From;
Exotic explanation for Pioneer anomaly ruled out
http://physicsworld.com/cws/article/news/2012/apr/16/exotic-explanation-for-pioneer-anomaly-ruled-out
"Pioneer 10 and 11 probes are following trajectories that cannot be
explained by conventional physics. Known as the "Pioneer anomaly",
both craft seem to be experiencing an extra acceleration towards the
Sun as they exit the solar system that is 10 billion times weaker than
the Earth's gravitational pull."
and
Efficient acceleration
The simulation reveals that the two main sources of thermal emissions
on the spacecraft are the RTG itself and the scientific instruments
that it powers. These instruments, which are mostly mounted on the
back of the spacecraft, face away from the Sun and, according to the
simulations, their thermal emissions have a relatively high efficiency
of accelerating the spacecraft towards the Sun.
"Benny Rievers of the University of Bremen in Germany. With his
colleague Claus L?mmerzahl, Rievers has also used computer modelling
to show that directional thermal emissions are the likely cause of the
Pioneer anomaly. "I think that we now completely understand what is
going on with the spacecraft and that the anomaly is completely down
to anisotropic heat radiation," says Rievers."
I personally form no hypothesis as to the cause of the anomaly, but
ansitropic thermal radiation seems exotic to me. How does either the
cooling of the instruments or the radiation of the heat do work upon
the momentum of the space-craft. I'm sorry, I just don't get it. Does
anyone else?
AAG
[[Mod. note --
The basic idea is simple: the Pioneer spacecraft were (are) powered
by Pu-238 radioactive generators which produced about 2500 Watts of
power at launch (decaying with the well-known Pu-238 half-life of
88 years). The question is, what happens to that power? A tiny bit
of it (about 8 Watts) leaves the spacecraft as radio power directed
back towards the Earth; all the rest ultimately leaves the spacecraft
as thermal radiation.
We know that photons carry momentum as well as energy, so the radio
beam and thermal radiation also carry momentum away from the spacecraft,
i.e., they can accelerate the spacecraft. If you work out the numbers,
it turns out that only about 60 Watts or so of beamed power would be
enough to give a recoil acceleration matching the measured anomolous
acceleration of the Pioneer spacecraft. Or more realistically, a
rather small anisotropy in the overall (~2500-Watt) thermal radiation
flux would suffice to explain the anomolous acceleration.
So, the question is, how isotropic or anisotropic is the thermal
radiation flux leaving the spacecraft? That basically depends on the
temperature distribution in the spacecraft. (Recall that the Pu-238
parts are very hot, and some other parts of the spacecraft are very
cold, so there are large temperature gradients across the spacecraft
structure.)
This recent research is the development of a more-accurate-than-before
thermal model of the spacecraft, and its calibration against the available
telemetry from temperature sensors at various places on the spacecraft.
The researchers find that the temperature does indeed vary a lot between
different parts of the spacecraft, and they calculate that the thermal
flux is in fact just anisotropic enough to explain the measured anomolous
acceleration of the Pioneer spacecraft.
For a more detailed account, see the recent technical paper:
Turyshev etal
"Support for the thermal origin of the Pioneer anomaly"
arXiv:1204.2507.
-- jt]]