2019-08-01_Sky_and_Telescope

skyandtelescope.com • AUGUST 2019 15

Turns out, Sco X-1 is the brightest endur-

ing X-ray source outside the solar system.

But the rocket launched by Giacconi’s team

might easily have missed it: A big chunk of

sky was hidden behind Earth during the

nearly six minutes the rocket was aloft. The

discovery was fortunate indeed for Giacconi,

as it played a key role in winning him the

2002 Nobel Prize in Physics. But it was even

more fortunate for X-ray astronomy, galva-

nizing the fi eld as well as the imagination.

“It was pretty hard to explain [Sco X-1] by

anything except something that you didn’t

expect to fi nd,” says former Chandra X-ray

Center director Harvey Tananbaum (Center

for Astrophysics, Harvard & Smithsonian).

Over the next six decades, X-ray astron-

omy kept growing, albeit sometimes in fi ts

and starts. As more instruments took to

space, the data that came back helped con-

fi rm theorists’ wildest imaginings — X-rays

provided crucial evidence for the existence

and physics of neutron stars, black holes, dark matter, and

more. “There’s a whole range of activity in the universe that

would have been completely unknown to us without X-ray

astronomy,” says Peter Kretschmar (European Space Agency).

Yet even as 2019 sees the triumphant 20th anniversaries

of the Chandra X-ray Observatory and the XMM-Newton

satellite, astronomers are still struggling to maintain their

space-based window on the X-ray universe.

Freedom: Satellites Take to the Sky

Not long after the fi rst discoveries, scientists began craving

more than the few minutes of observing time that a rocket

could grant them. Giacconi led the team at AS&E as they

began to build a dedicated X-ray satellite — this time with

NASA funding.

The project, offi cially known as Small Astronomical Satel-

lite A, would contain two sets of proportional counters to scan

the sky and pinpoint X-ray sources to within a few arc-

minutes. These proportional counters consisted of beryllium

casings surrounding interiors that were fi lled with argon gas.

An X-ray photon that penetrated the tube’s thin beryllium

windows would collide with an argon atom and initiate an

avalanche of ion-electron pairs proportional to the photon’s

energy. Combined with a star tracker that told scientists

which way the satellite was pointing, the proportional coun-

ter could record X-rays by their position on the sky.

pDISCOVERY Riccardo Giacconi and his team

launched an Aerobee rocket and, in addition to solar

fl uorescence off the surface of the Moon, the second

proportional counter onboard detected X-rays

streaming from a source identifi ed as Scorpius X-1.

The third counter, which was pointing in another

direction, saw a pervasive background of X-ray pho-

tons. (The fi rst counter failed and isn’t shown.)

uX-RAY VISION Rather than using wavelengths, astronomers typi-

cally refer to X-rays in terms of their energy, given in units of electron

volts (eV) or, more often, kiloelectron volts (1,000 eV, or 1 keV). Uhuru, for

example, used proportional counters to detect X-rays in the range from

2 to 20 keV. Nowadays, XMM-Newton sees X-rays between 0.1 and 10

keV. Some instruments, like Integral, go to even higher energies, catch-

ing both X-rays and gamma rays (3 to 10,000 keV).

The just-graduated Tananbaum joined

the team in 1968, when the fi eld of X-ray

astronomy was only six years old. He accom-

panied equipment to the launch site off the

coast of Kenya, an equatorial location where

Earth’s rotation boosts rocket speed. With

the rocket due to launch shortly after midnight, Tananbaum

followed the crew’s progress via a computer on the mainland,

six miles from the rocket platform. He was waiting to perform

a last equipment test about half an hour before launch.

“They’re counting down, and they go into a hold, they’re

checking something on the rocket,” he recalls. “There’s limited

information fl owing, and the Sun comes up and it’s starting

to get warm.... Temperatures inside the payload are going up

and up.” High heat and humidity were threatening the mission

before it could make it into space. The platform crew had to

decide: scrub or launch.

The decision was quick — the count jumped from T minus

hours to T minus minutes. “And bingo, it launches,” Tanan-

baum chuckles. That day, December 12, 1970, happened to

fall on Kenya’s independence day, and Giacconi renamed the

mission Uhuru (Swahili for freedom) in the country’s honor.

Before long, computer screens showed so-called “X-ray

stars” seething on the sky. Some varied predictably in their

Revealing

the X-ray Sky

Year Number of

X-ray sources

1962 1*

1965 10

1970 60

1974 160

1980 680

1984 840

1990 8,

2000 340,

2010 780,

2017 1,250,

*Excluding the Sun.

Data source: NASA’s High Energy

Astrophysics Science Archive

Research Center

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