1. CIEMAT ALMERÍA MADRID SORIA NAVARRA (Mock·up) CIEMAT- El Bierzo CIEMAT- Extremadura Puerto Información Científica Barcelona Public Research Institution Ministry of Science and Innovation

2. CIEMAT Energy Renewable Energies Nuclear Fusion Combustion Technology Materials Chemistry Comm. and Inf. Tech Infrastructures Scientific Instrument. Environment Radiological Conventional Long-term storage National Laboratory for Nuclear Fusion LNF Particle Physics Superconductivity Cellular and Molecular Biology Basic Research Planning and prospective Technology Transfer All other horizontal services Strategic projects (new centers) General Secretariat PIMIC Refurbishment of old facilities

3. Personnel: Budget 2007: 125 M€ 2007: 1,500 60 M€ 80 M€ 100 M€ 120 M€ 140 M€

4. Division of Scientific Instrumentation Technology ElectronicsMedical Applications AMS FAST DES CMS ITACA The CSTD project The BrainPET project Monte Carlo simulation for radiology and neutron dosimetry Accelerators Division of Scientific Instrumentation Technology Development of electronics within R&D projects, in collaboration with other teams at CIEMAT (large contribution to HEP projects) Medical Applications. R&D line on non conventional radiation detectors for medical applications. Imaging reconstruction and simulation. Accelerators Activities: FEBEX ACE 2 ECT SEPTA Magnets for particle accelerators, kinetic energy storage and superconductivity technology research. A special program launched to extend these activities to other fields of accelerators

5. Running Projects. ACE 2 Control system for a kinetic energy accumulator.

6. Fossil Fuels Development of a electrocapacitance tomography system 89 1 5 6 7 10 11 12 13 14 15 16 2 3 4 Electrodes (detail) Radial Guard Electrode belt Running Projects. ACT Guard

7. Radiator 3 cm Aerogel (n  1.05) Mirror Multilayer metallic layer deposited on Carbon Fiber Reinforced Composite Light Detection 680 PMT (Hamamatsu7600-00- M16) 4 x 4 mm 2 /pixel Goals: Measurement of the charge particle velocity (  ) (  ) /   10 -3 @  = 1 (p+) Measurement of the mass: resolution  1% Measurement of the ion charge up to Z < 25 Discrimination e+/e- up to  10GeV  Measurement of the relative abundance of light atoms H/H 2 /H 3, He 3 /He 4, Be 10 /Be 9 Size: 50 cm height 160 cm diam Weight< 200 Kg Power < 100 Watt AMS. The Rich detector

8. RICH Electronics LV - PP RPD R-Crate: 2 Units 11 modules/R-Crate 6 RDR 2 HV modules 2 Control modules 1 Link module with the main DAQ RPD: 2 Units 6 DC-DC/RPD converters Active redundancy J-Crate PMT Divisor Pre- Amp ADC board HV Distribution Input Signal Capton connectort Front End Electronics (ISN) 5 boards (3 x 3 cm 2) – HV divisor 80M  – Pre-Amplification – HV distribution – Signal Distributor – ADC (AD7476BR) x 680 units

9. Dark Energy Survey (DES) room for electronics 4 -> 6-slot backplanes 3556 mm Camera Filters Optical Lenses 2.2 deg. FOV Scroll Shutter 1575 mm CTIO (Chile) Partners Fermilab University of Illinois The Lawrence Berkeley National Laboratory NOAO -- The National Optical Astronomy Observatory NCSA -- The National Center for Supercomputer Applications CIEMAT The Barcelona Consortium IEEC/CSIC - IFAE The U.K. Consortium University London, Cambridge, Edinburgh, Portsmouth Technical goal 500 MegaPixels Camera 72 CCDs CIEMAT: Clock&Bias board Master Control board

10. CMS. Muon chambers CIEMAT developed a layer of the CMS muon drift chambers.

11. CMS. Electronics ROB Minicrate Muon drift tube chamber CIEMAT coordinates the overall electronics of the CMS muon drift chambers since 1995. Elaborates the design and construction of the read- out electronics (ROB, ROS) and its mechanics. ROS

12. CMS. The LINK alignment system Measure elements Laser sources Sensors High precision mechanical supports Periscopes Optics Control and DAS Optic (2D CMOS), CCD Position (proximity sensors: potentiometric and optical) Tilt Temperature (PT 100) Must establish relative coordinates between the inner detector at CMS (Tracker) and the muon detectors in the Barrel and End Cap Detectors are inter-connected via laser beams. Beams define six  - planes, one each 60º. Detector positions are related through these planes

13. The Superconductivity group started in 1989 and their activities include magnets for particle accelerators, kinetic energy storage, and superconductivity technology research. In addition Ciemat has launched a special program to extend these activities to other fields of accelerator A group of people is training at CERN who are contributing to LHC commissioning. Accelerators