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X-ray Polarimeter Biswajit Paul Raman Research Institute, Bangalore

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1 X-ray Polarimeter Biswajit Paul Raman Research Institute, Bangalore
X-ray Polarimeter Team at RRI Biswajit, Rishin, Gopala Krishna, Duraichelvan, Chandreyee, Ateequlla, Arasi, Jincy, Mamatha, Marykutty, Nagaraj, Rajagopal, Sandhya, …

2 X-ray Polarimeter Polarisation is unexplored in High Energy Astrophysics X-ray emission from the following processes should be polarised Cyclotron Synchrotron Non-Thermal Bremsstrahlung Scattering from non-spherical plasma These objects should produce polarised X-ray radiation Accretion powered pulsars Rotation powered pulsars Magnetars Pulsar wind nebulae Non-thermal supernova remnants Black holes, micro-quasars and active galactic nuclei Measurement Technique Anisotropic Thomson Scattering Crab nebula is the only source for which X-ray polarisation measurement exists. This was made in 1976 !! Approved mission: GEMS

3 Accreting X-ray Pulsars

4 Jets & Motion in Accretion Disk
around Black Holes

5 X-ray Reflection from BH Accretion Disk

6 Rotation Powered Pulsars & Magnetars

7 X-ray Polarisation Measurement Techniques
Bragg Reflection Thompson Scattering Photoelectron imaging

8 A Thomson X-ray Polarimeter
Photoelectron/Bragg: < 10 keV Compton :> 30 KeV Thomson: 5-30 keV

9 Test Setup

10 Polarised X-ray Source
Log (N) Energy (keV)

11 Test Results

12 Engineering Model The mechanical configuration
Similar to prototype ->Consists of 4 detectors placed symmetrically on all sides of the scattering element ->Larger area ->Overlapping arrangement to reduce corner dead area ->Detectors side-connected to increase stiffness

13 Mechanical configuration…..

14 Polarimeter electronics: The five main sections

15 Results – Square Detector
15

16 Design Simulations

17 Collimators Front Back

18 Scientific Requirements & Experiment Configuration
Minimum Science goal: MDP of 2-3% at 5 sigma level for 1 million sec exposure of a 50 mCrab source. Potential Sources :50 MDP (n) = (n /  S) (2(S+B)/T) 1/2

19 Sensitivity MDP(n) =(n/S) (2(S+B)/T) 1/2 GEMS

20 Cylindrical detector An alternative approach No dead area at corners
Uniform gain and quantum efficiency in all directions Less systematic uncertainties

21 Cylindrical detector The completed wire-frame
Total no of wires =24 anodes+48 anti anodes+648 cathodes = 720

22 Development Status Results
A Thomson X-ray polarimeter has been designed, developed and successfully tested at RRI. These have been made: Detectors Front end electronics Processing electronics Collimators with flat top response Test and calibration setup Rotational stage Results Power spectrum Unpolarised source Polarised source

23 Thomson X-ray Polarimeter
Proposal submitted to ISRO Key features of the polarimeter Minimum detectable Polarisation of 2% at 5 sigma level for a 50 mCrab source No of sources: 50 Weight: 110 kg Data rate: 300 Mb per orbit Spacecraft requirements Spinning platform/satellite, rpm Very long exposures required, one week to one month Pointing accuracy required: 0.1 degree Equatorial orbit, less than 10 degree Altitude: 500—600 km Collimator Scatterer Detectors

24 New Development/Technique
50.3mm 50mm Photoelectron polarimeter with proportional counters Initial two piece design 0.6mm 0.15mm Anode wire The new design AN1 AN2

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