Knowledge of physical characteristics of extrasolar material, obtained with these local space measurements, represents an important step in our understanding the Sun's interaction with its immediate interstellar neighbourhood.

The Sun is located in the outskirts of the Milky Way, about 30 000 light years from its centre, embedded in a fairly dilute and warm cloud of interstellar gas, which consists of a mixture of neutral and ionized gas or plasma.

This cloud material represents a sample of today's interstellar matter in our Milky Way Galaxy from which stars and planetary systems form. In the case of the Sun and its planets this occurred about 4.5 billion years ago.

Differences in the composition of these two samples of galactic matter tell the story of the evolution of matter in the galaxy as heavy elements are added by dying stars.

The solar wind, which expands radially from the Sun at supersonic speed, blows a cavity - the heliosphere - into the surrounding interstellar cloud, filling it with solar material and magnetic field. The plasma component of the interstellar gas is kept outside the heliosphere.

By balancing the solar wind ram pressure, which is easily measured, against the pressure of the surrounding cloud, the size and shape of the heliosphere is determined.

With the new consensus set of interstellar helium parameters, its density, temperature, flow direction and speed relative to the Sun, the interstellar pressure can now be computed more reliably and the roughly 100 AU size of the heliosphere more accurately determined.

Because the Sun's motion relative to the surrounding gas, an interstellar breeze of neutral atoms blows through the heliosphere, very much like the wind felt when driving an open car.

Only very close to the Sun is the neutral gas ionized by the Sun's UV light and the by the solar wind, which leads to a small cavity in the neutral gas, roughly of several AU in size.

Except for hydrogen, which is affected by radiation pressure, the Sun's gravity deflects the neutral gas flow, leading to a concentration of neutral gas density in the direction opposite to inflow direction of the gas.

The resulting flow pattern is shown in Figure 1 for helium. It is this flow pattern that is analyzed to derive the flow speed, its direction, and temperature.

Helium, the second most abundant element after hydrogen, distinguishes itself by infiltrating closest to the Sun, to distances even inside the Earth's orbit.

Furthermore, because its density, temperature, and speed are not affected by processes at the heliospheric boundary, analysis of the properties of the helium gas inside the heliosphere allows one to establish the state of the pristine interstellar medium.

Since the late 1990's various instruments on a fleet of spacecraft have provided observations of interstellar helium. These observations are depicted schematically in Figure 1:

For detailed charts and digrams

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