Your search keyword '"Ozaita, M."' showing total 11 results

1. Investigations of the Laser Ablation Mechanism of PMMA Microchannels Using Single-Pass and Multi-Pass Laser Scans.

Author

Li, Xiao, Tang, Rujun, Li, Ding, Li, Fengping, Chen, Leiqing, Zhu, Dehua, Feng, Guang, Zhang, Kunpeng, and Han, Bing

Subjects

LASER machining, LASER ablation, LASER deposition, CHEMICAL decomposition, ENERGY density

Abstract

CO2 laser machining is a cost effective and time saving solution for fabricating microchannels on polymethylmethacrylate (PMMA). Due to the lack of research on the incubation effect and ablation behavior of PMMA under high-power laser irradiation, predictions of the microchannel profile are limited. In this study, the ablation process and mechanism of a continuous CO2 laser machining process on microchannel production in PMMA in single-pass and multi-pass laser scan modes are investigated. It is found that a higher laser energy density of a single pass causes a lower ablation threshold. The ablated surface can be divided into three regions: the ablation zone, the incubation zone, and the virgin zone. The PMMA ablation process is mainly attributed to the thermal decomposition reactions and the splashing of molten polymer. The depth, width, aspect ratio, volume ablation rate, and mass ablation rate of the channel increase as the laser scanning speed decreases and the number of laser scans increases. The differences in ablation results obtained under the same total laser energy density using different scan modes are attributed to the incubation effect, which is caused by the thermal deposition of laser energy in the polymer. Finally, an optimized simulation model that is used to solve the problem of a channel width greater than spot diameter is proposed. The error percentage between the experimental and simulation results varies from 0.44% to 5.9%. [ABSTRACT FROM AUTHOR]

Published

2024

2. 2D Microfluidic Devices for Pore-Scale Phenomena Investigation: A Review.

Author

Massimiani, Alice, Panini, Filippo, Marasso, Simone Luigi, Cocuzza, Matteo, Quaglio, Marzia, Pirri, Candido Fabrizio, Verga, Francesca, and Viberti, Dario

Subjects

MICROFLUIDICS, MICROFLUIDIC devices, POROUS materials, FLUID dynamics, MULTIPHASE flow, MANUFACTURING processes, FABRICATION (Manufacturing)

Abstract

Underground porous media are complex multiphase systems, where the behavior at the macro-scale is affected by physical phenomena occurring at the pore(micro)-scale. The understanding of pore-scale fluid flow, transport properties, and chemical reactions is fundamental to reducing the uncertainties associated with the dynamic behavior, volume capacity, and injection/withdrawal efficiency of reservoirs and groundwater systems. Lately, laboratory technologies were found to be growing along with new computational tools, for the analysis and characterization of porous media. In this context, a significant contribution is given by microfluidics, which provides synthetic tools, often referred to as micromodels or microfluidic devices, able to mimic porous media networks and offer direct visualization of fluid dynamics. This work aimed to provide a review of the design, materials, and fabrication techniques of 2D micromodels applied to the investigation of multiphase flow in underground porous media. The first part of the article describes the main aspects related to the geometrical characterization of the porous media that lead to the design of micromodels. Materials and fabrication processes to manufacture microfluidic devices are then described, and relevant applications in the field are presented. In conclusion, the strengths and limitations of this approach are discussed, and future perspectives are suggested. [ABSTRACT FROM AUTHOR]

Published

2023

3. Creep adjustment of strain gauges based on granular NiCr-carbon thin films.

Author

Mathis, Maximilian, Vollberg, Dennis, Langosch, Matthäus, Göttel, Dirk, Lellig, Angela, and Schultes, Günter

Subjects

THIN films, STRAINS & stresses (Mechanics), METALLIC films, CREEP (Materials), METALS, POLYMER films, STRAIN gages, STRAIN sensors

Abstract

An important property of high-precision mechanical sensors such as force transducers or torque sensors is the so-called creep error. It is defined as the signal deviation over time at a constant load. Since this signal deviation results in a reduced accuracy of the sensor, it is beneficial to minimize the creep error. Many of these sensors consist of a metallic spring element and strain gauges. In order to realize a sensor with a creep error of almost zero, it is necessary to compensate for the creep behavior of the metallic spring element. This can be achieved by creep adjustment of the used strain gauges. Unlike standard metal foil strain gauges with a gauge factor of 2, a type of strain gauges based on sputter-deposited NiCr -carbon thin films on polymer substrates offers the advantage of an improved gauge factor of about 10. However, for this type of strain gauge, creep adjustment by customary methods is not possible. In order to remedy this disadvantage, a thorough creep analysis is carried out. Five major influences on the creep error of force transducers equipped with NiCr -carbon thin-film strain gauges are examined, namely, the material creep of the metallic spring element (1), the creep (relaxation) of the polymer substrate (2), the composition of the thin film (3), the strain transfer to the thin film (4), and the kind of strain field on the surface of the transducer (5). Consequently, we present two applicable methods for creep adjustment of NiCr -carbon thin- film strain gauges. The first method addresses the intrinsic creep behavior of the thin film by a modification of the film composition. With increasing Cr content (at the expense of Ni, the intrinsic negative creep error can be shifted towards zero. The second method is not based on the thin film itself but rather on a modification of the strain transfer from the polyimide carrier to the thin film. This is achieved by controlled cutting of well-defined deep trenches into the polymer substrate via a picosecond laser. [ABSTRACT FROM AUTHOR]

Published

2021

4. Novel method to reduce the transverse sensitivity of granular thin film strain gauges by modification of strain transfer.

Author

Mathis, Maximilian, Vollberg, Dennis, Langosch, Matthäus, Göttel, Dirk, Lellig, Angela, and Schultes, Günter

Subjects

STRAIN gages, THIN films, METAL foils, GAGES, TRANSDUCERS

Abstract

Strain gauges based on polyimide carrier foils and piezoresistive granular thin films are highly sensitive to strain. Unlike conventional metal foil, granular film strain gauges also have a pronounced sensitivity to strain acting in the transverse direction. A novel method that allows for the modification of the strain transfer is proposed and proven experimentally. The method is based on the creation of stand-alone polyimide paths, on top of which the piezoresistive thin film is located. In this way, the granular film hardly receives any transverse strain; hence, the transverse sensitivity is drastically reduced. A picosecond laser system can be used for both patterning of the thin film and for controlled ablation of polyimide in order to generate well-defined high path structures. The working principle of the method is demonstrated by simulation, followed by an experimental verification using measurements of the transverse gauge factor. Furthermore, the output signal of force transducers may be increased using granular thin film strain gauges of reduced transverse sensitivity. [ABSTRACT FROM AUTHOR]

Published

2020

5. Ionic mechanisms maintaining action potential conduction velocity at high firing frequencies in an unmyelinated axon.

Author

Cross, Kevin P. and Robertson, R. Meldrum

Subjects

INTERNEURONS, AXONS, CADMIUM, PHYSIOLOGICAL effects of calcium, CATIONS

Abstract

The descending contralateral movement detector (DCMD) is a high-performance interneuron in locusts with an axon capable of transmitting action potentials (AP) at more than 500 Hz. We investigated biophysical mechanisms for fidelity of high-frequency transmission in this axon. We measured conduction velocities (CVs) at room temperature during exposure to 10 ammo/L cadmium, a calcium current antagonist, and found significant reduction in CV with reduction at frequencies >200 Hz of ~10%. Higher temperatures induced greater CV reductions during exposure to cadmium across all frequencies of ~20-30%. Intracellular recordings during 15 min of exposure to cadmium or nickel, also a calcium current antagonist, revealed an increase in the magnitude of the afterhyperpolarization potential (AHP) and the time to recover to baseline after the AHP (Medians for Control: -19.8%; Nickel: 167.2%; Cadmium: 387.2%), that could be due to a T-type calcium current. However, the removal of extracellular calcium did not mimic divalent cation exposure suggesting calcium currents are not the cause of the AHP increase. Computational modeling showed that the effects of the divalent cations could be modeled with a persistent sodium current which could be blocked by high concentrations of divalent cations. Persistent sodium current shortened the AHP duration in our models and increased CV for high-frequency APs. We suggest that faithful, high-frequency axonal conduction in the DCMD is enabled by a mechanism that shortens the AHP duration like a persistent or resurgent sodium current. [ABSTRACT FROM AUTHOR]

Published

2016

6. Effect of process parameters in nanosecond pulsed laser micromachining of PMMA-based microchannels at near-infrared and ultraviolet wavelengths.

Author

Teixidor, Daniel, Orozco, Francisco, Thepsonthi, Thanongsak, Ciurana, Joaquim, Rodríguez, Ciro, and Özel, Tuğrul

Subjects

PARAMETER estimation, PULSED lasers, MICROMACHINING, POLYMETHYLMETHACRYLATE, MICROCHANNEL flow, NEAR infrared radiation, ULTRAVIOLET radiation, WAVELENGTHS

Abstract

This paper presents investigations on the effects of nanosecond laser processing parameters on depth and width of microchannels fabricated from polymethylmethacrylate (PMMA) polymer. A neodymium-doped yttrium aluminium garnet pulsed laser with a fundamental wavelength of 1,064 nm and a third harmonic wavelength of 355 nm with pulse duration of 5 ns is utilized. Hence, experiments are conducted at near-infrared (NIR) and ultraviolet (UV) wavelengths. The laser processing parameters of pulse energy (402-415 mJ at NIR and 35-73 mJ at UV wavelengths), pulse frequency (8-11 Hz), focal spot size (140-190 μm at NIR and 75 μm at UV wavelengths) and scanning rate (400-800 pulse/mm at NIR and 101-263 pulse/mm at UV wavelengths) are varied to obtain a wide range of fluence and processing rate. Microchannel width and depth profile are measured, and main effects plots are obtained to identify the effects of process parameters on channel geometry (width and depth) and material removal rate. The relationship between process variables (width and depth of laser-ablated microchannels) and process parameters is investigated. It is observed that channel width (140-430 μm at NIR and 100-150 μm at UV wavelengths) and depth (30-120 μm at NIR and 35-75 μm at UV wavelengths) decreased linearly with increasing fluence and increased non-linearly with increasing scanning rate. It is also observed that laser processing at UV wavelength provided more consistent channel profiles at lower fluences due to higher laser absorption of PMMA at this wavelength. Mathematical modeling for predicting microchannel profile was developed and validated with experimental results obtained with pulsed laser micromachining at NIR and UV wavelengths. [ABSTRACT FROM AUTHOR]

Published

2013

7. Polymer microfabrication technologies for microfluidic systems.

Author

Becker, Holger and Gärtner, Claudia

Subjects

POLYMERS, MICROFLUIDICS, MICROFABRICATION, LITHOGRAPHY, LASER ablation

Abstract

Polymers have assumed the leading role as substrate materials for microfluidic devices in recent years. They offer a broad range of material parameters as well as material and surface chemical properties which enable microscopic design features that cannot be realised by any other class of materials. A similar range of fabrication technologies exist to generate microfluidic devices from these materials. This review will introduce the currently relevant microfabrication technologies such as replication methods like hot embossing, injection molding, microthermoforming and casting as well as photodefining methods like lithography and laser ablation for microfluidic systems and discuss academic and industrial considerations for their use. A section on back-end processing completes the overview. [ABSTRACT FROM AUTHOR]

Published

2008

8. Laser processing for bio-microfluidics applications (part II).

Author

Khan Malek, Chantal G.

Subjects

BIOCHIPS, INDUSTRIAL lasers, RAPID prototyping, SILICON, LASER ablation

Abstract

This paper reviews applications of laser-based techniques to the fabrication of microfluidic devices for biochips and addresses some of the challenges associated with the manufacture of these devices. Special emphasis is placed on the use of lasers for the rapid prototyping and production of biochips, in particular for applications in which silicon is not the preferred material base. This review addresses applications and devices based on ablation using femtosecond lasers, infrared lasers as well as laser-induced micro-joining, and the laser-assisted generation of micro-replication tools, for subsequent replication of polymeric chips with a technique like laser LIGA. [ABSTRACT FROM AUTHOR]

Published

2006

9. Differential Subcellular Localization of the Two Alternatively Spliced Isoforms of the Kv3.1 Potassium Channel Subunit in Brain.

Author

OZAITA, A., MARTONE, M. E., ELLISMAN, M. H., and RUDY, B.

Published

2002

10. Review of Microfluidic Devices and Imaging Techniques for Fluid Flow Study in Porous Geomaterials.

Author

Jahanbakhsh, Amir, Wlodarczyk, Krystian L., Hand, Duncan P., Maier, Robert R. J., and Maroto-Valer, M. Mercedes

Subjects

MICROFLUIDIC devices, FLUID flow, FLOW visualization, POROUS materials, CHEMICAL processes, MICROFLUIDICS, EARTH sciences

Abstract

Understanding transport phenomena and governing mechanisms of different physical and chemical processes in porous media has been a critical research area for decades. Correlating fluid flow behaviour at the micro-scale with macro-scale parameters, such as relative permeability and capillary pressure, is key to understanding the processes governing subsurface systems, and this in turn allows us to improve the accuracy of modelling and simulations of transport phenomena at a large scale. Over the last two decades, there have been significant developments in our understanding of pore-scale processes and modelling of complex underground systems. Microfluidic devices (micromodels) and imaging techniques, as facilitators to link experimental observations to simulation, have greatly contributed to these achievements. Although several reviews exist covering separately advances in one of these two areas, we present here a detailed review integrating recent advances and applications in both micromodels and imaging techniques. This includes a comprehensive analysis of critical aspects of fabrication techniques of micromodels, and the most recent advances such as embedding fibre optic sensors in micromodels for research applications. To complete the analysis of visualization techniques, we have thoroughly reviewed the most applicable imaging techniques in the area of geoscience and geo-energy. Moreover, the integration of microfluidic devices and imaging techniques was highlighted as appropriate. In this review, we focus particularly on four prominent yet very wide application areas, namely "fluid flow in porous media", "flow in heterogeneous rocks and fractures", "reactive transport, solute and colloid transport", and finally "porous media characterization". In summary, this review provides an in-depth analysis of micromodels and imaging techniques that can help to guide future research in the in-situ visualization of fluid flow in porous media. [ABSTRACT FROM AUTHOR]

Published

2020

11. Rapid Laser Manufacturing of Microfluidic Devices from Glass Substrates.

Author

Wlodarczyk, Krystian L., Carter, Richard M., Jahanbakhsh, Amir, Lopes, Amiel A., Mackenzie, Mark D., Maier, Robert R. J., Hand, Duncan P., and Maroto-Valer, M. Mercedes

Subjects

SUBSTRATES (Materials science), MICROSTRUCTURE

Abstract

Conventional manufacturing of microfluidic devices from glass substrates is a complex, multi-step process that involves different fabrication techniques and tools. Hence, it is time-consuming and expensive, in particular for the prototyping of microfluidic devices in low quantities. This article describes a laser-based process that enables the rapid manufacturing of enclosed micro-structures by laser micromachining and microwelding of two 1.1-mm-thick borosilicate glass plates. The fabrication process was carried out only with a picosecond laser (Trumpf TruMicro 5×50) that was used for: (a) the generation of microfluidic patterns on glass, (b) the drilling of inlet/outlet ports into the material, and (c) the bonding of two glass plates together in order to enclose the laser-generated microstructures. Using this manufacturing approach, a fully-functional microfluidic device can be fabricated in less than two hours. Initial fluid flow experiments proved that the laser-generated microstructures are completely sealed; thus, they show a potential use in many industrial and scientific areas. This includes geological and petroleum engineering research, where such microfluidic devices can be used to investigate single-phase and multi-phase flow of various fluids (such as brine, oil, and CO2) in porous media. [ABSTRACT FROM AUTHOR]

Published

2018