4th Concept Pixel Vertex (PX) 20-micron pixels (like Fermilab/SiD thin pixel) TPC (like GLD or LDC) with “gaseous club sandwich” Triple-readout fiber calorimeter:

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Presentation transcript:

4th Concept Pixel Vertex (PX) 20-micron pixels (like Fermilab/SiD thin pixel) TPC (like GLD or LDC) with “gaseous club sandwich” Triple-readout fiber calorimeter: scintillation/Cerenkov/neutron (new) Muon dual-solenoid iron-free geometry (new), cluster counting (new) basic design B Mostly orthogonal to other three concepts Basic design principle: only four basic, powerful systems, each as simple as possible. Obviate any need for tail-catchers, pre-showers detectors, end-cap chambers, or silicon blankets to augment performance of main detector. ~1/3 Asian, ~1/3 American, ~1/3 European J. Hauptman; A. Penzo, A. Mikhailichenko, C. Gatto, F. Grancagnolo (at Valencia)

4th talks at Valencia Workshop Alexander Mikhailichenko, Cornell LNS, machine-detector interface, push-pull, B-field configuration Aldo Penzo, INFN Trieste, dual readout calorimetry and its extensions Franco Grancagnolo, INFN Lecce, muon spectrometer Corrado Gatto, INFN Lecce, ILCroot simulation and analysis of 4th Concept

Final focus optics, mounted inside a cylinder attached to the detector by consoles. This reduces influence of ground motion. Dual solenoids Directional kicker Valves for push- pull disconnection FF optics A. Mikhailichenko

New magnetic field, new ``wall of coils’’, iron-free: many benefits to muon detection and MDI, Alexander Mikhailichenko design

Aldo Penzo : DREAM module: simple, robust, not intended to be “best” at anything, just test dual-readout principle Unit cell Back end of 2-meter deep module Physical channel structure

Downstream end of DREAM module, showing HV and signal connectors

Dual-Readout: Measure every shower twice - in scintillation light and in Cerenkov light. 200 GeV “jets” Data NIM A537 (2005) 537.

DREAM data 200 GeV π - : Energy response Scintillating fibers Scint + Cerenkov f EM ∝ (C/E shower - 1/  C ) (4% leakage fluctuations) Scint + Cerenkov f EM ∝ (C/E beam - 1/  C ) (suppresses leakage) Data NIM A537 (2005) 537.

More important than good Gaussian response: DREAM module calibrated with 40 GeV e - into the centers of each tower responds linearly to π - and “jets” from 20 to 300 GeV. Hadronic linearity may be the most important achievement of dual- readout calorimetry. e-e- Data NIM A537 (2005) 537.

DREAM module 3 scintillating fibers 4 Cerenkov fibers “Unit cell” → ILC-type module 2mm Pb or brass plates; fibers every 2 mm (Removes correlated fiber hits)

Binding energy loss fluctuations: next largest hadronic shower fluctuation after EM fraction, correlated with MeV neutrons (1) Measure MeV neutrons by time. ~~~~~~~~~~~~~~ t(ns) → (protons) (neutrons) Pathlength (cm) Velocity of MeV neutrons is ~ 0.05 c Scintillation light from np→np scatters comes late; and, (2) neutrons fill a larger volume

Franco Grancagnolo : Muon spectrometer

Dual solenoid tracking along muon trajectories in the annulus between solenoids

Dual readout of muons in DREAM module

Illustrates all the detectors of 4 th Concept … particle ID “obvious” Text Corrado Gatto: ILCroot