Ultrashort pulsed laser technology for new detectors

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Presentation transcript:

Ultrashort pulsed laser technology for new detectors 6th RD51 Collaboration Meeting 7-10 October 2010 Bari, Italy Ultrashort pulsed laser technology for new detectors Antonio Ancona U.O.S. Bari, Italy Dip. Interuniversitario di Fisica “M. Merlin”

Outline Laser ablation: a short introduction Laser drilling techniques Critical aspects of GEM fabrication via laser ablation Laser Materials Processing lab @ CNR-IFN Bari Preliminary results Outlook Antonio Ancona - 9 October 2010 Bari – 6° RD51 Collaboration Meeting

Laser Ablation Definition Laser ablation is the process of removing material from a solid surface by irradiating it with a laser beam. At low laser flux, the material is heated by the absorbed laser energy and evaporates or sublimates. At high laser flux, the material is typically converted to a plasma. Usually, laser ablation refers to removing material with a pulsed laser Antonio Ancona - 9 October 2010 Bari – 6° RD51 Collaboration Meeting

Timescales of the laser ablation process fs ps ns µs energy absorption by free electons electron - lattice energy transfer ablation by phase explosion or evaporation Thermal diffusion Melting and resolidification Mazur et al. Nature Materials 2, 217 (2002) Antonio Ancona - 9 October 2010 Bari – 6° RD51 Collaboration Meeting

Precision Vs. Pulse duration F. Dausinger, Proc. FTK, 289-308 Stuttgart 2003 Antonio Ancona - 9 October 2010 Bari – 6° RD51 Collaboration Meeting

Laser ablation with long pulses Antonio Ancona - 9 October 2010 Bari – 6° RD51 Collaboration Meeting

Laser ablation with short pulses Antonio Ancona - 9 October 2010 Bari – 6° RD51 Collaboration Meeting

Micromachining of metals “long” pulses (3.3 ns) melting and creation of burr heat diffusion non reproducible process Ultrashort pulses (200 fs) practically burr- and melting-free ablation low ablation threshold negligible heat diffusion minimized heat affected zones high process efficiency stable ablation process high reproducibility C. Momma et al. Opt. Comm. 129 (1996) Antonio Ancona - 9 October 2010 Bari – 6° RD51 Collaboration Meeting

Laser drilling strategies for high accuracy Trepanning optic for helical drilling F. Dausinger et al., Springer (2004) Antonio Ancona - 9 October 2010 Bari – 6° RD51 Collaboration Meeting

GEM fabrication 5 μm Copper 50 μm Kapton Antonio Ancona - 9 October 2010 Bari – 6° RD51 Collaboration Meeting

Thermal Conductivity (W m-1 K-1) Vaporization temperature (°C) Critical asprcts of GEM fabrication via laser ablation Kapton and Cu are materials with completely different thermal and physical properties Material Density (g cm-3) Thermal Conductivity (W m-1 K-1) Melting point (°C) Vaporization temperature (°C) Copper Metal 8.94 400 1084 2562 Kapton Polymer 1.42 0.12 none ~ 600 Finding optimal laser process parameters (pulse duration, wavelength, fluence, drilling strategy) Copper particle redeposition inside the hole walls (post process etching could be required) Advantages Flexible technology: complete control of the hole morphology (taper, diameter) and geometry (density of the holes mm-2, distribution) Antonio Ancona - 9 October 2010 Bari – 6° RD51 Collaboration Meeting

Microchip laser fiber amplifier (100 ps) Quasi-monolithic Q-switched microchip laser mm Pump diode 0.55 m PM-DC 1.5 m PM-PCF 18 Watt 5 Watt Yb-doped photonic crystal fiber Antonio Ancona - 9 October 2010 Bari – 6° RD51 Collaboration Meeting

CNR-IFN Bari - Laser materials processing lab Short pulse 100 ps fiber laser Specifications Wavelength 1064 nm Pulse duration 100 ps Repetition rate ≈ 100 kHz Pulse energy max. 100 μJ Average power 10 W Peak power max. 1 MW Collaboration CNR-IFN Bari FSU JENA Antonio Ancona - 9 October 2010 Bari – 6° RD51 Collaboration Meeting

Expected delivery: February 2011 CNR-IFN Bari - Laser materials processing lab Ultrafast high power fiber CPA lasersystem Wavelength: 1030 nm Repetition rate: < 50 kHz … >10 MHz Average power: up to 50 W Pulse energy: up to 100 μJ Pulse duration: < 500 fs … >20 ps Beam quality: M² < 1.5 Options: SHG (515 nm), THG (345 nm) mode profile autocorrelation Time delay [ps] Expected delivery: February 2011 Antonio Ancona - 9 October 2010 Bari – 6° RD51 Collaboration Meeting

Post process Analysis Electron Microscopy - Field Emission EDS (Energy Dispersive X-ray Spectroscopy) Optical microscopy Profilometry Antonio Ancona - 9 October 2010 Bari – 6° RD51 Collaboration Meeting

Preliminary results Laser trepanned hole Cu – Kapton internal edge Laser parameters: wavelength: 1064 nm pulse duration: 100 ps repetition rate: 100 kHz average power: 0.7 W spot size: 30 μm trepanning radius: 20 μm Antonio Ancona - 9 October 2010 Bari – 6° RD51 Collaboration Meeting

Preliminary results High repeatibility Cu particle redeposition inside the hole electric isolation not always guaranteed post-process etching needed Antonio Ancona - 9 October 2010 Bari – 6° RD51 Collaboration Meeting

Outlook Etching tests to remove the Cu redeposited particles inside the hole in order to prevent voltage failures Laser trepanning assisted by an inert gas flow (or trepanning with smaller spot size) to avoid particle redeposition Micromegas (Cu 5μm/18 μm) small pitch laser machining (focusing spot down to < 10 μm) Ceramic (Al2O3) laser drilling for thick GEM fabrication Antonio Ancona - 9 October 2010 Bari – 6° RD51 Collaboration Meeting

Laser Material Processing Research Group Antonio Ancona CNR-IFN, technologist Teresa Sibillano CNR-IFN, researcher Francesco Mezzapesa Politecnico di Bari, post doc Domenico Rizzi CNR-IFN, research fellow Francesca Di Niso Università di Bari, PhD student Pietro Mario Lugarà Università di Bari, full professor Gaetano Scamarcio INFN Bari Collaboration Gabriella Catanesi INFN, Senior reseracher Vincenzo Berardi Politecnico di Bari, associate professor Antonio Ancona - 9 October 2010 Bari – 6° RD51 Collaboration Meeting

Pulse energy distribution during laser ablation absorbed laser energy : plasma generation and bond breaking particle ablation residual thermal energy vapor lattice / solid D. Breitling et al. „Fundamental aspects in machining of metals with short and ultrashort laser pulses“, Proc. of SPIE 5339 (2004), 49-63 Antonio Ancona - 9 October 2010 Bari – 6° RD51 Collaboration Meeting