For future communications work, particularly with satellites at longer ranges, it would seem to be preferable to use stiffer, flatter mirrors and to make them from beryllium rather than aluminum alloy. More accurate tracking means, more observatory sites, and more powerful telescopes will also be needed. But for this first experimental use our little mirrors have worked very well.

Jeofry S. Courtney-Pratt was born in Hobart, Tasmania, Australia, and received a Bachelor of Engineering degree from the University of Tasmania in 1942 and a Ph.D. from Cambridge University in 1949. He was also awarded an Sc.D. by Cambridge in 1958. He joined Bell Telephone Laboratories in 1958, and has done research in high-speed photography, optics, optical masers, the properties of materials, and the physics of the contact of solids.

CASE HISTORY NO. 4
How Do We Keep Solar Cell Power Plants Working in Space?

Kenneth D. Smith
Electronics Engineer—Member of Staff, Semiconductor Device Laboratory

THE PROBLEM

Before we learned about the Van Allen belts, we expected that the solar cells used to power satellites would last for many years in space. We thought they would be damaged only by cosmic rays, micrometeorites, and occasional bursts of particles from the sun. But when the solar plants of some American satellites went out of action after only a few weeks in orbit, we realized that in the future solar cell power units would need better protection from radiation damage. We had learned that satellites—and particularly medium altitude communications satellites—must spend a lot of time in regions where they will be struck by thousands or even millions of high-speed radiation particles each second.

This fact forced us to change almost all our thinking about solar power plants for satellites. To make sure they would last for several years, we had to design new types of solar cells and devise new ways of mounting them. We also had to revise our estimates of how much power we could expect to get from our cells.

If a communications satellite is to go into regular commercial service, it must continue working for several years in space. The Telstar satellite, however, was designed as an experimental project, and we decided that two years would be a reasonable lifetime to plan for. When Project Telstar began, our problem was to develop solar cells that would operate in an environment subject to strong radiation effects—and keep on operating there for two years.