Bibliographies thématiques / Ultrafast laser ablation

Littérature scientifique sur le sujet « Ultrafast laser ablation »

Auteur : Grafiati
Publié le 25 mai 2024

Créez une référence correcte selon les styles APA, MLA, Chicago, Harvard et plusieurs autres

Choisissez une source :

Sommaire

Consultez les listes thématiques d’articles de revues, de livres, de thèses, de rapports de conférences et d’autres sources académiques sur le sujet « Ultrafast laser ablation ».

À côté de chaque source dans la liste de références il y a un bouton « Ajouter à la bibliographie ». Cliquez sur ce bouton, et nous générerons automatiquement la référence bibliographique pour la source choisie selon votre style de citation préféré : APA, MLA, Harvard, Vancouver, Chicago, etc.

Vous pouvez aussi télécharger le texte intégral de la publication scolaire au format pdf et consulter son résumé en ligne lorsque ces informations sont inclues dans les métadonnées.

Articles de revues sur le sujet "Ultrafast laser ablation"

1

Rethfeld, Baerbel, Dmitriy S. Ivanov, Martin E. Garcia et Sergei I. Anisimov. « Modelling ultrafast laser ablation ». Journal of Physics D : Applied Physics 50, no 19 (10 avril 2017) : 193001. http://dx.doi.org/10.1088/1361-6463/50/19/193001.

Texte intégral
Styles APA, Harvard, Vancouver, ISO, etc.
2

Xiaochang Ni, Xiaochang Ni, Anoop K. K. Anoop K.K., Mario Bianco Mario Bianco, Salvatore Amoruso Salvatore Amoruso, Xuan Wang Xuan Wang, Tong Li Tong Li, Minglie Hu Minglie Hu et Zhenming Song Zhenming Song. « Ion dynamics in ultrafast laser ablation of copper target ». Chinese Optics Letters 11, no 9 (2013) : 093201–93205. http://dx.doi.org/10.3788/col201311.093201.

Texte intégral
Styles APA, Harvard, Vancouver, ISO, etc.
3

Ionin, Andrey A., Sergey I. Kudryashov, Sergey V. Makarov, N. N. Mel’nik, Pavel N. Saltuganov, Leonid V. Seleznev et Dmitry V. Sinitsyn. « Ultrafast femtosecond laser ablation of graphite ». Laser Physics Letters 12, no 7 (1 juin 2015) : 075301. http://dx.doi.org/10.1088/1612-2011/12/7/075301.

Texte intégral
Styles APA, Harvard, Vancouver, ISO, etc.
4

Reis, D. A., K. J. Gaffney, G. H. Gilmer et B. Torralva. « Ultrafast Dynamics of Laser-Excited Solids ». MRS Bulletin 31, no 8 (août 2006) : 601–6. http://dx.doi.org/10.1557/mrs2006.156.

Texte intégral
Résumé :
AbstractWe discuss recent experimental and theoretical results on ultrafast materials dynamics. Intense, femtosecond lasers can deposit energy in a time that is short compared with relaxation processes and can generate extremely large carrier densities that drive bond softening, nonthermal melting, and ablation. In particular, we present optical experiments on electronic softening of coherent phonons in bismuth and x-ray experiments on ultrafast disordering in indium antimonide that probe the bonding of the lattice under successively higher carrier concentrations. We review a number of molecular dynamics simulations and their assumptions, which address nonthermal melting. Large-scale molecular dynamics simulations elucidate the role of void formation in laser ablation.
Styles APA, Harvard, Vancouver, ISO, etc.
5

Yin, C. P., S. T. Zhang, Y. W. Dong, Q. W. Ye et Q. Li. « Molecular-dynamics study of multi-pulsed ultrafast laser interaction with copper ». Advances in Production Engineering & ; Management 16, no 4 (18 décembre 2021) : 457–72. http://dx.doi.org/10.14743/apem2021.4.413.

Texte intégral
Résumé :
Ultrafast laser has an undeniable advantage in laser processing due to its extremely small pulse width and high peak energy. While the interaction of ultrafast laser and solid materials is an extremely non-equilibrium process in which the material undergoes phase transformation and even ablation in an extremely short time range. This is the coupling of the thermos elastic effect caused by the pressure wave and the superheated melting of the material lattice. To further explore the mechanism of the action of ultrafast laser and metal materials, the two-temperature model coupling with molecular dynamics method was used to simulate the interaction of the copper and laser energy. Firstly, the interaction of single-pulsed laser and copper film was reproduced, and the calculated two-temperature curve and the visualized atomic snapshots were used to investigate the influence of laser parameters on the ablation result. Then, by changing the size of the atomic system, the curve of ablation depth as a function of laser fluence was obtained. In this paper, the interaction of multi-pulsed laser and copper was calculated. Two-temperature curve and temperature contour of copper film after the irradiation of double-pulsed and multi-pulsed laser were obtained. And the factors which can make a difference to the incubation effect were analyzed. By calculating the ablation depth under the action of multi-pulsed laser, the influence of the incubation effect on ablation results was further explored. Finally, a more accurate numerical model of laser machining metal is established and verified by an ultra-short laser processing experiment, which provides a new calculation method and theoretical basis for ultra-fast laser machining of air film holes in aviation turbine blades, and has certain practical guiding significance for laser machining.
Styles APA, Harvard, Vancouver, ISO, etc.
6

Ryabchikov, Yury V., Inam Mirza, Miroslava Flimelová, Antonin Kana et Oleksandr Romanyuk. « Merging of Bi-Modality of Ultrafast Laser Processing : Heating of Si/Au Nanocomposite Solutions with Controlled Chemical Content ». Nanomaterials 14, no 4 (6 février 2024) : 321. http://dx.doi.org/10.3390/nano14040321.

Texte intégral
Résumé :
Ultrafast laser processing possesses unique outlooks for the synthesis of novel nanoarchitectures and their further applications in the field of life science. It allows not only the formation of multi-element nanostructures with tuneable performance but also provides various non-invasive laser-stimulated modalities. In this work, we employed ultrafast laser processing for the manufacturing of silicon–gold nanocomposites (Si/Au NCs) with the Au mass fraction variable from 15% (0.5 min ablation time) to 79% (10 min) which increased their plasmonic efficiency by six times and narrowed the bandgap from 1.55 eV to 1.23 eV. These nanostructures demonstrated a considerable fs laser-stimulated hyperthermia with a Au-dependent heating efficiency (~10–20 °C). The prepared surfactant-free colloidal solutions showed good chemical stability with a decrease (i) of zeta (ξ) potential (from −46 mV to −30 mV) and (ii) of the hydrodynamic size of the nanoparticles (from 104 nm to 52 nm) due to the increase in the laser ablation time from 0.5 min to 10 min. The electrical conductivity of NCs revealed a minimum value (~1.53 µS/cm) at 2 min ablation time while their increasing concentration was saturated (~1012 NPs/mL) at 7 min ablation duration. The formed NCs demonstrated a polycrystalline Au nature regardless of the laser ablation time accompanied with the coexistence of oxidized Au and oxidized Si as well as gold silicide phases at a shorter laser ablation time (<1 min) and the formation of a pristine Au at a longer irradiation. Our findings demonstrate the merged employment of ultrafast laser processing for the design of multi-element NCs with tuneable properties reveal efficient composition-sensitive photo-thermal therapy modality.
Styles APA, Harvard, Vancouver, ISO, etc.
7

Li, Celina L., Carl J. Fisher, Ray Burke et Stefan Andersson-Engels. « Orthopedics-Related Applications of Ultrafast Laser and Its Recent Advances ». Applied Sciences 12, no 8 (14 avril 2022) : 3957. http://dx.doi.org/10.3390/app12083957.

Texte intégral
Résumé :
The potential of ultrafast lasers (pico- to femtosecond) in orthopedics-related procedures has been studied extensively for clinical adoption. As compared to conventional laser systems with continuous wave or longer wave pulse, ultrafast lasers provide advantages such as higher precision and minimal collateral thermal damages. Translation to surgical applications in the clinic has been restrained by limitations of material removal rate and pulse average power, whereas the use in surface texturing of implants has become more refined to greatly improve bioactivation and osteointegration within bone matrices. With recent advances, we review the advantages and limitations of ultrafast lasers, specifically in orthopedic bone ablation as well as bone implant laser texturing, and consider the difficulties encountered within orthopedic surgical applications where ultrafast lasers could provide a benefit. We conclude by proposing our perspectives on applications where ultrafast lasers could be of advantage, specifically due to the non-thermal nature of ablation and control of cutting.
Styles APA, Harvard, Vancouver, ISO, etc.
8

Lu, Mingyu, Ming Zhang, Kaihu Zhang, Qinggeng Meng et Xueqiang Zhang. « Femtosecond UV Laser Ablation Characteristics of Polymers Used as the Matrix of Astronautic Composite Material ». Materials 15, no 19 (29 septembre 2022) : 6771. http://dx.doi.org/10.3390/ma15196771.

Texte intégral
Résumé :
Ultrafast laser processing has recently emerged as a new tool for processing fiber-reinforced polymer (FRP) composites. In the astronautic industry, the modified epoxy resin (named 4211) and the modified cyanate ester resin (known as BS-4) are two of the most widely used polymers for polymer-based composites. To study the removal mechanism and ablation process of different material components during the ultrafast laser processing of FRPs, we isolated the role of the two important polymers from their composites by studying their femtosecond UV laser (260 fs, 343 nm) ablation characteristics for controllable machining and understanding the related mechanisms. Intrinsic properties for the materials’ transmission spectrum, the absorption coefficient and the optical bandgap (Eg), were measured, derived, and compared. Key parameters for controllable laser processing, including the ablation threshold (Fth), energy penetration depth (δeff), and absorbed energy density (Eabs) at the ablation threshold, as well as their respective “incubation” effect under multiple pulse excitations, were deduced analytically. The ablation thresholds for the two resins, derived from both the diameter-regression and depth-regression techniques, were compared between resins and between techniques. An optical bandgap of 3.1 eV and 2.8 eV for the 4211 and BS-4 resins, respectively, were obtained. A detectable but insignificant-to-ablation difference in intrinsic properties and ablation characteristics between the two resins was found. A systematic discrepancy, by a factor of 30%~50%, between the two techniques for deriving ablation thresholds was shown and discussed. For the 4211 resin ablated by a single UV laser pulse, a Fth of 0.42 J/cm2, a δeff of 219 nm, and an Eabs of 18.4 kJ/cm3was suggested, and they are 0.45 J/cm2, 183 nm, and 23.2 kJ/cm3, respectively, for the BS-4 resin. The study may shed light on the materials’ UV laser processing, further the theoretical modeling of ultrafast laser ablation, and provide a reference for the femtosecond UV laser processing characteristics of FRPs for the future.
Styles APA, Harvard, Vancouver, ISO, etc.
9

Pallarés-Aldeiturriaga, David, Alain Abou Khalil, Jean-Philippe Colombier, Razvan Stoian et Xxx Sedao. « Ultrafast Cylindrical Vector Beams for Improved Energy Feedthrough and Low Roughness Surface Ablation of Metals ». Materials 16, no 1 (25 décembre 2022) : 176. http://dx.doi.org/10.3390/ma16010176.

Texte intégral
Résumé :
The use of ultrafast cylindrical vector vortex beams in laser–matter interactions permits new ablation features to be harnessed from inhomogeneous distributions of polarization and beam geometry. As a consequence, the ablation process can yield higher ablation efficiency compared with conventional Gaussian beams. These beams prevent surface quality degradation during the ablative processes. When processing stainless steel and titanium, the average surface roughness obtained by deploying the cylindrical vector is up to 94% lower than the Gaussian case, and the processing efficiency is 80% higher.
Styles APA, Harvard, Vancouver, ISO, etc.
10

Hernandez-Rueda, Javier, Anne de Beurs et Dries van Oosten. « Ultrafast laser ablation of trapped gold nanoparticles ». Optics Letters 44, no 13 (25 juin 2019) : 3294. http://dx.doi.org/10.1364/ol.44.003294.

Texte intégral
Styles APA, Harvard, Vancouver, ISO, etc.
Plus de sources

Thèses sur le sujet "Ultrafast laser ablation"

1

Stoian, Razvan. « Adaptive techniques for ultrafast laser material processing ». Habilitation à diriger des recherches, Université Jean Monnet - Saint-Etienne, 2008. http://tel.archives-ouvertes.fr/tel-00352662.

Texte intégral
Résumé :
Le besoin d'une très grande précision lors du traitement des matériaux par laser a fortement encouragé le développement des études de l'effet des impulsions ultra brèves pour la structuration des matériaux à une échelle micro et nano métrique. Une diffusion d'énergie minimale et une forte non linéarité de l'interaction permet un important confinement énergétique à des échelles les plus petites possibles. La possibilité d'introduire des changements de phases rapides et même de créer de nouveaux états de matière ayant des propriétés optimisées et des fonctions améliorées donne aux impulsions ultra brèves de sérieux arguments pour être utilisées dans des dispositifs très précis de transformation et de structuration des matériaux. L'étude de ces mécanismes de structuration et, en particulier, de leurs caractéristiques dynamiques, est une clé pour l'optimisation de l'interaction laser-matière suivant de nombreux critères utiles pour les procédés laser : efficacité, précision, qualité. Ce mémoire synthétise les travaux de l'auteur sur l'étude statique et dynamique du dépôt d'énergie ultra rapide, avec application aux procédés laser. La connaissance de la réponse dynamique des matériaux après irradiation laser ultra brève montre que les temps de relaxation pilotent l'interaction lumière-matière. Il est alors possible d'adapter l'énergie déposée à la réponse du matériau en utilisant les toutes récentes techniques de mise en forme spatio temporelle de faisceaux. Un couplage optimal de l'énergie donne la possibilité d'orienter la réponse du matériau vers un résultat recherché, offrant une grande flexibilité de contrôle des procédés et, sans doute, la première étape du développement de procédés « intelligents ».
Styles APA, Harvard, Vancouver, ISO, etc.
2

Mingareev, Ilja. « Ultrafast dynamics of melting and ablation at large laser intensities ». Göttingen Cuvillier, 2009. http://d-nb.info/992684498/04.

Texte intégral
Styles APA, Harvard, Vancouver, ISO, etc.
3

Werner, Kevin Thomas. « Ultrafast Mid-Infrared Laser-Solid Interactions ». The Ohio State University, 2019. http://rave.ohiolink.edu/etdc/view?acc_num=osu1546542784608798.

Texte intégral
Styles APA, Harvard, Vancouver, ISO, etc.
4

Huchon, Christophe Xavier. « Time of flight spectrometry studies of graphite surface : ultrafast laser ablation and photoelectron spectroscopy ». Thesis, University of Birmingham, 2008. http://etheses.bham.ac.uk/372/.

Texte intégral
Résumé :
This work reports an investigation of the interaction of ultrashort laser pulses with a graphite surface. Time-of-flight experiments were conducted with a 100 fs laser system, then 13 fs laser pulses at 800 nm wavelength were used for photoelectron spectroscopy studies. Multi-shots and single-shot laser pulse regimes have shown the existence of two mechanisms involved in the ablation of graphite: at low laser fluence, a non-thermal physical process known as Coulomb explosion (CE) is responsible for the ultrafast removal of particles. At high laser fluence, a thermal process, called plasma generation and characterized by a liquid-carbon phase initiated by the laser pulse, takes place and is believed to be at the origin of the ejection of particles. On the other hand, results from 13 fs laser pulses give rise to unusual high kinetic energy photoelectron around 20 eV that cannot be explained by the multiphoton ionization process but by tunnel and/or above barrier ionization (ABI). This unexpected result at such low intensities (10¹⁰ < I(W/cm²) <10¹²) is interpreted as a roughening of the surface by the laser pulse that leads to photon-plasmon coupling, then an enhancement of the local electric surface field enough to make possible electrons tunneling through the potential barrier or even to escape directly (ABI) into the vacuum.
Styles APA, Harvard, Vancouver, ISO, etc.
5

Talisa, Noah Brodzik. « Laser-Induced Damage and Ablation of Dielectrics with Few-Cycle Laser Pulses ». The Ohio State University, 2020. http://rave.ohiolink.edu/etdc/view?acc_num=osu1609243476481238.

Texte intégral
Styles APA, Harvard, Vancouver, ISO, etc.
6

Abtahi, Seyed Ali. « Ultrafast Laser Sampling of a Plant Tissue and ion Conductivity Measurement for Investigation of Light Stress Generation Mechanisms ». Thesis, University of North Texas, 2010. https://digital.library.unt.edu/ark:/67531/metadc31522/.

Texte intégral
Résumé :
In this study we applied ultra-short laser pulses on a biological sample (Arabidopsis), in order to cut it precisely in a square pattern and subsequently use it for studying stress generation mechanisms. For this purpose, we utilized femtosecond laser pulses at 100 fs pulse width and 80 MHz repetition rate. We took two processing parameters into consideration such as laser power, laser exposure time which is related to the stage speed. Therefore, we were able to find the laser optimum conditions for ablation of biological tissues. The mutant and wildtype (control) obtained from laser cutting with a size of 500 µm × 500 µm were directly transferred (in-situ with laser cutting) into a microfabricated chamber containing ~500 nanoliters deionized water for measuring ion conductivity. The ion conductivity is a signature of cell-death mechanisms caused by various stresses. A light with intensity of 100 µmol was exposed to the samples for 2 hours and 20 minutes as a source of stress. A quantitative electrical analysis with high accuracy was assured by utilizing a microchamber, which enables a measurement in nanoliter volume. We measured the impedance which is reciprocal of conductivity using a lock-in amplifier and a precise current source at frequency of 130 Hz. Initially high impedance of mutant sample tended to drop within 2 hours and finally approached the constant value which signified that the cell death mechanism was complete. However, the wildtype sample demonstrated approximately constant impedance (conductivity) during the experiment.
Styles APA, Harvard, Vancouver, ISO, etc.
7

Maier, Stephanie [Verfasser], et R. J. Dwayne [Akademischer Betreuer] Miller. « Studies of Laser Ablation, Biodiagnostics, and new Laser Surgery Applications under Conditions of Ultrafast Desorption by Impulsive Vibrational Excitation (DIVE) / Stephanie Maier ; Betreuer : R. J. Dwayne Miller ». Hamburg : Staats- und Universitätsbibliothek Hamburg, 2018. http://d-nb.info/1166851141/34.

Texte intégral
Styles APA, Harvard, Vancouver, ISO, etc.
8

Chen, Yin-hao, et 陳胤豪. « The Study of ITO Ablation with Ultrafast Laser ». Thesis, 2009. http://ndltd.ncl.edu.tw/handle/32911170185009692936.

Texte intégral
Résumé :
碩士
義守大學
機械與自動化工程學系碩士班
97
Indium tin oxide (ITO) is a material with high transparency and electric conductivity. Thin film ITO coatings are commonly used in flat panel displays, touch panels and other electronic devices as electrodes. The traditional patterning technique has used photolithography followed by wet etching process to ablate ITO on substrates. However, this technique involves complex multi-step processes and may induce chemical pollution. In this research, the laser direct-write patterning method is applied to the micromachining of ITO thin films on plastic substrates. Owing to the adiabatic heating characteristics of ultrafast laser, it is possible to complete the patterning process without damaging the substrates. The purpose of this study is to ideutify the proper processing parameters, namely the focal length, laser repetition rate and laser power, of a ultrafast laser machine, for the purpose of clean selective removal of the ITO films. The outcomes sre assessed by measuring the line width after processing using OM, observing the surface guality of ITO films and trench bottom using VMC, and calculating the laser energy density. The range of laser energy density that allowing clean ITO removal and good surface guality is obtained. In the experiments, the minimum lin width of 3.6μm with good surface guality and clean removal of ITO films is achieved by using the following processing parameters: platform moving speed 30mm/s, focal length -1.9mm, repetition rate 70kHz, and power 0.07W. This research shows when the laser energy density is in the range of 0.141~0.247J/cm2, the 120nm thick ITO film is completely removed without damaging the substrate.
Styles APA, Harvard, Vancouver, ISO, etc.
9

Mingareev, Ilja [Verfasser]. « Ultrafast dynamics of melting and ablation at large laser intensities / vorgelegt von Ilja Mingareev ». 2009. http://d-nb.info/993404146/34.

Texte intégral
Styles APA, Harvard, Vancouver, ISO, etc.

Chapitres de livres sur le sujet "Ultrafast laser ablation"

1

Neu, W., R. Nyga, C. Tischler et K. E. Karsch. « Ultrafast Imaging of Atherosclerotic Tissue Ablation ». Dans Laser in der Medizin / Laser in Medicine, 232–35. Berlin, Heidelberg : Springer Berlin Heidelberg, 1992. http://dx.doi.org/10.1007/978-3-642-50234-7_59.

Texte intégral
Styles APA, Harvard, Vancouver, ISO, etc.
2

Rácz, B., Zs Bor, B. Hopp, G. Szabó, I. Süveges, J. Mohay, I. Ratkay et A. Füst. « Ultrafast Photography of the Cornea Ablation ». Dans Laser in der Medizin / Laser in Medicine, 412–14. Berlin, Heidelberg : Springer Berlin Heidelberg, 1994. http://dx.doi.org/10.1007/978-3-642-93548-0_93.

Texte intégral
Styles APA, Harvard, Vancouver, ISO, etc.
3

Sokolowski-Tinten, K., S. Kudryashov, V. Temnov, J. Bialkowski, D. von der Linde, A. Cavalleri, H. O. Jeschke, M. E. Garcia et K. H. Bennemann. « Femtosecond laser-induced ablation of graphite ». Dans Ultrafast Phenomena XII, 425–27. Berlin, Heidelberg : Springer Berlin Heidelberg, 2001. http://dx.doi.org/10.1007/978-3-642-56546-5_124.

Texte intégral
Styles APA, Harvard, Vancouver, ISO, etc.
4

Gamaly, Eugene G., Andrei V. Rode et Barry Luther-Davies. « Ultrafast Laser Ablation and Film Deposition ». Dans Pulsed Laser Deposition of Thin Films, 99–129. Hoboken, NJ, USA : John Wiley & Sons, Inc., 2006. http://dx.doi.org/10.1002/9780470052129.ch5.

Texte intégral
Styles APA, Harvard, Vancouver, ISO, etc.
5

Lausten, Rune, Jakob A. Olesen, Kasper Vestentoft et Peter Balling. « Ultrashort-pulse-laser ablation of metals : Significant changes in ablation rates with depth ». Dans Ultrafast Phenomena XIII, 675–77. Berlin, Heidelberg : Springer Berlin Heidelberg, 2003. http://dx.doi.org/10.1007/978-3-642-59319-2_208.

Texte intégral
Styles APA, Harvard, Vancouver, ISO, etc.
6

Glover, T. E., G. D. Ackermann, A. Belkacem, P. A. Heimann, Z. Hussain, H. A. Padmore, C. Ray, R. W. Schoenlein et W. F. Steele. « Kinetics of Cluster Formation During Femtosecond Laser Ablation ». Dans Ultrafast Phenomena XIII, 42–44. Berlin, Heidelberg : Springer Berlin Heidelberg, 2003. http://dx.doi.org/10.1007/978-3-642-59319-2_12.

Texte intégral
Styles APA, Harvard, Vancouver, ISO, etc.
7

Uhlig, Sebastian. « Introduction to Laser-Ablation &-Surface Structuring ». Dans Self-Organized Surface Structures with Ultrafast White-Light, 4–11. Wiesbaden : Springer Fachmedien Wiesbaden, 2015. http://dx.doi.org/10.1007/978-3-658-09894-0_1.

Texte intégral
Styles APA, Harvard, Vancouver, ISO, etc.
8

Rao, S. Venugopal, S. Hamad et G. Krishna Podagatlapalli. « Applications of Metal Nanoparticles and Nanostructures Fabricated Using Ultrafast Laser Ablation in Liquids ». Dans Semiconductor Nanocrystals and Metal Nanoparticles, 367–421. Taylor & Francis Group, 6000 Broken Sound Parkway NW, Suite 300, Boca Raton, FL 33487-2742 : CRC Press, 2016. http://dx.doi.org/10.1201/9781315374628-12.

Texte intégral
Styles APA, Harvard, Vancouver, ISO, etc.
9

Oguri, Katsuya, Yasuaki Okano, Tadashi Nishikawa et Hidetoshi Nakano. « Observation of Ultrafast Bond-length Expansion at the Initial Stage of Laser Ablation by Picosecond Time-resolved EXAFS ». Dans Springer Series in Optical Sciences, 173–80. New York, NY : Springer New York, 2007. http://dx.doi.org/10.1007/978-0-387-49119-6_22.

Texte intégral
Styles APA, Harvard, Vancouver, ISO, etc.
10

Sima, Felix, Jian Xu et Koji Sugioka. « Ultrafast Laser-Induced Phenomena inside Transparent Materials ». Dans Pulsed Laser Ablation, 357–98. Pan Stanford, 2018. http://dx.doi.org/10.1201/9781315185231-10.

Texte intégral
Styles APA, Harvard, Vancouver, ISO, etc.

Actes de conférences sur le sujet "Ultrafast laser ablation"

1

B, J. Camilo Diaz, Dmitry Ivanov et Gabriel M. Bilmes. « Laser Ablation thresholds of thin Aluminium films ». Dans Ultrafast Optics. Washington, D.C. : Optica Publishing Group, 2023. http://dx.doi.org/10.1364/ufo.2023.p2.17.

Texte intégral
Résumé :
We present an experimental and theoretical study of nanosecond and femtosecond laser ablation process of thin Al films. By using Laser Ablation Induced Photoacoustics (LAIP) we identify experimentally the laser ablation thresholds. Results were compared with computational simulations based in the Two Temperature Model and Molecular Dynamics (TTM-MD).
Styles APA, Harvard, Vancouver, ISO, etc.
2

Moore, David S., Cynthia A. Bolme, Shawn D. McGrane et David J. Funk II. « Single pulse ultrafast dynamic ellipsometry ». Dans High-Power Laser Ablation 2006, sous la direction de Claude R. Phipps. SPIE, 2006. http://dx.doi.org/10.1117/12.674782.

Texte intégral
Styles APA, Harvard, Vancouver, ISO, etc.
3

Moloney, J. V., et M. Kolesik. « Nonlinear ultrafast femtosecond X-waves ». Dans High-Power Laser Ablation 2008, sous la direction de Claude R. Phipps. SPIE, 2008. http://dx.doi.org/10.1117/12.783463.

Texte intégral
Styles APA, Harvard, Vancouver, ISO, etc.
4

Bolme, C. A., S. D. McGrane, D. S. Moore et D. J. Funk. « Ultrafast dynamic ellipsometry of laser ablated silicon ». Dans High-Power Laser Ablation 2008, sous la direction de Claude R. Phipps. SPIE, 2008. http://dx.doi.org/10.1117/12.782739.

Texte intégral
Styles APA, Harvard, Vancouver, ISO, etc.
5

Agranat, Michail B., Sergei I. Anisimov, Sergei I. Ashitkov, Vladimir E. Fortov, Alexander V. Kirillin, Petr S. Kondratenko et Alexander V. Kostanovskii. « Laser-induced ultrafast phase transitions in solids using optical anisotropy ». Dans High-Power Laser Ablation, sous la direction de Claude R. Phipps. SPIE, 1998. http://dx.doi.org/10.1117/12.321516.

Texte intégral
Styles APA, Harvard, Vancouver, ISO, etc.
6

Tolbert, William A., I. Y. Sandy Lee, David E. Hare, Xiaoning Wen et Dana D. Dlott. « Ultrafast dynamics of photothermal polymer ablation ». Dans Laser ablation : mechanisms and applications—II. AIP, 1993. http://dx.doi.org/10.1063/1.44920.

Texte intégral
Styles APA, Harvard, Vancouver, ISO, etc.
7

Gamaly, Eugene G., et Andrei V. Rode. « Ultrafast ablation with high-pulse-repetition-rate lasers : I. Theoretical considerations ». Dans High-Power Laser Ablation, sous la direction de Claude R. Phipps. SPIE, 1998. http://dx.doi.org/10.1117/12.321554.

Texte intégral
Styles APA, Harvard, Vancouver, ISO, etc.
8

Clarke, Steven A., George Rodriguez, Antoinette J. Taylor et Andrew Forsman. « Interferometric diagnostic suite for ultrafast laser ablation of metals ». Dans High-Power Laser Ablation 2004, sous la direction de Claude R. Phipps. SPIE, 2004. http://dx.doi.org/10.1117/12.547192.

Texte intégral
Styles APA, Harvard, Vancouver, ISO, etc.
9

Stoian, Razvan, Alexandre Mermillod-Blondin, Arkadi Rosenfeld, Ingolf V. Hertel, Maria Spyridaki, Emmanuel Koudoumas, Costas Fotakis, Igor M. Burakov et Nadezhda M. Bulgakova. « Adaptive optimization in ultrafast laser material processing (Plenary Paper) ». Dans High-Power Laser Ablation 2004, sous la direction de Claude R. Phipps. SPIE, 2004. http://dx.doi.org/10.1117/12.547267.

Texte intégral
Styles APA, Harvard, Vancouver, ISO, etc.
10

Maigler, Maximilian, Tobias Held, Dirk O. Gericke, Jochen Schein, Baerbel Rethfeld, S. H. Glenzer et M. Z. Mo. « Atomistic modelling of ultrafast laser-induced melting in copper ». Dans High-Power Laser Ablation VIII, sous la direction de Claude R. Phipps et Vitaly E. Gruzdev. SPIE, 2024. http://dx.doi.org/10.1117/12.3012630.

Texte intégral
Styles APA, Harvard, Vancouver, ISO, etc.
Vous pouvez également être intéressé par les bibliographies sur le sujet « Ultrafast laser ablation » pour d’autres types de sources :
Articles de revues
Nous offrons des réductions sur tous les plans premium pour les auteurs dont les œuvres sont incluses dans des sélections littéraires thématiques. Contactez-nous pour obtenir un code promo unique!

Vers la bibliographie