the laser engraving feature ensures a level of precision that borders on the artistic. What truly sets this multipurpose 3D printer apart is its intuitive interface, seamlessly guiding users through the transition between 3D printing, CNC engraving, and laser engraving modes. This user-centric design not only enhances efficiency but also fosters a fluid creative process, empowering users to explore and experiment without constraint. In essence, this multipurpose 3D printer isn't just a tool; it's a catalyst for innovation. It bridges the gap between additive and subtractive manufacturing, offering a holistic solution that embodies versatility, precision, and creative freedom. With each layer and each engraving, it propels us further into a future where imagination knows no bounds. [ABSTRACT FROM AUTHOR]

Published

2025

6. Advancements in Superhydrophobic Paper-Based Materials: A Comprehensive Review of Modification Methods and Applications.

Author

Tang, Yin, Ban, Shouwei, Xu, Zhihan, Sun, Jing, and Ning, Zhenxin

Subjects

*LASER engraving, *CONTACT angle, *SURFACE energy, *ENVIRONMENTAL management, *WEARABLE technology

Abstract

Superhydrophobic paper-based functional materials have emerged as a sustainable solution with a wide range of applications due to their unique water-repelling properties. Inspired by natural examples like the lotus leaf, these materials combine low surface energy with micro/nanostructures to create air pockets that maintain a high contact angle. This review provides an in-depth analysis of recent advancements in the development of superhydrophobic paper-based materials, focusing on methodologies for modification, underlying mechanisms, and performance in various applications. The paper-based materials, leveraging their porous structure and flexibility, are modified to achieve superhydrophobicity, which broadens their application in oil–water separation, anti-corrosion, and self-cleaning. The review describes the use of these superhydrophobic paper-based materials in diagnostics, environmental management, energy generation, food testing, and smart packaging. It also discusses various superhydrophobic modification techniques, including surface chemical modification, coating technology, physical composite technology, laser etching, and other innovative methods. The applications and development prospects of these materials are explored, emphasizing their potential in self-cleaning materials, oil–water separation, droplet manipulation, and paper-based sensors for wearable electronics and environmental monitoring. [ABSTRACT FROM AUTHOR]

Published

2025

7. Laser applications in GaN growth and processing.

Author

Song, Yifei, Wang, Gong, Li, Yunfei, and Lv, Zhiwei

Subjects

PULSED laser deposition, LASER engraving, GALLIUM nitride, LASER deposition, EPITAXY

Abstract

GaN has a wide application prospect in optoelectronics, semiconductor lighting and other fields because of its superior physical and electrical attributes. The in-depth research of the preparation and processing technology of GaN is particularly important. However, traditional GaN processing methods have limitations in processing, such as high processing difficulty and limited processing accuracy. Laser processing is a high-precision, non-contact, non-thermal carrier damage processing method that is widely employed for the growth and processing of GaN. Progress in GaN laser processing over the last few years is reviewed in this paper,focusing on laser etching of GaN and laser growth of GaN, including laser epitaxial growth technology, laser pulsed deposition technology and laser stripping transfer technology. Finally, the future development direction and challenges of laser growing and processing of GaN are prospected. Laser growth and processing techniques for GaN are expected to expand the range of applications for GaN devices. [ABSTRACT FROM AUTHOR]

Published

2025

8. Role of Laser Etching on Shear Bond Strength between Recast Nickel-Chromium Alloy and Dental Ceramic: An Experimental Study.

Author

Sriman, Janardanan, Chidembaranathan, Ahila Singaravel, and Balasubramanium, Muthukumar

Subjects

NICKEL-chromium alloys, DENTAL acid etching, DENTAL ceramics, DENTAL metallurgy, LASER engraving

Abstract

Objectives: The purpose of this study was to investigate the effect of laser etching, air bone particle abrasion and acid etching on shear bond strength between re-cast Nickel Chromium alloy and dental ceramics. Materials and Methods: A master die was made according to ISO 9693; TR (11406). A total of 40 samples were fabricated with 50%w nickel-chromium alloy and 50%w previously casted nickel-chromium alloy. The samples were divided into four groups based on the surface treatment applied. Group 1 served as the untreated control, Group 2 underwent etching with 10% hydrochloric acid (HCl), Group 3 received surface treatment via air-borne particle abrasion, while Group 4 was conditioned using a pulsed Nd:YAG laser. Shear bond strength between ceramic and metal was tested using a universal testing machine and the mode of debonding was evaluated using scanning electron microscope. The obtained values were statistically analyzed using one-way ANOVA and Tukey's HSD Post Hoc test. Results: The mean values of shear bond strength for Group 1 was 22.69±2.63Mpa, Group 2 was 27.05±2.15Mpa, Group 3 was 34.46±2.46Mpa and Group 4 was 39.54±2.16Mpa. The difference among the groups was significant (P<0.001). Hence there was a statistical difference seen in shear bond strength between control and acid etching, air borne particle abrasion and laser etching. Conclusion: Laser surface conditioning produced more surface roughness compared to acid etching and air bone particle abrasion on re-cast Nickel Chromium alloy which increased the shear bond strength markedly between recast nickel-chromium alloy and dental Ceramic. [ABSTRACT FROM AUTHOR]

Published

2025

9. Earthworm inspired lubricant self-pumping hydrogel with sustained lubricity at high loading.

Author

Ma, Shuanhong, Liu, Lunkun, Zhao, Weiyi, Li, Renjie, Zhao, Xiaoduo, Zhang, Yunlei, Yu, Bo, Liu, Ying, and Zhou, Feng

Subjects

LASER engraving, PHYSICAL & theoretical chemistry, MANUFACTURING processes, HYDROGELS, MEDICAL equipment, LUBRICATION & lubricants

Abstract

The development of mechanically robust super-lubrication hydrogel materials with sustained lubricity at high contact pressures is challenging. In this work, inspired by the durable lubricity feature of the earthworm epidermis, a multilevel structural super-lubrication hydrogel (MS-SLH) system, the so-called lubricant self-pumping hydrogel, is developed. The MS-SLH system is manufactured by chemically dissociating a double network hydrogel to generate robust and wrinkled lubrication layer, and then laser etching was used to generate cylindrical texture pores as gland-like pockets for storing lubricants. The surface of MS-SLH system shows ultrafast hydration characteristics and reversible pore-closing and pore-opening behavior. The current MS-SLH system shows excellent SL features, as follows: a very low COF (~0.0079) at high contact pressure condition (P: 11.32 MPa); a stable and robust SL lifespan (COF: ~0.0028, P: 8.48 MPa, 100k cylces) without surface wear; and a sustained lubricity period (3700 cycles) with limited lubricant volume (5 μL) in air. The robust and sustained lubricity of the MS-SLH system is likely attributed to the synergy from the strong electrostatic repulsion effect at the sliding interface, the robust but compliant modulus of the dissociation lubrication layer, and the self-pumping lubricant release from the gland-like pocket of the texture pores during the dynamic shearing process. The demonstration experiments based on self-built equipments intuitively exhibit durable SL behavior of MS-SLH system. This work provides an easy strategy for the large-scale manufacture of high-performance water-lubrication coatings suitable for high-end medical devices or moving parts. Developing mechanically robust hydrogels with high lubricity is challenging but desirable. Here, the authors report the development of a layered hydrogel with a robust and wrinkled lubrication layer, and pores for storing lubricants, for sustained lubricity. [ABSTRACT FROM AUTHOR]

Published

2025

10. Mechanical Behavior of Origami-Based Inflatable Bistable Foldable Panels.

Author

Liang Jie Zhao and Bo Hua Sun

Subjects

*LASER engraving, *FAILURE mode & effects analysis, *AIR pressure, *ORIGAMI, *PROTOTYPES

Abstract

Deployable structures are extensively used in engineering. A bistable panel structure, inspired by multistable origami, is proposed, capable of deployment and folding powered by air pressure. Prototypes were manufactured using planar laser etching technology based on geometric design. Mechanical behavior under out-of-plane compression, in-plane compression, and out-of-plane bending loads was analyzed through experiments. The foldable panel showed superior mechanical performance under out-of-plane compression, highlighting its potential as an ideal energy-absorbing material. In-plane compression and out-of-plane bending along the folding direction exhibited lower strength due to foldability, with failure modes involving rigidity loss from folding. The structure demonstrated good energy absorption characteristics during in-plane compression. As the angle of the unit increased during out-of-plane bending, mechanical performance improved, but the failure mode shifted to fracture. In in-plane compression and out-of-plane bending perpendicular to the folding direction, mechanical performance was enhanced, but the structure failed due to strength loss from fracture. [ABSTRACT FROM AUTHOR]

Published

2025

11. Remaining Oil Distribution and Enhanced Oil Recovery Mechanisms Through Multi-Well Water and Gas Injection in Weathered Crust Reservoirs.

Author

Wang, Yuegang, Guo, Wanjiang, Sun, Gangzheng, Zhou, Xu, Lin, Junzhang, Ding, Mingshan, Huang, Zhaoqin, and Cao, Yingchang

Subjects

ENHANCED oil recovery, PETROLEUM distribution, GEOLOGICAL modeling, GAS injection, LASER engraving

Abstract

Weathered crust karst reservoirs with intricately interconnected fractures and caves are common but challenging enhanced oil recovery (EOR) targets. This paper investigated the remaining oil distribution rules, formation mechanisms, and EOR methods through physical experiments on acrylic models resembling the geological features of weathered crust reservoirs. Acrylic models with precision dimensions and morphologies were fabricated using laser etching technology. By comparing experiments under different cave filling modes and production well locations, it was shown that a higher cave filling extent led to poorer bottom water flooding recovery due to stronger flow resistance but slower rising water cut owing to continued production from the filling medium. Multi-well water and gas injection achieved higher incremental oil recovery by alternating injection–production arrangements to establish new displacement channels and change drive energy. Gas injection recovered more attic remaining oil from upper cave regions, while subsequent water injection helped wash the residual oil in the filling medium. The findings reveal the significant effects of fracture cave morphological configuration and connectivity on remaining oil distribution. This study provides new insights and guidance for EOR design optimization catering to the unique features of weathered crust karst fractured vuggy reservoirs. [ABSTRACT FROM AUTHOR]

Published

2025

12. Picosecond Laser Etching of Glass Spiral Microfluidic Channel for Microparticles Dispersion and Sorting.

Author

Chen, Rong, He, Shanshan, He, Xiansong, Xie, Jin, and Zhu, Xicong

Subjects

LASER engraving, LAMINAR flow, SURFACE roughness, INTEGRATED circuits, MICROFLUIDICS, BIOCOMPATIBILITY

Abstract

In microfluidic chips, glass free-form microchannels have obvious advantages in thermochemical stability and biocompatibility compared to polymer-based channels, but they face challenges in processing morphology and quality. Hence, picosecond laser etching with galvanometer scanning is proposed to machine spiral microfluidic channels on a glass substrate. The objective is to disperse and sort microparticles from a glass microchip that is difficult to cut. First, the micropillar array and the spiral microchannel were designed to disperse and sort the particles in microchips, respectively; then, a scanning path with a scanning interval of 5 μm was designed according to the spot diameter in picosecond laser etching; next, the effects of laser power, scanning speed and accumulation times were experimentally investigated regarding the morphology of spiral microchannels; finally, the microfluidic flowing test with 5 μm and 10 μm microparticles was performed to analyze the dispersing and sorting performance. It was shown that reducing the laser power and accumulation times alongside increasing the scanning speed effectively reduced the channel depth and surface roughness. The channel surface roughness reached about 500 nm or less when the laser power was 9 W, the scanning speed was 1000 mm/s, and the cumulative number was 4. The etched micropillar array, with a width of 89 μm and an interval of 97 μm, was able to disperse the different microparticles into the spiral microchannel. Moreover, the spiral-structured channel, with an aspect ratio of 0.51, significantly influenced the velocity gradient distribution, particle focusing, and stratification. At flow rates of 300–600 μL/min, the microparticles produced stable focusing bands. Through the etched microchip, mixed 5 μm and 10 μm microparticles were sorted by stable laminar flow at flow rates of 400–500 μL/min. These findings contribute to the design and processing of high-performance glass microfluidic chips for dispersion and sorting. [ABSTRACT FROM AUTHOR]

Published

2025

13. The Investigation of Graphene Oxide-Enhanced Hybrid Slurry Preparation and Its Polishing Characteristic on CVD Single Crystal Diamond.

Author

Wang, Zixuan, Zhao, Yang, Yao, Jie, Yu, Tianbiao, Qu, Sheng, and Zhao, Jun

Subjects

*DIAMOND crystals, *SINGLE crystals, *LASER engraving, *GRAPHENE oxide, *SURFACE roughness, *FEMTOSECOND lasers

Abstract

As an environment-friendly material, graphene oxide nanosheet can effectively improve the polishing surface quality of single crystal diamond workpieces. However, the lubricating and chemical effects of graphene oxide nanosheets have an uncertain impact on the polishing material removal rate. In this paper, the graphene oxide-enhanced hybrid slurry was prepared with good stability. The femtosecond laser etching and contour measurement method was adopted to analyze the polishing material removal rate of the CVD single crystal diamond workpiece. The surface damage of the workpiece polished with SiC abrasive grains is minimal, while the workpiece with diamond abrasive grains has the largest material removal rate. With an increase in abrasive grain size, the polishing material removal rate increases, but new surface scratches and pits can be introduced if the grain size is too large. Therefore, a grain size of 2.5 μm was selected to improve the surface quality. The surface roughness first decreases and then increases with the increase in polishing rotation speed. At a speed of 4000 rpm, the surface roughness reached its minimum with a relatively high material removal rate simultaneously. A series of CVD single crystal diamond scratching experiments were conducted with different scratching speeds, which proved that graphene oxide can help facilitate material surface micro-protrusion removal. [ABSTRACT FROM AUTHOR]

Published

2024

14. Rapid prediction of acute thrombosis via nanoengineered immunosensors with unsupervised clustering for multiple circulating biomarkers.

Author

Kaidong Wang, Shaolei Wang, Margolis, Samuel, Jae Min Cho, Enbo Zhu, Dupuy, Alexander, Junyi Yin, Seul-Ki Park, Magyar, Clara E., Adeyiga, Oladunni B., Jensen, Kristin Schwab, Belperio, John A., Passam, Freda, Peng Zhao, and Hsiai, Tzung K.

Subjects

*RECEIVER operating characteristic curves, *THROMBOSIS, *LASER engraving, *BIOMARKERS, *CARBON dioxide lasers

Abstract

The recent SARS-CoV-2 pandemic underscores the need for rapid and accurate prediction of clinical thrombotic events. Here, we developed nanoengineered multichannel immunosensors for rapid detection of circulating biomarkers associated with thrombosis, including C-reactive protein (CRP), calprotectin, soluble platelet selectin (sP-selectin), and D-dimer. We fabricated the immunosensors using fiber laser engraving of carbon nanotubes and CO2 laser cutting of microfluidic channels, along with the electrochemical deposition of gold nanoparticles to conjugate with biomarker-specific aptamers and antibody. Using unsupervised clustering based on four biomarker concentrations, we predicted thrombotic events in 49 of 53 patients. The four-biomarker combination yielded an area under the receiver operating characteristic curve (AUC) of 0.95, demonstrating high sensitivity and specificity for acute thrombosis prediction compared to the AUC values for individual biomarkers: CRP (0.773), calprotectin (0.711), sP-selectin (0.683), and D-dimer (0.739). Thus, a nanoengineered multichannel platform with unsupervised clustering provides accurate and efficient methods for predicting thrombosis, guiding personalized medicine. [ABSTRACT FROM AUTHOR]

Published

2024

15. Surface Oxide Removal in Preparation for Controlled Liquid Metal Embrittlement.

Author

Christensen, James M., Cody Goss, Robert, and Masters, Benjamin C.

Subjects

LIQUID metals, LASER engraving, MECHANICAL abrasion, LASER ablation, ALUMINUM oxide

Abstract

During liquid metal embrittlement a liquid metal infiltrates grain boundaries of a compatible solid metal, interrupting the inter-grain bonds and weakening the metal. Ongoing research has proposed that this effect may be used to perform additive/subtractive hybrid machining to fabricate replacement components, using relatively simple equipment and low material and instrument costs. The gallium/aluminum pairing is of particular interest due to the usage of aluminum in a wide variety of structural and aerospace applications coupled with gallium's nontoxicity and melting point just above room temperature, which facilitates storage and transport. To activate aluminum to gallium infiltration, the surface oxide formed on aluminum in atmosphere must first be removed simultaneously with a significant amount of bulk metal to promote flow control of the liquid metal. Three targeted techniques for oxide removal were tested and compared, specifically mechanical abrasion, chemical etching, and laser ablation. Mechanical abrasion is simple to implement but lower precision. Chemical etching requires significant prep work and cleanup but could operate on entire sheets of substrate simultaneously with proper masking. Although laser ablation requires the most complex instrumentation, it requires minimal prep work and provides the greatest precision, making it ideal for the manufacturing application under development here. [ABSTRACT FROM AUTHOR]

Published

2024

16. Laser-Induced Graphene Decorated with MOF-Derived NiCo-LDH for Highly Sensitive Non-Enzymatic Glucose Sensor.

Author

Li, Longxiao, Han, Yufei, Zhang, Yuzhe, Wu, Weijia, Du, Wei, Wen, Guojun, and Cheng, Siyi

Subjects

*CHEMICAL detectors, *LASER engraving, *ELECTROCHEMICAL sensors, *ELECTRON transport, *SUBSTRATES (Materials science)

Abstract

Designing and fabricating a highly sensitive non-enzymatic glucose sensor is crucial for the early detection and management of diabetes. Meanwhile, the development of innovative electrode substrates has become a key focus for addressing the growing demand for constructing flexible sensors. Here, a simple one-step laser engraving method is applied for preparing laser-induced graphene (LIG) on polyimide (PI) film, which serves as the sensor substrate. NiCo-layered double hydroxides (NiCo-LDH) are synthesized on LIG as a precursor, utilizing the zeolitic imidazolate framework (ZIF-67), and then reacted with Ni(NO3)2 via solvent-thermal methods. The sensitivity of the non-enzymatic electrochemical glucose sensor is significantly improved by employing NiCo-LDH/LIG as the sensing material. The porous and interconnected structure of NiCo-LDH, derived from ZIF-67, enhances the accessibility of electrochemically active sites, while the incorporation of LIG ensures exceptional conductivity. The combination of NiCo-LDH with LIG enables efficient electron transport, leading to an increased electrochemically active surface area and enhanced catalytic efficiency. The fabricated electrode achieves a low glucose detection limit of 0.437 μM and demonstrates a high sensitivity of 1141.2 and 631.1 μA mM−2 cm−2 within the linear ranges of 0–770 μM and 770–1970 μM, respectively. Furthermore, the NiCo-LDH/LIG glucose sensor demonstrates superior reliability and little impact from other substances. A flexible integrated LIG-based non-enzymatic glucose sensor has been developed, demonstrating high sensitivity and suggesting a promising application for LIG-based chemical sensors. [ABSTRACT FROM AUTHOR]

Published

2024

17. Dynamic wetting performance and resin-flow behavior of two-level selective laser-etched metal surface in resin transfer moulding process of fiber-metal laminates.

Author

Liang, Meile, Zhang, Wen, Zhuang, Xincun, and Zhao, Zhen

Subjects

*FLUID flow, *TRANSFER molding, *COMPUTATIONAL fluid dynamics, *POROUS materials, *LASER engraving

Abstract

In selective laser etching for the interfacial strengthening of Fiber Metal Laminates (FMLs), the wettability of customized structured features significantly affects their overall mechanical properties. For two-level features, their complicated geometry makes the evaluation of wettability difficult, which introduces challenges to feature design. In this study, a sandwich FMLs comprising an AA2024-O metal skin and a plain-woven carbon-fiber fabric core is investigated. Three types of two-level feature interfaces are designed and introduced into the FMLs structure. To understand the effect of two-level features on the resin flow and dynamic wetting progress in resin transfer molding, two-phase flow Computational Fluid Dynamics numerical models coupled with porous media and level-set numerical methods are built. The feasibility of the numerical simulation in the qualitative analysis was verified by comparing the results with those of the testing porosity values from X-ray scanning. In addition, the mechanisms of pore formation and transportation are revealed. These results indicate that the deeper groove structure in the etched features plays an important role in discharging residual air and determining the transformation of pores to reduce porosity. The permeability orientations of the porous media and surface structure both have significant impacts on the flow behavior and formation of pores. [ABSTRACT FROM AUTHOR]

Published

2024

18. Advantages of laser etching of metals and semiconductors when working in space.

Author

Khomich, Yury V., Malinskiy, Taras V., Rogalin, Vladimir E., Shakhmatov, Evgeniy V., Yamshchikov, Vladimir A., and Zheleznov, Viacheslav Yu.

Subjects

*LASER engraving, *METAL fatigue, *PLASMA etching, *METAL detectors, *FIRE prevention

Abstract

To work in space, it is necessary to create high-tech production facilities in orbit. It seems that they should include a universal, compact, powerful laser device to perform various tasks. The paper considers only one, relatively new, direction of laser use, designed to improve the fire safety of a spacecraft. An environmentally safe method of "dry" laser etching for the rapid detection of the structure of metals and semiconductors is proposed. • Nanosecond pulses of Nd:YAG laser were used for Ge and Cu surface modification. • Dry laser etching is proposed for quality control of space-grown Ge single crystals. • Laser etching is proposed for fatigue control of metal products of orbital stations. [ABSTRACT FROM AUTHOR]

Published

2024

19. Influence of Different Enamel Pretreatment on Bond Strength of Fissure Sealant.

Author

Doberdoli, Dafina and Jurić, Hrvoje

Subjects

LASER engraving, YAG lasers, PIT & fissure sealants (Dentistry), QUANTUM groups, BOND strengths

Abstract

Copyright of Acta Stomatologica Croatica is the property of Acta Stomatologica Croatica and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

20. Developing a soft micropatterned substrate to enhance maturation of human induced pluripotent stem cell-derived cardiomyocytes.

Author

Maaref, Yasaman, Jannati, Shayan, Jayousi, Farah, Lange, Philipp, Akbari, Mohsen, Chiao, Mu, and Tibbits, Glen F

Subjects

INDUCED pluripotent stem cells, DRUG discovery, SUBSTRATES (Materials science), LASER engraving, FETAL heart

Abstract

Human induced pluripotent stem cell-derived cardiomyocytes (hiPSC CMs) offer numerous advantages as a biological model, yet their inherent immaturity compared to adult cardiomyocytes poses significant limitations. This study addresses hiPSC CM immaturity by introducing a physiologically relevant micropatterned substrate for long-term culture and maturation. An innovative microfabrication methodology combining laser etching and casting creates a micropatterned polydimethylsiloxane (PDMS) substrate with varying stiffness, from 2 to 50 kPa, mimicking healthy and fibrotic cardiac tissue. Platinum electrodes were integrated into the cell culture chamber enable pacing of cells at various frequencies. Subsequently, cells were transferred to the incubator for time-course analysis, ensuring contamination-free conditions. Cell contractility, cytosolic Ca2+ transient, sarcomere orientation, and nucleus aspect ratio were analyzed in a 2D hiPSC CM monolayer up to 90 days post-replating in relation to substrate micropattern dimensions. Culturing hiPSC CMs for three weeks on a micropatterned PDMS substrate (2.5–5 µm deep, 20 µm center-to-center spacing of grooves, 2–5 kPa stiffness) emerges as optimal for cardiomyocyte alignment, contractility, and cytosolic Ca2+ transient. The study provides insights into substrate stiffness effects on hiPSC CM contractility and Ca2+ transient at immature and mature states. Maximum contractility and fastest Ca2+transient kinetics occur in mature hiPSC CMs cultured for two to four weeks, with the optimum at three weeks, on a soft micropatterned PDMS substrate. MS proteomic analysis further revealed that hiPSC CMs cultured on soft micropatterned substrates exhibit advanced maturation, marked by significant upregulation of key structural, electrophysiological, and metabolic proteins. This new substrate offers a promising platform for disease modeling and therapeutic interventions. Human induced pluripotent stem cell derived cardiomyocytes (hiPSC CMs) have been transformative to disease-in-a-dish modeling, drug discovery and testing, and autologous regeneration for human hearts and their role will continue to expand dramatically. However, one of the major limitations of hiPSC CMs is that without intervention, the cells are immature and represent those in the fetal heart. We developed protocols for the fabrication of the PDMS matrices that includes variations in its stiffness and micropatterning. Growing our hiPSC CMs on matrices of comparable stiffness to a healthy heart (5 kPa) and grooves of 20 μm, generate heart cells typical of the healthy adult human heart. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

21. Discolouration and Chemical Changes of Beech Wood After CO 2 Laser Engraving.

Author

Kúdela, Jozef, Kubovský, Ivan, and Andrejko, Michal

Subjects

HIGH power lasers, CARBON dioxide lasers, LASER engraving, INFRARED lasers, INFRARED radiation

Abstract

This study evaluated the influence of infrared laser radiation produced by a CO2 laser, performing under different engraving parameters, on the colour changes and chemical composition of a beech wood surface. The results showed that the lightness clearly decreased with increasing laser power and density. At the highest laser power and the highest raster density, the ΔL* value was 51.3. The values of coordinates a* and b* moderately increased up to a raster density of 5 mm−1; then, with a subsequent raster density increase, the values of these coordinates decreased again. However, the coordinate values were positive in all cases. Even the lowest laser power and raster density resulted in conspicuous discolouration or even a completely new colour compared to the original (ΔE = 10) of the beech wood surface. Further increases in the laser power and raster density resulted in progressively pronounced colour differences and a darker brown colour of the surface. The ATR-FTIR chemical analysis of the beech wood surface revealed that discolouration was mainly caused by heat-induced processes associated with the degradation of carbonyl groups (C=O) in lignin and hemicelluloses. The splitting of C=O bonds induced changes in the content of chromophores responsible for the natural wood colour and for the engraving-related discolouration. The study demonstrates that the amount of energy supplied onto the wood surface by a laser beam using diverse combinations of radiation parameters can be represented by a single variable: the total irradiation dose. The functional relation detected between this variable and the colour differences may serve as a basis for using a controlled laser beam for targeted wood surface discolouration to improve the quality of patterns transferred onto a wood surface. Knowledge of this relation will enable the targeted setting of the laser parameters during engraving so that the laser beam can be used as a tool for transferring high-quality patterns onto wood surfaces. [ABSTRACT FROM AUTHOR]

Published

2024

22. Flexible Supercapacitor Device Based on Laser‐Synthesized Nanographene for Low‐Power Applications.

Author

Awasthi, Himanshi, Kumar, Pavar Sai, Thundat, Thomas, and Goel, Sanket

Subjects

NANOSTRUCTURED materials, LASER engraving, PHOTOELECTRON spectroscopy, GRAPHENE oxide, ENERGY density

Abstract

Laser‐induced graphene (LIG) and laser‐induced reduced graphene oxide (LIrGO) are two relatively recent graphene‐based nanoscale materials suitable for miniaturized flexible supercapacitors. This study employs direct laser engraving techniques to generate patterns on flexible substrates, such as paper and polyamide (PI). This methodology allows fine control over the formed nanographene structures to fabricated LIG and LIrGO supercapacitors. The LIG on PI exhibits a distinctive porous structure and high surface area, adsorption, and transportation of ions. Furthermore, paper‐based LIrGO electrodes are recyclable and are formed in a single step. The morphological study is done using scanning electron microscopy, Raman spectroscopy, X‐ray photoelectron spectroscopy, and X‐ray diffraction. Galvanostatic charge–discharge studies at 0.05 mA cm−2 current density show an areal capacitance of 3.69 mF cm−2 for LIG and 1.61 mF cm−2 for LIrGO. The comparable energy densities for LIG and LIrGO are 0.32 and 0.16 μWh cm−2, respectively. From the calculative analysis of both types, the variation in specific areal capacitance enabling effective is 56.3% from GCD, indicating that the LIG device performs better. Finally, a portable potentiostat is employed to investigate the viability of utilizing supercapacitors to operate self‐powered sensors in a portable and integrable fashion. [ABSTRACT FROM AUTHOR]

Published

2024

23. Laser Preparation and Underwater Drag-Reduction Performance of Secondary Fractal–V Groove Composite Structures on the Surface of Equal-Diameter Revolution Bodies.

Author

Wang, Yan, Hu, Zhanpeng, Zhang, Qian, Yang, Zhisheng, Zhao, Xueyan, and Wang, Yonghua

Subjects

DRAG reduction, LASER engraving, COMPOSITE structures, REYNOLDS number, SURFACE structure

Abstract

The reduction of drag for both aircraft and underwater equipment has the potential to reduce their overall energy consumption. Consequently, research into the drag-reducing performance of metal surfaces has significant practical applications. However, there has been more research on the machining of grooves on flat surfaces and inside tubes and less research on the structure of drag-reducing grooves on the outside of circular rods. This paper presents a study in which laser etching technology is employed to machine a range of secondary fractal topologies and V-groove composite structures on the surface of equal-diameter stainless-steel bodies of revolution. The influence of different parameters on the surface properties of stainless-steel materials is analysed through the use of auxiliary positioning tools, adjustments to laser processing parameters and scanning path schemes, as well as the characterisation of the surface morphology of the processed stainless steel using super-depth microscopy, scanning electron microscopy, and other techniques. Subsequently, an underwater drag-reduction tester is employed to assess the drag-reduction efficacy of the optimised secondary fractal composite structure on the surface of the stainless-steel equal-diameter body of revolution. Subsequently, particle image velocity (PIV) tracking technology is employed to assess the surface flow field velocity and overall velocity average of the secondary fractal composite structure. The findings indicate that the secondary fractal composite structure exhibited a drag-reduction effect on the surface of the stainless-steel body of revolution only when the primary main groove had a width of 0.1 mm. Furthermore, an increase in the Reynolds number Re within the range of 4000 to 7000 resulted in a notable enhancement in the drag-reduction efficacy of the secondary fractal composite structure on the surface of the stainless-steel body of revolution. At Re values of 5000, 6000, and 7000, the corresponding drag-reduction rates were observed to be 5.15%, 5.28%, and 5.40%, respectively. [ABSTRACT FROM AUTHOR]

Published

2024

24. Preparation of Diamond Films with Cracked Textures on Stainless Steel Using W/W-N Film as an Interlayer.

Author

Li, Xiao, Shan, Yule, Xia, Fan, Chen, Chengke, Lu, Shaohua, and Hu, Xiaojun

Subjects

DIAMOND films, CHEMICAL vapor deposition, LASER engraving, VIBRATION (Mechanics), LASER ultrasonics

Abstract

The growth of diamond film with texture on stainless steel can significantly improve its wear properties, while conventional methods such as laser etching and ultrasonic vibration superimposed machining suffered from complex processes and extra equipment. Here, we propose a simple new method to prepare textured diamond film on stainless steel without any special apparatus. In this method, a W/W-N interlayer was first deposited on the stainless steel surface, and then the sample with the interlayer was put into a hot filament chemical vapor deposition (HFCVD) chamber to grow diamond films. The interlayer becomes cracked during the warm-up stage due to the large tensile stress formed by the thermal expansion coefficient difference between the interlayer and the steel. Then the deposited diamond films copy the morphology of the interlayer, forming the textured diamond film. The textured diamond film exhibits a small amount of stress, ~3.4 GPa, and greatly improved wear resistance. Our results provide a way to prepare textured diamond films with good wear resistance. [ABSTRACT FROM AUTHOR]

Published

2024

25. A simple method to remove polyimide coating from fused silica capillaries for capillary electrophoresis

Author

Wang, Pan, Cheng, Yulin, and Wei, Wei

Published

2024

26. Enhanced room temperature CO2 photoreduction on gas-solid interfaces using nanocrystals integrated with ZIF-8 wrapping design.

Author

Hou, Xiaoxiong, Ma, Zhuangzhuang, Zhang, Zhilei, Gao, Xiaotong, Wang, Hongqiang, and Jia, Lichao

Subjects

LASER engraving, GAS-solid interfaces, ARTIFICIAL photosynthesis, PHOTOREDUCTION, CHARGE exchange

Abstract

• Novel TiO 2 nanocrystals prepared by sonolaser ablation was firstly wrapped in ZIF-8 as composite photocatalyst. • Highest CO and CH 4 evolution rates of up to 250. 24 and 25.43 µmol g-1 h-1 were achieved in Pt x +-TiO 2 @ZIF-8. • The recombination of photo-induced electron-hole pairs had been impeded. • The enhanced performance relates to abundant active sites and effective Z-type charge-transfer channel. Composites derived from metal-organic frameworks (MOFs) show promise as catalysts for the photocatalytic reduction of CO 2. However, their potential is hindered by constraints such as limited light absorption and sluggish electron transfer and separation, impacting the overall efficiency of the photocatalytic process. In this study, TiO 2 nanocrystals, modified with Pt x+, underwent laser etching were encapsulated within the traditional MOF-ZIF-8 framework. This enhanced the adsorption capabilities for CO 2 reactants and solar light, while also facilitating directed electron transfer and the separation of photogenerated charges. The finely-tuned catalyst demonstrates impressive CH 4 selectivity at 9.5 %, with yields of 250. 24 µmol g-1 h-1 for CO and 25.43 µmol g-1 h-1 for CH 4 , utilizing water as a hole trap and H+ source. This study demonstrates the viability of achieving characteristics related to the separation of photogenerated charges in TiO 2 nanocrystals through laser etching and MOF composite catalysts. It offers novel perspectives for designing MOF-based catalysts with enhanced performance in artificial photosynthesis. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2025

27. SELECTING SUPER STOPPERS.

Author

CERIDONO, RON

Subjects

AUTOMOBILE parts, BRAKE systems, LASER engraving, TRAFFIC safety, STEEL wire, DISC brakes, SCREWS

Abstract

The article discusses the selection of Wilwood brake components for a 1972 Chevy Nova by Eddie Motorsports. The team opted for a six-piston caliper kit in the front and a four-piston caliper in the rear for street driving and occasional autocross. The article also covers topics such as rotor diameter, master cylinder size, brake pedal ratios, brake line recommendations, proportioning valves, and bedding procedures for the brakes. The text provides detailed instructions on adjusting wheel bearings and includes a list of Wilwood parts used in the Nova. [Extracted from the article]

Published

2025

28. Exploding foils with artificial structure as a source of ultraviolet radiation.

Author

Tilikin, I. N., Shelkovenko, T. A., Pikuz, S. A., Oginov, A. V., Mingaleev, A. R., Romanova, V. M., and Ter-Oganesyan, A. E.

Subjects

*RADIATION sources, *PINHOLE cameras, *LASER engraving, *MICROCHANNEL plates, *PULSE generators

Abstract

The results of the study of radiation produced by the electrical explosion of Al foil with a thickness of 4 μm with an artificial periodic structure of periodic holes with 50–400 μm steps created by laser engraving are presented. The experiments were carried out on a KING pulse high-current generator (220 kA, 40 kV, 300 ns). Images of exploded foils were recorded using pinhole cameras with a 20 μm aperture on a four-frame microchannel plate camera with 5 ns temporal resolution. In experiments on the electrical explosion of thin foils, it was shown that the application of an artificial periodic structure to the foil leads to a much more uniform radiation in the UV spectrum range along the entire length and width of the foil. Uniform radiation was observed from 20 to 70 ns. It is shown that such radiation can be used for the imaging of test objects or plasma objects like exploded wires. [ABSTRACT FROM AUTHOR]

Published

2023

29. Effects of femtosecond laser on hard dental tissues: A scoping review.

Author

Javed, Faraha, Akhter, Rahena, and Miletic, Vesna

Subjects

*DENTAL enamel, *FEMTOSECOND lasers, *LASER engraving, *DENTINAL tubules, *OPTICAL coherence tomography

Abstract

Traditional tooth preparation can cause patient discomfort, thermal damage to tissues, and occupational health risks for clinicians. Laser-based techniques, particularly femtosecond lasers, offer an alternative due to precise, non-invasive treatment without the thermal and mechanical drawbacks. The objective of this study was to assess available evidence on the effects of femtosecond laser treatment on enamel and dentin. The study design included in vitro or in vivo studies on human teeth reporting on qualitative and quantitative parameters of laser-dental tissue interaction. The review followed the Preferred Reporting Items for Systematic Reviews and Meta-Analyses extension for Scoping Reviews (PRISMA-ScR) statement. The review was registered in the Open Science Framework registry. A comprehensive literature search of PubMed, Scopus, EMBASE/Ovid, Cochrane Library, DARE, LILACS and Pro Quest databases was conducted by three reviewers until 10th January 2024 and then updated on 18th August 2024. Eligibility criteria included peer-reviewed articles published in English, focusing on human teeth, with available full text excluding reviews, conference proceedings and gray literature. The outcomes of interest were the quality of tooth preparation, surface characteristics, bond strength, thermal effects and damage to adjacent tissues with variables being laser parameters and tooth types. Methodological quality of studies was not conducted. The search yielded 48 articles after the removal of duplicates, irrelevant and non-retrievable articles. All were original in vitro studies investigating reporting on the outcomes of interest. Measurement methods included a range of microscopy, spectroscopy, optical coherence tomography, universal force testing and thermal imaging. Sapphire lasers were most commonly used with a wide range of parameters. Laser produced sharp-edged cavities with ablated surfaces free of melting (seen in approximately 10% of the craters), cracking, debris, with open dentinal tubules, increased wetting (Contact angle mean range 39.63 ̊(± 1.84 ̊) to 70.47 ̊(± 10.27 ̊) and roughness mean range 0.82 (± 0.05) to 4.20 (± 1.10)µm). Effects of femtosecond laser on bonding efficiency were inconsistent when compared to no treatment, conventional acid etching or Er:YAG laser. Femtosecond laser was shown to achieve precise tooth preparation with no or minimal thermal, mechanical and structural effects on adjacent tissue, however with variable bonding efficiency. Further research is needed to optimize laser parameters, investigate antibacterial effects, and establish long-term clinical outcomes and safety profiles. Date of registration: July 1st, 2024. Registration ID: OSF.IO/UQMNB. [ABSTRACT FROM AUTHOR]

Published

2024

30. Direction, Shape, and Scale Dependence of Ice Adhesion on Topographical Wetting Gradients.

Author

Misiiuk, Kirill, Blaikie, Richard, Sommers, Andrew, and Lowrey, Sam

Subjects

LASER engraving, SURFACE tension, PHYSICAL & theoretical chemistry, SHEARING force, SURFACE area

Abstract

In this work, a shear stress test is used to evaluate the ice adhesion strength on "as received", polished and micro/nanoengineered hierarchical superhydrophobic aluminium (produced via one-step laser etching) with fixed- and gradient-pitch structures. Due to the potential mismatch between the ice formation area and the wetting gradient length scale, the shear stress test method has been analysed in detail to understand its applicability to topographic gradients, since this could provide misleading results as compared with the application of this method to fixed-pitch topographic structured surfaces. To address this, the influence of the ice-surface contact area, as well as the mould shape and mould material, on the ice adhesion results, was observed for all samples. Moreover, the impact of the direction of the removal force was investigated on the wetting gradients. Key results are that topographically altered surfaces can be hydrophobic, but not icephobic; whereas non-altered surfaces are hydrophilic, but with much lower ice adhesion. Additionally, gradient surfaces were observed to provide hydrophobicity for most areas of the surface, while allowing removal of the ice column at lower forces from certain directions. [ABSTRACT FROM AUTHOR]

Published

2024

31. A Comparative Study of Laser Etching and Laser Shock Imprinting (LSI) for the Fabrication of a Multiscale Microtexture on TA1 Foil Surfaces.

Author

LI, P., LIU, B. Y., MENG, K. N., HU, S., and SHEN, Z. B.

Subjects

*LASER engraving, *ND-YAG lasers, *SURFACE stability, *SURFACE plates, *GRAIN refinement, *WEAR resistance

Abstract

Multiscale microtextures were fabricated on the surface of TA1 foil using laser etching and laser shock imprinting (LSI) processes. First, laser etching process was employed to directly fabricate multiscale microtextures on the 20 µm thick TA1 foil as the laser etching workpiece. Then, using the same laser etching parameters, multiscale microtextures were processed on a 1 mm thick TA1 plate surface as the mould for LSI. Finally, the LSI was used to replicate similar multiscale microtextures from the mould surface, and the influence of pulse number and power density on the forming depth and replication degree of the TA1 workpiece was analysed. By comparing the aging effect and durability of the hydrophobic TA1 foils treated by laser etching and LSI processes, the differences in chemical composition stability and mechanical stability between laser etching and LSI surfaces were analysed. The laser etching surface exhibited a super-hydrophilic state within 12 hours and tended to be a superhydrophobic state after 30 days of storage in air. In contrast, no obvious aging effect was observed on the surface of the LSI samples, indicating better stability of surface wettability (110°

Published

2024

32. Cartilage Laser Engraving for Fast-Track Tissue Engineering of Auricular Grafts.

Author

Kisel, Anastas A., Stepanov, Vladimir A., Isaeva, Elena V., Demyashkin, Grigory A., Isaev, Evgeny I., Smirnova, Ekaterina I., Yatsenko, Elena M., Afonin, Grigoriy V., Ivanov, Sergey A., Atiakshin, Dmitrii A., Shegay, Petr V., Kaprin, Andrey D., Klabukov, Ilya D., and Baranovskii, Denis S.

Subjects

*LASER engraving, *REGENERATIVE medicine, *SCANNING electron microscopy, *POWER density, *CARTILAGE, *CARTILAGE regeneration

Abstract

In this study, the optimal engraving parameters were determined through the analysis of scanning electron microscopy (SEM) data, as follows: a laser power density of 5.5 × 105 W/cm2, an irradiation rate of 0.1 mm/s, a well radius of 60 μm, a distance between well centers of 200 μm, and a number of passes for each well of 20. After 1 week of in vitro cultivation, chondrocytes were located on the surface of the scaffolds, in the sockets and lacunae of decellularized cartilage. When implanted into animals, both cellular and acellular scaffolds were able to support cartilage in-growth and complete regeneration of the defect without clear boundaries with normal tissue. Nevertheless, the scaffolds populated with cells exhibited superior biocompatibility and were not subject to rejection, in contrast to cell-free constructs. [ABSTRACT FROM AUTHOR]

Published

2024

33. Enhancing Performance of Composite-Based Triboelectric Nanogenerators Through Laser Surface Patterning and Graphite Coating for Sustainable Energy Solutions.

Author

Amorntep, Narong, Siritaratiwat, Apirat, Srichan, Chavis, Sriphan, Saichon, Wiangwiset, Thalerngsak, Ariyarit, Atthaporn, Supasai, Wisut, Bootthanu, Nuttapong, Narkglom, Sorawit, Vittayakorn, Naratip, and Surawanitkun, Chayada

Subjects

*NANOGENERATORS, *CLEAN energy, *LASER engraving, *OPEN-circuit voltage, *SHORT-circuit currents

Abstract

The performance of composite-based triboelectric nanogenerators (C–TENGs) was significantly enhanced through laser surface patterning and graphite coating. The laser etching process produced accurate and consistent patterns, increasing surface area and improving charge accumulation. SEM imagery confirmed the structural differences and enhanced surface properties of the laser-etched C–TENGs. Graphite fibers further augmented the contact surface area, enhancing charge accumulation and diffusion. Experimental results demonstrated that the optimized C–TENGs, especially those with line patterns and graphite coating, achieved a maximal 98.87 V open-circuit voltage (VOC) and a 0.10 µA/cm2 short-circuit current density (JSC) under a 20 N external force. Environmental tests revealed a slight decrease in performance with increased humidity, while long-term stability tests indicated consistent performance over three weeks. Practical application tests showed the potential of C–TENGs integrated into wearable devices, generating sufficient energy for low-power applications, thereby highlighting the promise of these devices for sustainable energy solutions. [ABSTRACT FROM AUTHOR]

Published

2024

34. Recent Advances in Black Silicon Surface Modification for Enhanced Light Trapping in Photodetectors.

Author

Alsolami, Abdulrahman, Hussain, Hadba, Noor, Radwan, AlAdi, Nourah, Almalki, Nada, Kurdi, Abdulaziz, Tabbakh, Thamer, Zaman, Adnan, Alfihed, Salman, and Wang, Jing

Subjects

LASER engraving, PLASMA etching, LASER ablation, SILICON surfaces, PHOTODETECTORS

Abstract

The intricate nanostructured surface of black silicon (BSi) has advanced photodetector technology by enhancing light absorption. Herein, we delve into the latest advancements in BSi surface modification techniques, specifically focusing on their profound impact on light trapping and resultant photodetector performance improvement. Established methods such as metal-assisted chemical etching, electrochemical etching, reactive ion etching, plasma etching, and laser ablation are comprehensively analyzed, delving into their mechanisms and highlighting their respective advantages and limitations. We also explore the impact of BSi on the emerging applications in silicon (Si)-based photodetectors, showcasing their potential for pushing the boundaries of light-trapping efficiency. Throughout this review, we critically evaluate the trade-offs between fabrication complexity and performance enhancement, providing valuable insights for future development in this rapidly evolving field. This knowledge on the BSi surface modification and its applications in photodetectors can play a crucial role in future implementations to substantially boost light trapping and the performance of Si-based optical detection devices consequently. [ABSTRACT FROM AUTHOR]

Published

2024

35. High precision microscale 3D manufacturing of ultralow expansion glass by femtosecond selective laser etching.

Author

Casamenti, Enrico, Bruno, Alessandro, Bernasconi, Pietro, and Lovera, Andrea

Subjects

LASER engraving, GLASS fibers, OPTICAL properties, GLASS structure, FIBER lasers

Abstract

Due to its exceptional dimensional stability in harsh thermal conditions and excellent mechanical and optical properties, Corning ultralow expansion (ULE®) glass is the material of choice in many high-demanding fields such as aerospace, astronomy, and advanced optics. This material has recently attracted renewed attention with the advent of femtosecond laser technology, with a particular focus on the interaction of ultrafast pulses and the material itself. Phenomena like the formation of self-assembled nanogratings and their thermal stability as well as the darkening of laser-affected zones have then been characterized. This paper presents how to exploit femtosecond selective laser etching (SLE) techniques to manufacture truly three-dimensional components. To demonstrate the micrometer-scale accuracy and repeatability of this process from the mm- to the cm-size range, various devices are designed and fabricated: fiber hole arrays with different hole densities, sizes, orientations, and shapes; and fiber V-groove arrays. Additionally, a mechanical flexural fiber mount is presented as an example of how multiple functionalities can be monolithically integrated into a single piece of glass through SLE technology. An example of a passive alignment substrate for optical components is also shown. SLE technique represents a new advancement in the field of microscale manufacturing, enabling the scalable production of custom-designed ULE® glass structures with unprecedented precision and complexity, paving the way for the miniaturized integration of highly stable components. [ABSTRACT FROM AUTHOR]

Published

2024

36. Modeling and experimental study on a photochemical microscale continuous oscillatory baffled reactor.

Author

Liu, Peiwen, Zhu, Weiping, and Zhao, Fang

Subjects

COMPUTATIONAL fluid dynamics, LASER engraving, PHOTOCATALYTIC oxidation, FEMTOSECOND lasers, MASS transfer

Abstract

Herein, the first photochemical microscale continuous oscillatory baffled reactor, that is, Photo‐μCOBR, was designed and evaluated. Computational fluid dynamics simulations were used to optimize the key structural parameter and operating conditions. Then, the mixing process was simulated and the μCOBR was shown to be more than 23 times faster than the straight channel both under oscillating conditions. Finally, a glass Photo‐μCOBR was fabricated by femtosecond laser internal engraving technology, and the photocatalytic gas–liquid oxidation of dihydroartemisinic acid was performed. A yield of 65.9% was achieved in a residence time of ~120 s and at a gas–liquid flow rate ratio of 1:3 (vs. 18.6% in the capillary photomicroreactor under identical conditions). The results in this work offer guidelines for the design and operation of microscale COBRs, and the as‐fabricated Photo‐μCOBR displays good potential for gas–liquid photochemical reactions. [ABSTRACT FROM AUTHOR]

Published

2024

37. Stability Challenges in Industrialization of Perovskite Photovoltaics: From Atomic‐Scale View to Module Encapsulation.

Author

Chen, Hongyu, Yan, Wensheng, and Chu, Liang

Subjects

*LASER engraving, *PHOTOVOLTAIC power generation, *CRYSTAL grain boundaries, *PEROVSKITE, *INDUSTRIALIZATION

Abstract

Perovskite photovoltaics have attracted significant attention in both academia and industry, benefiting from the superiorities of high efficiency, low cost, and simplified fabrication process. Importantly, long‐term stability is essential for practical industrialization; however, the stability challenge remains a significant impediment. Notably, stability is an essential prerequisite for practical applications. Unfortunately, as the device area increases, even to the module level, the efficiency gradually diminishes, and the stability deteriorates. This review summarizes the advances in perovskite photovoltaic technology stability from comprehensive perspectives, including the atomic‐scale, grain boundary, film morphology, interface, charge transport layer, electrode, laser etching, and module encapsulation. First, the review highlights the ongoing importance of stability in the industrialization of perovskite photovoltaics. Then, the review presents the stability challenge and explores the relationship between efficiency and stability in large‐area photovoltaic modules, shedding light on the stability issue. Later, the review explains the stability issue in terms of structure, chemistry, interfaces, device design, operation, and external environment, and proposes stability strategies ranging from the atomic‐scale to module encapsulation. Finally, the review emphasizes various improvement strategies, particularly multilevel synergistic optimization, offering fundamental guidance for the industrialization of perovskite photovoltaics. [ABSTRACT FROM AUTHOR]

Published

2024

38. Nanochannels in Fused Silica through NaOH Etching Assisted by Femtosecond Laser Irradiation.

Author

Barbato, Pasquale, Osellame, Roberto, and Martínez Vázquez, Rebeca

Subjects

*LASER engraving, *FUSED silica, *FEMTOSECOND lasers, *FEMTOSECOND pulses, *SODIUM hydroxide

Abstract

Sodium hydroxide (NaOH) is increasingly drawing attention as a highly selective etchant for femtosecond laser-modified fused silica. Unprecedented etching contrasts between the irradiated and pristine areas have enabled the fabrication of hollow, high-aspect-ratio structures in the bulk of the material, overcoming the micrometer threshold as the minimum feature size. In this work, we systematically study the effect of NaOH solutions under different etching conditions (etchant concentration, temperature, and etching time) on the tracks created by tightly focused femtosecond laser pulses to assess the best practices for the fabrication of hollow nanostructures in bulk fused silica. [ABSTRACT FROM AUTHOR]

Published

2024

39. 砂轮表面的磨料球自组装叶序排布原理.

Author

李胜泽, 吕玉山, 李兴山, and 南杰洪

Subjects

GRINDING wheels, LASER engraving, FIBONACCI sequence, SPHERE packings, MEASURING instruments

Abstract

Copyright of Diamond & Abrasives Engineering is the property of Zhengzhou Research Institute for Abrasives & Grinding and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

40. 耐磨防覆冰聚四氟乙烯表面设计与加工.

Author

何志豪, 张柄桢, 潘维浩, 孙晶, and 宋金龙

Subjects

SUPERHYDROPHOBIC surfaces, LASER engraving, CONTACT angle, WEAR resistance, CLEANING equipment

Abstract

Copyright of Acta Materiae Compositae Sinica is the property of Acta Materiea Compositae Sinica Editorial Department and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

41. Shear bond strength of a composite resin restoration in primary teeth following cavity preparation using laser- an in-vitro study.

Author

Babu, K. L. Girish, Hebbar, Kavyashree Gururaj, and Doddamani, Geeta Maruti

Subjects

*MOLARS, *DECIDUOUS teeth, *LASER engraving, *SHEAR strength, *YAG lasers

Abstract

To evaluate and compare the shear bond strength of composite resin restorations in primary teeth, following cavity preparation with both traditional dental burs and laser irradiation. One hundred primary molars extracted from the children visiting our department were collected and randomly divided into five groups (A-E) with 20 teeth in each group. In groups A, B, C, D, and E the teeth samples were etched with phosphoric acid, Er; YAG laser followed by acid etching, Er, Cr: YSGG laser followed by acid etching, Er; YAG laser etching only and Er, Cr: YSGG laser etching only, respectively. Following, all the samples were restored with composite resin and subjected to 500 cycles of thermocycling. The shear bond strength of the resin composite was analyzed. The type of fractures was also noted. Data obtained were subjected to statistical analysis. The mean value of shear bond strength of Group A, B, C, D, and E was 17.562 ± 0.810, 15.928 ± 0.415, 14.964 ± 0.566, 11.833 ± 0.533 and 11.187 ± 0.517, respectively. Adhesive failure was most commonly seen in all the groups. The phosphoric acid etching remains a highly effective technique for pre-treating dentin in composite resin restorations. The shear strength of composite resin to the dentin of laser-prepared cavity in primary teeth can be improved by the addition of acid etching. [ABSTRACT FROM AUTHOR]

Published

2024

42. PRISM: three-dimensional sub-diffractive phase-resolved imaging spectroscopic method.

Author

Dobrowolski, Artur, Jagiełło, Jakub, Pyrzanowska, Beata, Piętak-Jurczak, Karolina, Możdżyńska, Ewelina B., and Ciuk, Tymoteusz

Subjects

*CHEMICAL vapor deposition, *ATOMIC layer deposition, *LIGHT absorption, *LASER engraving, *PLASMA spectroscopy

Abstract

We demonstrate a genuine method for three-dimensional pictorial reconstructions of two-dimensional, three-dimensional, and hybrid specimens based on confocal Raman data collected in a back-scattering geometry of a 532-nm setup. The protocol, or the titular PRISM (Phase-Resolved Imaging Spectroscopic Method), allows for sub-diffractive and material-resolved imaging of the object's constituent material phases. The spacial component comes through either the signal distal attenuation ratio (direct mode) or subtle light-matter interactions, including interference enhancement and light absorption (indirect mode). The phase component is brought about by scrutinizing only selected Raman-active modes. We illustrate the PRISM approach in common real-life examples, including photolithographically structured amorphous Al2O3, reactive-ion-etched homoepitaxial SiC, and Chemical Vapor Deposition graphene transferred from copper foil onto a Si substrate and AlGaN microcolumns. The method is implementable in widespread Raman apparatus and offers a leap in the quality of materials imaging. The lateral resolution of PRISM is stage-limited by step motors to 100 nm. At the same time, the vertical accuracy is estimated at a nanometer scale due to the sensitivity of one of the applied phenomena (interference enhancement) to the physical property of the material (layer thickness). [ABSTRACT FROM AUTHOR]

Published

2024

43. Wireless control system for laser cutters and engraving machines.

Author

Gopalan, Sangeetha Rengachary, Jegan, Bhavithrah, and Govindarajan, Thirumalai Srinivasan

Subjects

*LASER engraving, *AUTOMATION, *NUMERICAL control of machine tools, *REMOTE control, *SYSTEMS design

Abstract

This paper presents an industrial wireless control and monitoring system for laser cutters and engravers based on computer numerical control (CNC), which aims to improve the overall performance, efficiency, and safety of the CNC machine and its peripherals as an ecosystem by allowing users to operate and maintain it remotely using Wi-Fi. The developed system is implemented through a dynamic hardware module and a multi-OS user application, thereby establishing real-time and simplified communication between the operator and the Laser Cutter/Engraver-CNC ecosystem for remote control and monitoring functions. Further, the system allows for configuring machine settings, and the start or stop of cutting or engraving processes. A Laser Cutter/Engraver-CNC ecosystem prototype was built and used in a test-validated environment to confirm the effectiveness of this system design. [ABSTRACT FROM AUTHOR]

Published

2024

44. Enhancement of ceramic tool behaviour with textured grooves during machining of Inconel® 718.

Author

Fernández-Lucio, P., Urbikain, G., Plaza, S., Ukar, E., and Pereira, O.

Subjects

*LASER engraving, *CUTTING force, *THERMAL conductivity, *THERMAL stability, *MACHINE performance, *CUTTING tools

Abstract

Inconel® 718, known for its excellent mechanical properties in extreme conditions, presents machining challenges due to its low machinability. The chip formation process, influenced by its high ductility and low thermal conductivity, leads to material adhesion and high cutting forces. Ceramic tools have been proposed to mitigate these inconveniences. Textured cutting tools have emerged as a promising solution, aiming to optimise tool-chip contact and, with it, the tribological conditions and the cutting forces. This study investigates the influence of textured grooves on ceramic tools when turning Inconel® 718. Two groove inclinations, 0° and − 25° relative to the cutting edge, were tested. Texturing was performed using a laser station. Experimental results showed improved tool wear characteristics with textured tools, indicating favourable chip extraction and reduced material adhesion. Cutting forces were notably lower with textured tools compared to the reference tool, attributed to reduced notch wear and altered chip flow. Chip morphology analysis revealed differences in chip shape and thermal stability between the reference and textured tools. In conclusion, textured tools, particularly those with − 25° inclined grooves, demonstrated enhanced performance in machining Inconel® 718. [ABSTRACT FROM AUTHOR]

Published

2024

45. An Economic, Compact Apparatus to Verify the Laws of Reflection and Refraction.

Author

Ramadan, Wael A. and El-Tawargy, Ahmed Salah

Subjects

*GEOMETRICAL optics, *OPTICAL elements, *LASER engraving, *OPTICAL glass, *LASER beam cutting

Abstract

This article presents a low-cost apparatus designed for teaching geometric optics experiments to first-year university students. The apparatus is made of medium-density fiberboard and uses glass optical elements to verify the laws of reflection and refraction. It allows for the direct observation of lateral displacement caused by a rectangular plate and the determination of the refractive index of the plate's material. Additionally, it enables investigation of refraction through a Littrow prism by determining its minimum deviation angle. The apparatus is economic, safe, and easy to use, making it suitable for educational purposes. The authors acknowledge the contributions of the Optics Research Group at Damietta University and Mohamed A. Atwa to the implementation of the apparatus. [Extracted from the article]

Published

2024

46. Design and Develop a Robot Arm to Automatically Feed Workpieces for Laser Engraving Machines.

Author

Phan Xuan Trung and Dang Anh Duy

Subjects

LASER engraving, PROGRAMMABLE controllers, INDUSTRIAL robots, STEPPING motors, LASER machining

Abstract

Copyright of FME Transactions is the property of University of Belgrade, Faculty of Mechanical Engineering and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

47. Módulo autobloqueante para el cambio automático de herramientas.

Author

Sánchez López, Carlos, Castillo Rojo, Andrea Yoselin, García Castañón, Alejandra Ibeth, Reyes Ramírez, Juan Gabriel, and Martínez Prieto, José de Jesús

Subjects

MANUFACTURING processes, LASER engraving, LOADING & unloading, THREE-dimensional printing, NUMERICAL control of machine tools

Abstract

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Published

2024

48. Forming Epoxy Coatings on Laser-Engraved Surface of Aluminum Alloy to Reinforce the Bonding Joint with a Carbon Fiber Composite.

Author

Zhu, Hongping, Zhang, Jinheng, Cheng, Fei, Li, Jiangzhou, Wu, Bo, and Zhao, Zhijie

Subjects

HYBRID materials, LASER engraving, LAMINATED materials, FIBROUS composites, METALLIC composites, EPOXY coatings, DEBONDING

Abstract

This study designed laser engraving and resin pre-coating (RPC) treatments on an aluminum alloy (AA) surface to construct through-the-thickness "epoxy pins" for improving the bonding strength with carbon fiber reinforced polymer (CFRP). A laser engraving treatment was used to create a pitted structure on the AA surface; higher wettability was acquired and greater vertical spaces were formed to impregnate epoxy resin, resulting in stronger mechanical interlocking. The RPC technique was further used to guide high-viscosity epoxy resin into pits to form the epoxy coatings and to minimize defects between the resin and the substrate. The bonding strength of the specimen treated with both laser engraving with a unit dimension of 0.3 mm and RPC increased up to 227.1% in comparison with that of the base. The failure modes of the hybrid composites changed from the debonding failure of the AA surface to the delamination-dominated failure of the laminated CFRP composites. It was confirmed that laser engraving is a feasible and effective method when combined with RPC for treating AAs to improve the bonding strength of AA-CFRP composites, which provides a reference for preparing high-performance hybrid composites with metals. [ABSTRACT FROM AUTHOR]

Published

2024

49. Dual-control of incubation effect for efficiently fabricating surface structures in fused silica.

Author

Wang, Zhi, Xiang, Zhikun, Li, Xiaowei, Wu, Mengnan, Yi, Peng, Zhang, Chao, Yan, Yihao, Li, Xibiao, Zhang, Xiangyu, Wang, Andong, and Huang, Lingling

Subjects

BESSEL beams, LASER engraving, FUSED silica, SURFACE structure, FEMTOSECOND lasers

Abstract

Fused silica with surface structures has potential applications in microfluidic, aerospace and other fields. To fabricate structures with high dimensional accuracy and surface quality is of paramount importance. However, it is indeed a challenge to strike a balance between accuracy and efficiency at the same time. Here, a temporally shaped femtosecond laser Bessel-beam-assisted etching method with dual-control of incubation effect is proposed to achieve this balance. Instead of layer-by-layer ablation continuously with Gaussian pulses, silica is modified discretely by double pulse Bessel beam with one single layer. During the modification process, incubation effect is dual-controlled in single shot process and spatial scanning process to generate even modified region efficiently. Then, the modified region is etched to form designed structures such as microholes, grooves, etc. The proposed method exhibits high efficiency for fabrication of surface structures in fused silica. [ABSTRACT FROM AUTHOR]

Published

2024

50. 380 Auto Pistol Shoot-out: Ruger Versus Smith & Wesson.

Author

Campbell, Bob

Subjects

MILITARY miniatures, HOLSTERS, LASER engraving, LEAF springs, TARGET acquisition, WRIST

Published

2025