Early Space Exploration

Lesson Objectives

  • Explain how a rocket works.
  • Describe different types of satellites.
  • Outline major events in early space exploration, including the Space Race.

Vocabulary

  • low Earth orbit
  • orbit
  • rocket
  • satellite
  • space probe
  • thrust

Introduction

Humans have long dreamed of traveling into space. Greek mythology tells of Daedelus and Icarus, a father and son who took flight using wings made of feathers and wax (Figure below). Icarus, thrilled with the feel of flying, got too close to the Sun, the wax melted, and he fell into the sea. In a time before airplanes and hot air balloons, we can relate to the excitement Icarus would have felt. Much later, science fiction writers, such as Jules Verne (1828–1905) and H.G. Wells (1866–1946), wrote about technologies that explore the dream of traveling beyond Earth into space.

Daedelus and Icarus.

Rockets

Humans did not reach space until the second half of the 20th century. However, the main technology that makes space exploration possible, the rocket, has been around for a long time. A rocket is propelled by particles flying out of one end at high speed. We do not know who built the first rocket, or when, but there are records of the Chinese using rockets in war against the Mongols as early as the 13th century. The Mongols then spread rocket technology in their attacks on Eastern Europe. Early rockets were also used to launch fireworks and for other ceremonial purposes.

How Rockets Work

Rockets were used for centuries before anyone could explain exactly how they worked. The theory to explain rockets did not arrive until 1687, when Isaac Newton (1643–1727) described the three basic laws of motion, now referred to as Newton’s Laws of Motion:

  1. An object in motion will remain in motion unless acted upon by a net force.
  2. Force equals mass multiplied by acceleration.
  3. To every action, there is an equal and opposite reaction.

Newton’s third law of motion is particularly useful in explaining how a rocket works. To better understand this law, consider the skate boarder in (Figure below).

When the skate boarder pushes the wall, his force – the action – is matched by an equal force by the wall on the skate boarder in the opposite direction – the reaction.

Once the skate boarder is moving, however, he has nothing to push against and he will soon stop because of friction. Imagine now that he is is holding a fire extinguisher. When he pulls the trigger on the extinguisher, a fluid or powder flies out of the extinguisher, and he moves backward. In this case, the action force is the pressure pushing the material out of the extinguisher. The reaction force of the material against the extinguisher pushes the skate boarder backward.

Since space is a vacuum, how does a rocket work if there is nothing for the rocket to push against? A rocket in space moves like the skater holding the fire extinguisher. Fuel is ignited in a chamber, which causes an explosion of gases. The explosion creates pressure that forces the gases out of the rocket. As these gases rush out the end, the rocket moves in the opposite direction, as predicted by Newton’s Third Law of Motion (Figure below). The reaction force of the gases on the rocket pushes the rocket forward. The force pushing the rocket is called thrust.

Explosions in a chamber create pressure that pushes gases out of a rocket. This in turn produces thrust that pushes the rocket forward. The rocket shown here is a Saturn V rocket, used for the Apollo 11 mission – the first to carry humans to the Moon.

A Rocket Revolution

For centuries, rockets were powered by gunpowder or other solid fuels and could travel only fairly short distances. At the end of the 19th century and the beginning of the 20th century, several breakthroughs in rocketry led to rockets that were powerful enough to carry the rockets—and humans—beyond Earth. During this period, three people independently came up with similar ideas for improving rocket design.

The first person to establish many of the main ideas of modern rocketry was a Russian schoolteacher, named Konstantin Tsiolkovsky (1857–1935). Most of his work was done before the first airplane flight, which took place in 1903. Tsiolkovsky realized that in order for rockets to have enough power to escape Earth’s gravity, they would need liquid fuel instead of solid fuel. He also realized that it was important to find the right balance between the amount of fuel a rocket uses and how heavy the rocket is. He came up with the idea of using multiple stages when launching rockets, so that empty fuel containers would drop away to reduce mass. Tsiolkovsky had many great ideas and designed many rockets, but he never built one.

The second great rocket pioneer was an American, Robert Goddard (1882–1945). Goddard independently came up with using liquid fuel and using multiple stages for rockets. He also designed a system for cooling the gases escaping from a rocket, which made the rocket much more efficient. Goddard built rockets to test his ideas, such as the first rocket to use liquid fuel (Figure below). Over a lifetime of research, Goddard came up with many innovations that are still used in rockets today.

Left: Robert Goddard launched the first liquid-fueled rocket on March 16, 1926, in Massachusetts; Right: This schematic shows details of Goddard’s rocket.

The third great pioneer of rocket science was a Romanian-born German, named Hermann Oberth (1894–1989). In the early 1920’s, Oberth came up with many of the same ideas as Tsiolkovsky and Goddard. Oberth built a liquid-fueled rocket, which he launched in 1929. Later, he joined a team of scientists that designed the rocket shown in (Figure below) for the German military. This rocket played a major role in World War II. The Germans used the V-2 as a missile to bomb numerous targets in Belgium, England, and France. In 1942, the V-2 was launched to an altitude of 176 km (109 miles), making it the first human-made object to travel into space (an altitude of 100 km (62 miles).

Explosions in a chamber create pressure that pushes gases out of the rocket. This in turn produces thrust that pushes the rocket forward.

The leader of the V-2 team was a German scientist named Wernher von Braun. von Braun later fled Germany and came to the United States, where he helped the United States develop missile weapons. He then joined NASA to design rockets for space travel including the Saturn V rocket (Figure below), which was eventually used to send the first men to the Moon.

Wernher von Braun in front of the F1 engines in front of the Saturn V rocket’s first stage.

Satellites

One of the first uses of rockets in space was to launch satellites. A satellite is an object that orbits a larger object. An orbit is a circular or elliptical path around an object. The Moon was Earth’s first satellite, but now many human-made artificial satellites orbit the planet.

Newton’s Law of Universal Gravitation

Isaac Newton also developed the theory that explains why satellites stay in orbit. Newton’s law of universal gravitation describes how every object in the universe is attracted to every other object. The same gravity that makes an apple fall to the ground and keeps a person from floating away into the sky, also holds the Moon in orbit around Earth, and Earth in orbit around the Sun.

Newton used the following example to explain how gravity makes orbits possible. Consider a cannonball launched from a high mountain (Figure below).

If a cannonball is launched off a high mountain at a slow speed, it will fall back to Earth (A, B) If the cannonball is launched at a fast enough speed, the Earth below curves away at the same rate that the cannonball falls, and the cannonball goes into a circular orbit (C). If the cannonball is launched even faster, it goes into an elliptical orbit (D) or leaves Earth’s gravity entirely (E).

Not that Newton’s idea would actually work in real life: A cannonball launched from Mt. Everest would burn up in the atmosphere if launched at the speed required to put it into orbit. However, a rocket can launch straight up, then steer into an orbit. A rocket can also carry a satellite above the atmosphere and then release the satellite into orbit.

To further understand how satellites work, visit http://science.howstuffworks.com/satellite.htm.

Types of Satellites

Since the first satellite was launched more than 50 years ago, thousands of artificial satellites have been put into orbit around Earth. We have even put satellites into orbit around the Moon, the Sun, Venus, Mars, Jupiter, and Saturn. There are four main types of satellites.

  • Imaging satellites take pictures of Earth’s surface to be used by the military, when taken by spy satellites; or for scientific purposes, such as meteorology, if taken by weather satellites. Astronomers use imaging satellites to study the Moon and other planets.
  • Communications satellites, such as the one in (Figure below), are designed to receive and send signals for telephone, television, or other types of communications.
  • Navigational satellites are used for navigation systems, such as the Global Positioning System (GPS).
  • The International Space Station, the largest artificial satellite is designed for humans to live in space while conducting scientific research.

This is a Milstar communications satellite used by the U.S. military. The long, flat solar panels provide power for the satellite. The antennas are for sending or receiving signals.

Types of Orbits

The speed of a satellite depends on how high it is above the object it is orbiting (Figure below). Satellites that are relatively close to Earth are said to be in low Earth orbit (LEO). Satellites in LEO are often in polar orbit; they orbit over the North and South Poles, perpendicular to Earth’s spin. Because Earth rotates underneath the orbiting satellite, a satellite in polar orbit is over a different part of Earth’s surface each time it circles. Imaging satellites and weather satellites are often put in low-Earth, polar orbits.

Different orbits of Earth: ISS orbit = red dotted line; LEO = filled blue; Medium Earth Orbit = filled yellow; GPS = green dash-dot; geostationary = black dash.

An animation of GPS satellites orbiting Earth is seen here: http://en.wikipedia.org/wiki/File:ConstellationGPS.gif

An animation of roughly half the orbit of the ISS from sunrise to sunset: http://en.wikipedia.org/wiki/File:Sunrise_To_Sunset_Aboard_The_ISS.OGG

A satellite placed at just the right distance above Earth — 35,786 km (22,240 miles) — orbits at the same rate that Earth spins. The satellite is always in the same position over Earth’s surface, called a geostationary orbit (GEO). Many communications satellites are in geostationary orbits.

The Space Race

From the end of World War II in 1945 to the breakup of the Soviet Union (USSR) in 1991, the Soviet Union and the United States were in a military, social, and political conflict, known as the Cold War. Although there were very few actual military confrontations, each of the two countries was in an arms race — continually developing new and more powerful weapons to try to best the other. While the arms race had many social and political consequences, it helped to drive technology. For example, the development of missiles during the Cold War significantly sped up the development of rocket technologies.

More information about the Space Race can be found at http://www.nasm.si.edu/exhibitions/gal114/gal114.htm.

Sputnik

On October 4, 1957, the USSR launched the first artificial satellite ever put into orbit. Sputnik 1 (Figure below) was 58 cm in diameter and weighed 84 kg (184 lb). Antennas trailing behind the satellite sent out radio signals, which were detected by scientists and amateur radio operators around the world. Sputnik 1 orbited in an LEO on an elliptical path every 96 minutes. After about 3 months, the satellite slowed down enough to descend into Earth’s atmosphere where it burned up as a result of friction.

The Soviet Union launched Sputnik 1, the first artificial satellite, on October 4, 1957.

The launch of Sputnik 1 triggered the Space Race between the USSR and the United States. Many Americans were shocked that the Soviets had the technology to put a satellite in orbit, and they worried that the Soviets might also be winning the arms race. On November 3, 1957, the Soviets launched Sputnik 2, which carried the first animal to go into orbit—a dog named Laika (Figure below).

Laika was a stray trained for space flight. No one yet knew how to bring a satellite out of orbit and Laika was not expected to survive the flight.

The Race Is On

In response to the Sputnik program, the United States launched its first satellite, Explorer I, on January 31, 1958, and its second, Vanguard 1, on March 17, 1958. Later that year, the U.S. Congress and President Eisenhower established NASA.

The Soviets stayed ahead of the United States for many notable “firsts,” but the United States soon followed with some firsts of its own. The timeline in Table below shows many Space Race firsts.

Space Race Timeline
Date Accomplished Country Name of Mission
October 4, 1957 First artificial satellite, first signals from space USSR Sputnik 1
November 3, 1957 First animal in orbit (the dog Laika) USSR Sputnik 2
January 31, 1958 USA’s first artificial satellite USA Explorer 1
January 4, 1959 First human-made object to orbit the Sun USSR Luna 1
September 13, 1959 First impact into another planet or moon (the Moon) USSR Luna 2
April 12, 1961 First manned spaceflight and first manned orbital flight (Yuri Gagarin) USSR Vostok 1
May 5, 1961 USA’s first spaceflight with humans (Alan Shepherd) USA Mercury-Redstone 3 (Freedom 7)
February 20, 1962 USA’s first orbital flight with humans (John Glenn) USA Mercury-Atlas 6 (Friendship 7)
December 14, 1962 First planetary flyby (Venus) USA Mariner 2
June 16, 1963 First woman in space, first woman in orbit (Valentina Tereshkova) USSR Vostok 6
March 18, 1965 First extra-vehicular activity (“spacewalk”) (Aleksei Leonov) USSR Voskhod 2
February 3, 1966 First soft landing on another planet or moon (the Moon), first photos from another world USSR Luna 9
March 1, 1966 First impact into another planet (Venus) USSR Venera 3
April 3, 1966 First artificial satellite around another world (the Moon) USSR Luna 10
June 2, 1966 USA’s first soft landing on the Moon, USA’s first photos from the Moon USA Surveyor 1
December 21, 1968 First humans to orbit another world (the Moon) (James Lovell, Frank Borman, Bill Anders) USA Apollo 8
July 21, 1969 First humans on the Moon (Neil Armstrong, Buzz Aldrin) USA Apollo 11

The Space Race reached a peak in 1969 when the United States put the first human on the Moon. However, the competition between the two countries’ space programs continued for many more years.

Reaching the Moon

On May 25, 1961, shortly after the first American went into space, President John F. Kennedy presented the following challenge to the U.S. Congress (Figure below):

“I believe that this nation should commit itself to achieving the goal, before this decade is out, of landing a man on the Moon and returning him back safely to the Earth. No single space project in this period will be more impressive to mankind, or more important for the long-range exploration of space; and none will be so difficult or expensive to accomplish.”

Eight years later, NASA’s Apollo 11 mission achieved Kennedy’s ambitious goal. On July 20, 1969, astronauts Neil Armstrong and Buzz Aldrin were the first humans to set foot on the moon (Figure below).

Neil Armstrong took this photo of Buzz Aldrin on the Moon during the Apollo 11 mission. Armstrong and the Lunar Module can be seen in the reflection in Aldrin’s helmet.

Following the Apollo 11 mission, four other American missions successfully put astronauts on the Moon. The last manned mission to the moon was Apollo 17, which landed on December 11, 1972. To date, no other country has put a person on the Moon.

In July 1975, the USSR and the United States carried out a joint mission called the Apollo-Soyuz Test Project. During the mission, an American Apollo spacecraft docked with a Soviet Soyuz spacecraft (Figure below).

The docking of an Apollo spacecraft with a Soyuz spacecraft in 1975. Many considered this to be the symbolic end of the Space Race.

Exploring Other Planets

Both the United States and the USSR sent probes to other planets during the Space Race. A space probe is a an unmanned spacecraft that is sent to collect data by flying near or landing on an object in space, such as a planet, moon, asteroid, or comet. During the Venera missions, the USSR sent several probes to Venus, including some that landed on the surface. The United States sent probes to Mercury, Venus, and Mars in the Mariner missions (Figure below), and landed two probes on Mars in the Viking missions.

Data from Mariner 10 was used to create this image of Mercury.

In the Pioneer and Voyager missions, the United States also sent probes to the outer solar system, including flybys of Jupiter, Saturn, Uranus, and Neptune. The Pioneer and Voyager probes are still traveling, and are now beyond the edges of our solar system. We have lost contact with the two Pioneer probes, but expect to have contact with the two Voyager probes until at least 2020 (Figure below).

A portrait of the solar system more than 4 billion miles from Earth was taken by Voyager I. The pale blue dot halfway down the brown band on the right side is Earth.

As of late 2012, Voyager 1 was about 11 billion miles from Earth. The spacecraft was about to leave the Sun’s influence and enter interstellar space.

Lesson Summary

  • Rockets have been used for warfare and ceremonies for many centuries.
  • Newton’s third law explains how a rocket works. The action force of the engine on the gases is accompanied by a reaction force of the gases on the rocket.
  • Konstantin Tsiolkovsky, Robert Goddard, and Hermann Oberthall came up with similar ideas for improving rocket design, such as using liquid fuel and multiple stages.
  • A satellite orbits a larger object. Moons are natural satellites; humans make artificial satellites.
  • Newton’s law of universal gravitation explains how satellites enter an orbit.
  • Artificial satellites are used for imaging planets, for navigation, and for communication.
  • The launch of Sputnik 1 started a Space Race between the United States and the USSR.
  • The United States’ Apollo 11 mission put the first humans on the Moon.
  • The United States and USSR sent several probes to other planets during the Space Race.

Review Questions

  1. Use Newton’s third law to explain how a rocket moves.
  2. List the three great pioneers of rocket science and their contributions.
  3. What is the difference between a rocket and a satellite? How are they related?
  4. What is the name of Earth’s natural satellite?
  5. Explain why a satellite in polar orbit can take pictures of all parts of the Earth over time.
  6. Describe three different types of orbits.
  7. What event launched the Space Race?
  8. What goal did John F. Kennedy set for the United States in the Space Race?
  9. What are the advantages of a multi-stage rocket instead of a single-stage rocket?

Further Reading / Supplemental Links

  • In Wikipedia, www.wikipedia.org: Hermann_Oberth; Wernher_von_Braun; V-2_rocket; Satellites; Natural_satellite; Newton_cannonball; Sputnik_1; Sputnik_program; Space_Race; Cold_War; John_F._Kennedy; Apollo_program; List_of_planetary_probes.
  • A history of lunar exploration: http://nssdc.gsfc.nasa.gov/planetary/lunar/apollo_25th.html

Points to Consider

  • The Space Race and the United State’s desire to get to the Moon brought about many advances in science and technology. Can you think of any challenges we face today that are, could be, or should be a focus of science and technology?
  • If you were in charge of NASA, what new goals would you set for space exploration?
  • Do you think that a space program is a good use of government funding?