Transcript new tools for metrology, geology & fundamental physics

1 Introduction to Space Rad EoI.
Our views and the views of Brussel 20 R. Battiston
2 Highlights of space sensor developements in France
20 S. Katsanevas
3 Highlights of space sensor developements in Italy
20 A. Vacchi
4 Space weather activities in ESA
20 R. Battiston for A. Glover
Coffee Break
20
5 Highlights of space sensor developements in Germany
20 L. Strueder
6 Highlights of space sensor: Rumenia, Spain, Slovakia
20 D. Hasegaunu R. Battiston
7 Highlights of space sensor developement in Netherland
20 H. Hoevers
8 Space radiation activities in Belgium
20 J. Lemaire
9 General discussion. How to proceed
60 All
10 Action items and conclusions
20 All
13:00 Lunch at the University Cantine
SPACERAD
Cosmic Radiation European Initiative
an integrated tool for space radiation
detectors, space radiation hardness, earth
sciences & fundamental physics“
an European Initiative for the 6th European Framework Programme
Coordination R. Battiston
ACTUAL STATEMENTS OF
INTEREST
THIS PROGRAM IS SUPPORTED BY THE
Astro Particle European Committee
(ApPEC)
INTEGRATED PROJECTS
versus
NETWORK OF EXCELLENCE
Network of Excellence
COMIC RAYS COMMUNITY
(BALLOONS & SATELLITES & GROUND BASED
DETECTORS, NETWORKING & TRAVEL)
Integ. Proj.
SPACERAD
Industrial Partners
Integ. Proj.
???
COSMIC RAYS SPECTRA
AND COMPOSITION
RADIATION HARDNESS
SPACE WEATHER
TOLERANT SOFTWARE,
Radiation Physics
RADIATION DETECTORS,
EARTHQUAKE MONITORING,
Earth Science
SOLAR FLARES
RADIATION SIMULATION TOOLS,
EARLY WARNING,
MONTECARLO SIMULATIONS
ATMOSPHERIC PHYSICS ...
GROUND ELECTRONICS,
& SPACE FAULT
APPLICATIONSMONITORING,
ANTIMATTER
Fundamental
DARK MATTER
Physics
GAMMA RAY BURST
IONIZATION FLASHES
...
Application oriented Research
GROUND & SPACE
SPACERAD
Demonstrators
New generation of particle detectors for space applications
Particle detectors
Radiation
physics
Computing and
simulation
PARTICLE DETECTORS
FAULT TOLERANT SOFTWARE
COSMIC RADIATON SIMULATION TOOLS
SPACE WEATHER
EARTH OBSERVATON (E.G. EARTHQUAKE PREDICTION)
ATMOSPHERE OBSERVATION
THE NETWORK CHART
INDUSTRY
RESEARCH
FRONT END AND DAQ RADIATION HARD ELECTRONCS
RADIATION HARD ELECTRONICS
RADIATION HARD DAQ
RADIATION HARD MEMORIES
SIMUATION TECNIQUES
TIME OF FLIGHT
CALORIMETERS
SILICON TRACKER
TRANSITION RADIATION DETECTOR
RING IMAGING CERENKOV
MONTECARLO SIMULATION
FLUKA SIMULATION
SPENVIS
FORWARD/BACKWARD TRACING
CPU INTENSIVE CALCULATIONS
EARTH MAGNETIC FIELD ANOMALIES
EARTHQUAKES MONITORING
ERROR TOLERANT
SOFTWARE
MONITORING AND
PREDICTION OF SOLAR FLARES
GOALS

.... should foster the fundamental research on medium and
high energy cosmic radiation, with precision experiments
in space, in the atmosphere and in ground laboratories,
involving Radiation Detectors, Radiation Hard Electronics
and CPU, Space Weather, Fundamental Physics in Space
and Earth Sciences

….should stimulate the coordination and collaboration
among European Groups working in the field of High
Energy Cosmic Radiation detection and study
S
P
A
C
E
 ... should develop the technology to build a new generation
R
of compact, low cost, high sensitivity, radiation detectors A
for the use in Space such as AMS, GLAST, PAMELA, D
NINA, ALTEA, BABY-EUSO …. (demonstrators)
GOALS


ctd.
SPACERAD wish to motivate industry to support
the design of small size, reliable, high precision
satellites capable to withstand cosmic radiation,
and able to monitor with accuracy the radiation
environment around the Earth and its periodic
modifications
... should deliver compact detectors such as
silicon trackers, silicon and scintillating
calorimeters, time of flight detectors, transition
radiation detectors, ring imaging Cerenkov
detectors, magnets, UV detectors (demonstrators)
S
P
A
C
E
R
A
D
...develop
GOALS
ctd.
new methods for fundamental research
exploring the different forms of radiation reaching our
planet
….develop
new methods for simulation and study of
the effects of cosmic radiation on electronics and
software tools for space applications
….stimulate
the developments of new CPUintensive algorithms to study the behaviour and
development of cosmic radiation
...should
be a platform for joint cooperation e.g. to
perform comparisons and integrated measurements
among ground and space experiments
S
P
A
C
E
R
A
D
GOALS
ctd.

...should develop advanced technologies for fast
triggering and advanced warning for Radiation
Intensive Events

...should integrate the diverse research activities in
S
cosmic rays („Job sharing“)

... should include groups who will start on the
related fields and provide training for young
researchers
P
A
C
E
R
A
D
Examples for
primary DELIVERABLES
to be generated by the IP
(not from each individual partner)

DEMONSTRATORS: Innovative cosmic radiation
space born detectors like:
silicon trackers, silicon and fiber calorimeters, ring
imaging detectors,time of flight, transition
radiation detectors, magnet spectrometers, UV
detectors
 Low power radiation hard power supplies,
electronics, trigger and CPU and related
technologies
 Radiation hard algorithms and related
technologies
S
P
A
C
E
R
A
D
Examples for
primary DELIVERABLES
to be generated by the IP
(not from each individual partner)
Cosmic radiation software simulation
tools (MonteCarlo simulation, FLUKA,
SPENVIS)
 Cosmic radiation data processing and
simulation involving massive amount
of CPU power

S
P
A
C
E
R
A
D
WHY INDUSTRIAL
PARTNERS ?

BILATERAL KNOW-HOW TRANSFER
 SYNERGIES BY USING INDUSTRIAL
EXPERIENCES, STANDARDS, FACILITIES
& EQUIPEMENT
 INDUSTRIAL PRODUCTS HAVE
Higher reliability
Higher stability
High performance
Application oriented design (low power
consumption, miniaturisation,...)