Philips Atlas of the Universe

ATLAS OF THE UNIVERSE

Missions to Mars

M

ariner 4 bypassed Mars on 14 July 1965, at a range

of 9789 kilometres (6080 miles). It carried cameras,

and the images showed that Mars is a cratered world

rather than having a smooth, gently undulating surface, as

had been generally believed. Other probes followed,

mainly American; even now the Russians have had

very little luck with their Martian spacecraft. Then, on 13

November 1971, Mariner 9 entered a closed orbit, and

for the next eleven months sent back splendid pictures of

much of the surface. The minimum distance from Mars

was 1640 kilometres (1020 miles), over 7000 images were

received, and contact was not lost until October 1972.

Mariner 9 changed many of our ideas about Mars.

First the atmosphere turned out to be much thinner than

anticipated. It had been estimated that the ground pressure

should be about 87 millibars, equivalent to the pressure

in the Earth’s air at rather less than twice the height of

Everest, and that the main constituent was likely to be

nitrogen; in fact the pressure is below 10 millibars every-

where – so that it corresponds to what we regard as a

reasonably good laboratory vacuum – and most of the

atmosphere is made of carbon dioxide, with only small

amounts of nitrogen and other gases.

It is now known that the polar caps are made chiefly

of water ice, with a variable coating of carbon dioxide ice.

The caps are not identical; the carbon dioxide layer is

thicker in the south, and never vanishes completely.

During the southern winter, which is colder than that of

the northern, carbon dioxide condenses out of the atmos-

phere on to the polar cap, and there is a temporary fall in

atmospheric pressure.

The pictures of the surface were dramatic; naturally, it

had not been realized that all the earlier probes had sur-

veyed the least interesting areas of the planet. For the first

time we could examine the giant volcanoes, such as the

majestic Olympus Mons, which has an altitude of 25 kilo-

metres (15 miles) – three times the height of Everest –

with a 600-kilometre (375-mile) base and an 85-kilometre

(50-mile) caldera at its summit. It was found that there are

two marked bulges in the Martian crust, those of Tharsis

and Elysium, and it is here that most of the volcanoes lie,

though there are minor volcanoes elsewhere. Tharsis is

the major feature; along it lie the volcanoes of Ascraeus

Mons, Arsia Mons and Pavonis Mons, with Olympus

Mons not far away. All these had been seen by Earth-

based observers, but there had been no way of finding out

just what they were; Olympus Mons had been known as

Nix Olympia, the Olympic Snow, as it sometimes shows

up telescopically as a white patch. North of Tharsis lies

Alba Patera, only a few kilometres high but more

than 2400 kilometres (1500 miles) across. The Elysium

bulge is smaller than that of Tharsis, and the volcanoes

are lower.

The two hemispheres of Mars are not alike. In general

the southern part of the planet is the higher, more heavily

cratered and more ancient, though it does contain two

deep and well formed basins, Hellas and Argyre. The

northern hemisphere is lower, younger and less cratered,

though it does contain part of the Tharsis bulge.

The Mariner Valley (Valles Marineris), just south of

the equator, has a total length of 4500 kilometres (2800

miles), with a maximum width of 600 kilometres (375

miles); the deepest part of the floor is 7 kilometres

(4 miles) below the rim. There are complex systems, such

as Noctis Labyrinthus (once taken for a lake, and named

Noctis Lacus), with canyons from 10 to 20 kilometres

(6 to 12 miles) wide making up the pattern which has led

to the nickname of the Chandelier. There are features

which can hardly be anything other than old riverbeds, so

that in the past Mars must have had a warmer climate

and a denser atmosphere than it does now; and of course

there are the craters, which are everywhere and some of

which are more than 400 kilometres (250 miles) across.

Here and there we find ‘islands’, and there is strong

evidence of past flash-flooding.

Whether there is any active vulcanism going on now

on Mars is a matter for debate. There is a crust, probably

between 15 and 20 kilometres (9 to 12 miles) deep, which

overlies a mantle. A magnetic field has been detected but

is very weak.

▲ Olympus Mons,the

highest volcano on Mars;

it is 25 km (15 miles) above

the outer surface, and has

a base measuring 600 km

(375 miles). It is crowned by

an 85-km (53-mile) caldera.

It is a huge shield volcano,

far larger and more massive

than terrestrial shield

volcanoes such as Mauna

Kea and Mauna Loa. This

view is a composite of

images obtained from the

Viking orbiter.

 Mars in winter,

photographed by Viking

Lander 2. In the shadows

of rocks and boulders a

white condensate can be

seen, either water ice or

frozen carbon dioxide (dry

ice), or a combination of the

two precipitated on to the

ground as snow or frost.

Or it could have come to

the surface from below,

by cryopumping. Several

small trenches can be seen

in the centre foreground;

they were dug by the

lander’s soil-sampler arm

as it gathered material for

Viking soil experiments.

The soil scoop’s cover

lies to the right of the

trenches, where it was

dropped when the lander’s

mission began. Most rocks

in the scene are

approximately 50 cm (19–20

inches) across.

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