Title: AQUEYE: SCIENTIFIC TARGETS
1AQUEYESCIENTIFIC TARGETS
2Aqueye ultrafast photometer
- Exploitation of high time resolution to study
high speed astrophysical phenomena in - Pulsars
- Cataclysmic variables
- X-ray binaries
- Pulsating white dwarfs
- Pulsating neutron stars
- Flare stars
- Planetary nebulae
- Stars with transiting exoplanets
3PULSAR
- Formation by a supernova explosion
extremely high rotational velocity (periods
range from 1.5 ms to 8.5 s )
intense magnetic field (typically in the range of
108 - 1012 gauss )
4- Pulsars are highly magnetized rotating neutron
stars - Accelerated charged particles
emissions in radio, visible, x-ray and ?-ray
domains
5- Lighthouse effect
- extraordinarily rapid and stable rotation
pulsed nature
very regular rotation period (the regularity of
pulsation is as precise as an atomic clock)
pulsars as useful instrument for Aqueyes
calibration
6Crab Pulsar
- The first pulsar discovered (1968)
- Remnant of AD1054 supernova
- It lies in the Crab Nebula (M1)
- Period P 33 ms
- Delay 36ns /day
- The brightest optical pulsar we know
- Double pulse per rotation in visible, X-ray and
?-ray domains - The most energetic pulsar we know
- Right ascension 05h 34m 31.97s
- Declination 22 00 52.1
7CATACLYSMIC VARIABLES
- CVs binary systems in which a late-type
secondary star fills the Roche lobe and transfers
matter onto a white dwarf (WF)
CLASSIFICATION ACCORDING TO THE MAGNETIC
BEHAVIOUR
1) non-magnetic systems
82) Intermediate- Polars (DQ Herculis stars)
3) Polars (AM herculis stars)
9CVs flickering
- FLICKERING stochastic brightness variations
- Time scale dozen minutes less than a
second - Amplitudes a few tenths of magnitude
magnitude scale
flickering as a continuous series of overlapping
flares and bursts in the light curves of CVs with
random variability
Fig lightcurve of V709 Cas (Tamburini et al., in
preparation)
10WHY IS FLICKERING IMPORTANT? 1) its a
fundamental signature of accretion processes 2)
it represents a significant fraction of the total
luminosity of the source
OPEN QUESTIONS 1) whats the exact physical
nature? 2) is flickering a self-similar process
also at very small scales?
short time-scale down to which flickering
is still self-similar vital information about
the driving mechanism behind flickering underst
anding the physics occurring at much shorter
time-scales
HIGH SPEED PHOTOMETRY
114-6 APRIL
- Object RA(J2000) Dec(J2000) Type ltmgt
?morb Pspin (s) Porb (h) - ST LMi 11 05 39.8 25 06 28.9 P 15.1 (B)
1.8 (B) - 1.898 - YY Dra 11 43 38.3 71 41 20.4 IP 14.0 (V)
2.0 (V) 529.31 3.969 - AM CV 12 34 54.6 37 37 43.4 NL 14.1 (V)
0.1 (V) - 0.286 (17.1 min) - GP Com 13 05 42.9 18 01 03 NL 15.6 (B)
0.4 (B) - 0.776 (46.6 min) - CT Ser 15 45 39.0 14 22 32.7 N 16.3 (V)
0.3 (V) - 4.68 - DQ Her 18 07 30.3 45 51 32.6 IP 15.2 (V)
3.5 (V) 71.066 4.647 - V533 Her 18 14 20.3 41
51 21.3 N 14.4 (V) 0.8 (V) 63.63 3.528 - AM Her 18 16 13.3 49 52 04.2 P 12.0 (V)
1.5 (V) - 3.094 -
- Object RA(J2000) Dec(J2000) Type ltmgt
?morb Pspin (s) Porb (h)
8-12 OCTOBER
1222-27 OCTOBER
- Object RA(J2000) Dec(J2000) Type ltmgt ?morb Pspin
(s) Porb (h) - RX And 01 04 35.6 41 17 58.0 DN 14.0 (V) 1.5
(V) - 5.037 - XY Ari 02 56 09.0 19 26 29 IP 13.1 (K) 0.4
(K) 206.298 6.065 - GK Per 03 31 11.8 43 54 16.8 IP 12.8 (V) 0.9
(V) 351.332 47.923 - V1159 Ori 05 28
59.5 -03 33 52.8 DN 13.6 (V) 1.8 (V) - 1.492 - V405 Aur 05 57 59.3 53
53 44.9 IP 13.9 (V) 0.7 (V) 545.455 4.143 - KR Aur 06 15 43.9 28 35 08.9 NL 11.3 (B) 2.3
(B) - 3.907 - BG CMi 07 31 29.0 09 56 22.6 IP 14.3 (V) 1.1
(V) 847.03 3.234 - PQ Gem 07 51 17.4 14 44 24.6 IP 14.0 (V) 0.5
(V) 833.42 5.193 - EI UMa 08 38 22.0 48 38 01.7 DN 14.8 (V) 1.2
(V) 741.6 6.434 - BK Lyn 09 20 11.2 33 56 42.6 NL 14.5 (V) 2.4
(V) - 1.800 - YY Dra 11 43 38.3 71 41 20.4 IP 14.0 (V) 2.0
(V) 529.31 3.969 - P polar, IP intermediate polar, N nova, NL
nova-like, DN dwarf nova
13QPOs (Quasi Periodic Oscillations)
- QPOs quasi coherent variabilities about certain
frequencies - Main sources Low Mass X-Ray Binaries
- Probable emission s cause shocked wave created
on the accretion disk - Why are we interested in?
to understand the innermost regions of accretion
disks of the central compact objects
What sort of variation with time could cause a
QPO?
14PULSATING WHITE DWARFS and NEUTRON STARS
- Luminosity varitions due to radial and
non-radial pulsations - Oscillations time-scale white dwarfs ?
1001000 ms -
neutron stars ? 100 ?s
superposition of vibrational modes light output
variations asteroseismological evidence about
the interiors of the star
154-6 APRIL
- Object RA Dec Type ltmgt ?mpuls Period(s) (sec)
- HE 12580123 13 01 110.5 01 07 39.7 DAV 16.26
(V) 0.18 (V) 529 - 1092 - IU Vir 14 03 57.2 -15 01 10 DAV 15.67 (B) 0.30
(B) 399, 610, 724, 937 - TY CrB 16 01 21.2 36 48 34.3 DAV 14.36 (V) 0.15
(V) 833, complex - V470 Lyr 18 57 30.2 33 57
25.9 DAV 14.62 (V) 0.06 (V) 259, 292, 557, 739 - PT Vul 19 52 28 25 09 24 DAV 15.12 (V) 0.05
(V) 256 - Object RA Dec Type ltmgt ?mpuls Period(s) (sec)
- ZZ Cet 01 36 13.6 -11 20 32.2 DAV 14.16 (V) 0.01
(V) 213, 274 - GD 1400 01 47 21.8 -21
56 51 DAV 15.4 (V) 0.24 (V) 462 - 823 - V411 Tau 04 18 56.5 27 17 51.4 DAV 15.20
(V) 0.28 (V) 494, 625, 746
8-12 OCTOBER
1622-27 DECEMBER
- Object RA Dec Type ltmgt ?mpuls Period(s)
(sec) - ZZ Cet 01 36 13.6 -11 20 32.2 DAV 14.16
(V) 0.01 (V) 213, 274 - V411 Tau 04 18 56.5 27 17 51.4 DAV 15.20
(V) 0.28 (V) 494, 625, 746 - V468 Per 04 20 18 36 16 36 DAV 15.59
(V) 0.22 (V) 910, 1024 - V1396 Ori 05 10 13.9 04 38 44 DAV 15.36
(V) 0.2 (V) 355, 445, 560 - VW Lyn 09 01 48.7 36 07 07.7 DAV 14.55
(V) 0.07 (V) 350, 481, 592 - RY LMi 09 24 16 35 16 54 DAV 15.50
(V) 0.06 (V) 215, 271, 304 - SW LMi 09 57 50 33 59 42 DBV 17.2
(B) 0.30 (B) 650, complex - DAV ZZ Cet WD, DBV V777 Her WD, DOV GW Vir
17FLARE STARS
FLARE STARS variable star which can undergo
unpredictable increases
in brightness for a few minutes
4-6 APRIL
- Object RA(J2000) Dec(J2000) ltmgt TSp
- FL Vir 12 33 26.5 09 01 01 12.50
(V) dM5.5e/M7 - GJ 643 16 55 25.23 -08 19 21.3 11.70
(V) dM3.5 - V1054 Oph 16 55 28.76 -08 20 10.8 9.04
(V) dM3e - VB8 (Gl644C) 16 55 35.74 -08 23 36.0 16.70
(V) dM7 - Object RA(J2000) Dec(J2000) ltmgt TSp
- V1005 Ori 04 59 35.1 01 47 09 10.05 (V) M1Ve
- YZ CMi 07 44 43 03 33.7 11.12 (V) dM4.5
8-12, 22-27 OTTOBRE
18PLANETARY NEBULAE
- PLANETARY NEBULAE astrophysical
laser emissions
NGC 7027
RA Dec ltmgt
21 07 01.6 42 14 10.2 8.8 (V)
19STARS WITH TRANSITING EXOPLANETS
- observation of planetary transit
- (for a large time span!)
- accurate evaluation of the transit starting time
- observation of TTVs (Transit Timing Variations)
- detection of other exoplanets orbiting around
- the same parent star
high time resolution
detection of companion planets with
small masses large mutual distances
204-6 APRIL
Object RA Dec ltmgt Porb (day) Mass (MJ) XO-1 16
02 12 28 10 11 11.3 (V) 3.941534 0.9 HD147506
16 20 36 41 02 53 8.71 (V) 5.63341 8.17 HD14
9026 16 30 29 38 20 50 8.15 (V) 2.8766 0.36 TrES-
3 17 52 07 37 32 46 12.4 (V) 1.30619 1.92 TrES-1
19 04 09 36 37 57 11.79 (V) 3.0300737 0.61 TrES-2
19 07 14 49 18 59 11.41 (V) 2.47063 1.98
8-12 OCTOBER
Object RA Dec ltmgt Porb (day) Mass (MJ) WASP-1 00
20 40 31 59 24 11.79 (V) 2.51997 0.89 XO-2 07 48
07 50 13 33 11.18 (V) 2.615838 0.57
22-27 DECEMBER
Object RA Dec ltmgt Porb (day) Mass (MJ) XO-2 07 48
07 50 13 33 11.18 (V) 2.615838 0.57