1. Detection of UHE Shower Cores by ANITA By Amir Javaid University Of Delaware

2. Topics Rough estimates for event rate & shower core analysis summary Detection of Shower cores by ANITA Brief look at the shower Cores Summary of UD Monte Carlo Simulator for Shower core detection by ANITA Present status of UD Monte Carlo Some preliminary results from Monte Carlo Simulator test runs Search for a better Model for Antarctic topography Summary and future plans

3. Rough estimates for event rate above 10 19 eV for ANITA Air Showers For one steradian around the vertical axis the Event Rate estimated for ANITA payload horizon ~ 1.5×10 16 cm 2 from the measured cosmic ray flux data is ~1400 events per day[1]. Neutrinos For 2 π steradian the Event Rate estimated for ANITA horizon from the Waxman Bahcall flux model is~237 interactions per day[1]. [1] ftp://ftp.bartol.udel.edu/anita/amir/EventRate_analysis_V1.4.pdf

4. Detection of Shower cores by ANITA schematic

5. Detection of Shower cores by ANITA Energy in the Shower cores above 100PeV~10% (Corsika Shower Simulations) Shower cores will produce Askaryan pulse. Pulses may be strong enough to be detected by ANITA payload Askaryan pulses moving downwards and reflecting back from the bed rock are the most favorable for detection Regions with thin ice and high elevation are most suitable for shower core detection by ANITA. Approximately 8% of the area in Antarctica has Ice thickness 1km, which may be the region to look for shower core events

6. Detection of Shower cores by ANITA (contd..) Ice thickness Histogram (Bedmap) Area suitable for Shower core detection ~8%

7. Brief look at the shower Cores To analyze the properties of the shower cores a library of Corsika shower runs has been generated Present energy span of this library is from 10PeV -1EeV The detector elevation is set at the South Pole and zenith angle is chosen to be zero Showers are produce in South Pole magnetic field Flat detector and curved atmosphere model is used.

8. Brief look at the shower Cores (Corsika Simulation runs) 1 EeV primary proton shower footprint at South Pole for 10m 2 area

9. Brief Look at the shower Cores (contd..) 1 EeV primary proton shower footprint at South Pole for 1m 2 area

10. Brief Look at the shower Cores (contd..) 1 EeV primary proton shower footprint at South Pole for 10cm 2 area

11. Brief look at the shower cores (contd..) 150 PeV~15% of Total Shower

12. Present Status of UD Monte Carlo Simulator UD MC is in testing Stage. It is based on the SADE0.1 MC by Shahid Hussain modified to fit the ANITA event Geometry. For testing purpose AVZ parameterized Askaryan pulses are used. It uses Bedmap for ice thickness, bedrock elevation and surface elevation. Interpolation is used to fill the gaps in Bedmap data. For testing purpose Snell’s law with constant refractive of ice for ray tracing is used.

13. Present Status of UD Monte Carlo Simulator (contd..) More sophisticated ray tracing techniques do exist in UD MC. It assumes that the ice and bedrock surfaces are flat. Perfect reflection from bedrock and perfect transmission from ice/air surface. Point detector model with orientation. Constant attenuation model for testing purpose. More realistic attenuation models are also built in UD MC.

14. Preliminary Results (UD MC) Test Run geometry Detector position Latitude=-79.2993 deg Longitude=-90 o deg, Altitude=36986.5m Event position & Energy Latitude=-78 deg, Longitude=-90 deg, depth=198.3m Energy=100PeV, Cherenkov Angle=55.85 deg Test runs Red Arrows show various shower axes used to test the code X parallel depth Altitude R bn X perp Shower axes Event Vertex

15. Test Run Results (contd..)

18. Search for a better Model for Antarctic topography For modeling of the surface and bedrock roughness much high resolution Antarctic topographical models are needed. One option is the Radarsat Antarctic Mapping (RAMP) Project Digital Elevation Model Version 2 available from The National Snow and Ice Data Center. RAMP 1 km, 400 m, and 200 m DEM data are provided in ARC/INFO and binary grid formats, and the 1 km and 400 m DEMs are also available in ASCII format.

19. Search for a better Model for Antarctic topography (contd..)

20. Radarsat Surface elevation 400mRes Bedmap Surface elevation 5km Res

21. Summary and Future Plans Development of parameterization of Askaryan pulses from shower cores. Use of Fresnel reflection and transmission in UD MC Realistic Detector and triggering model. Effective area calculation Feasibility check of the Radarsat RAMP data for the use in Monte Carlo for modeling surface roughness for bedrock and ice/air surface. These files are large (~2.5 GB), which mean more cpu cycles are required Plan of ANITA -1 flight data analysis for shower core events.