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Microlensing with CCDs

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Presentation on theme: "Microlensing with CCDs"— Presentation transcript:

1 Microlensing with CCDs
Philip Yock University of Auckland, NZ NZ-Australia Semiconductor Instrumentation Workshop, June 2004

2 Why microlensing? – Why CCDs?
Precision measurements can be made on stars Highest precision measurements on planets Many stars must be monitored – CCDs essential

3 Basics of microlensing
Source Earth EINSTEIN RING

4 Demonstration with a glass lens
Courtesy Sidney Liebes, Princeton

5 Typical astronomical dimensions
10,000 ly 20,000 ly 2 AU 1 mas

6 Detectable in the Galactic Bulge

7 Required separation ~ 1mas, but typical separation ~1as
The need for CCDs Required separation ~ 1mas, but typical separation ~1as “No chance of observing this phenomenon” - Einstein (1936)

8 Typical CCD arrays MOA-II MOA-I 24 million pixels 80 million pixels

9 Difference imaging essential from the ground
Ground versus space MACHO 98-BLG-35 HST MOA Difference imaging essential from the ground

10 Typical transverse velocity ~ 200 km/sec
Light curve Typical transverse velocity ~ 200 km/sec

11 Liebes-Paczynski light curve versus data

12 Planetary microlensing
Planets perturb the Einstein ring

13 Comparison with Rutherford scattering

14 Planetary perturbations
Neptune at 2 AU Perturbation ~ 5%

15 Neptune at ~ 2AU at different 

16 Earth at ~ 2 AU Perturbation ~ 0.5%

17 Two planets Detectable if  > 20°

18 MACHO 98-BLG-35  Magnification = 80  Possible Earth-mass planet

19 MOA 2003-BLG-32/OGLE 2003-BLG-219 Magnification = 520
e-4 = Neptune e-5 = Earth e-6 = Mars (preliminary)

20 MOA 2003-BLG-32/OGLE 2003-BLG-219 e-4 = Neptune e-3 = Saturn

21 Binary lens A “caustic” is formed

22 MOA 2002-BLG-33 Wise 1m 20 exp MOA 0.6m 480 exp HST 2.4m 5 exp EROS 1m
MDM 2.4m 260 exp HST 2.4m 5 exp EROS 1m 186 exp Boyden 1.5m 473 exp

23 MOA 2002-BLG-33  The light curve determines the lens geometry
 The lens profiles the source

24 MOA 2002-BLG-33  Caustic crossed in 15.6 hours
 Profiles obtained, on entry and on exit

25 Stellar profile  Stellar atmosphere theory confirmed
MOA 2002-BLG33 Another star  Stellar atmosphere theory confirmed  Precision comparable to that of the VLTI - Very Large Telescope Interferometer at ESO

26 Conclusions  Stellar gravitational lenses exist
 Extra-solar planets detectable  Stars resolvable  Nature helpful!

27 64 million dollar question
Is SU(3)SU(2)U(1) being studied on other planets?

28 Acknowledgements  Ian Bond & Nick Rattenbury
 John Hearnshaw & Yasushi Muraki  Colleagues in MOA, MACHO, EROS, OGLE, FUN, PLANET  Marsden Fund, Department of Education of Japan

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