A space gun, sometimes called a Verne gun because of its appearance in From the Earth to the Moon by Jules Verne, is a method of launching an object into space using a large gun- or cannonlike structure. Space guns could thus potentially provide a method of non-rocket spacelaunch. It has been conjectured that space guns could place satellites into Earth's orbit (although after-launch propulsion of the satellite would be necessary to achieve a stable orbit), and could also launch spacecraft beyond Earth's gravitational pull and into other parts of the Solar System by exceeding Earth's escape velocity of about 11.2 km/s or 40,320 km/h (25,050 mph). However, these speeds are too far into the hypersonic range for most practical propulsion systems and also would cause most objects to burn up due to aerodynamic heating or be torn apart by aerodynamic drag. Therefore, a more likely future use of space guns would be to launch objects into near Earth orbit, from where attached rockets could be fired or the objects could be "collected" by maneuverable orbiting satellites.

In Project HARP, a 1960s joint United States and Canada defence project, a U.S. Navy 16 in (410 mm) 100 caliber gun was used to fire a 180 kg (400 lb) projectile at 3600 m/s or 12,960 km/h (8,050 mph), reaching an apogee of 180 km (110 mi), hence performing a suborbital spaceflight. However, a space gun has never been successfully used to launch an object into orbit or out of Earth's gravitational pull.

Technical issues

The large g-force likely to be experienced by a ballistic projectile launched in this manner would mean that a space gun would be incapable of safely launching humans or delicate instruments, rather being restricted to freight, fuel or ruggedized satellites.

Atmospheric drag also makes it more difficult to control the trajectory of any projectile launched, as it would subject the projectile to extremely high counter-pressures, and likely would cause severe energy losses that would be difficult to overcome.
Getting to orbit

A space gun by itself is not capable of placing objects into stable orbit around the object (planet or otherwise) from which it launches them. The laws of two-body gravitation make it impossible to reach a stable orbit without an active (kinetic) payload propulsion process which would perform orbital correction/stabilization burns or tether momentum exchange to change the shape of its orbit after launch. The orbit is a parabolic orbit, a hyperbolic orbit, or part of an elliptic orbit which ends at the planet's surface at the point of launch or another point. This means that an uncorrected ballistic payload will always strike the planet within its first orbit unless the velocity was so high as to reach or exceed escape velocity.
Conceptual drawing of balloon-supported space gun that could be raised to heights of many miles

Isaac Newton avoided this objection in his thought experiment by positing an impossibly tall mountain from which his cannon was fired. If in a stable orbit, the projectile, however, would still tend to circle the planet and strike the point of launch (see Newton's cannonball).[1][2]

As a result, all payloads intended to reach a closed orbit need at least to perform some sort of course correction to create another orbit that does not intersect the planet's surface. A rocket can be used for additional boost as planned in both Project HARP and the Quicklaunch project. The magnitude of such may be small; for instance, the StarTram Generation 1 reference design involves a total of 0.6 km/s of rocket burn to raise perigee well above the atmosphere when entering an 8 km/s Low Earth Orbit.[3]

In a three-body or larger system, a gravity assist trajectory might be available such that a carefully aimed escape velocity projectile would have its trajectory modified by the gravitational fields of other bodies in the system such that the projectile would eventually return to orbit the initial planet using only the launch delta-v.[4][5]

A space gun with a "gun barrel" of length (l), and the needed velocity (v_e), the acceleration (a) is provided by the following formula:

a = \frac{v_e^2}{2l}

For instance, with a space gun with a vertical "gun barrel" through both the Earth's crust and the troposphere, totalling ~60 km of length (l), and a velocity (v_e) enough to escape the Earth's gravity (escape velocity, which is 11.2 km/s on Earth), the acceleration (a) would theoretically be more than 1000 m/s2, which is more than 100 g-forces, which is about 3 times the human tolerance to g-forces of maximum 20 to 35 g[6] during the ~10 seconds such a firing would take. Theoretically, a space gun with a circular (ring shaped) track could utilize much lower accelerations because its effective track length is infinite (with the object going around the ring numerous times), though the centripetal acceleration could be enormous as the payload neared escape velocity, depending on the track size.
Practical attempts
Two sections of the Project Babylon gun
Project HARP, a prototype of a space gun.

The German V-3 cannon program (less well known than the V-2 rocket or V-1 flying bomb), during the Second World War was an attempt to build something approaching a space gun. Based in the Pas-de-Calais area of France it was planned to be more devastating than the other Nazi 'Vengeance weapons'. It was destroyed by RAF bombing using Tallboy blockbuster bombs in July 1944.[7]

On the practical side, the most prominent recent attempt to make a space gun was artillery engineer Gerald Bull's Project Babylon, which was also known as the 'Iraqi supergun' by the media. During Project Babylon, Bull used his experience from Project HARP to build a massive cannon for Saddam Hussein, leader of Ba'athist Iraq. Bull was assassinated before the project was completed.
Super High Altitude Research Project

Since Bull's death, few have seriously attempted to build a space gun. Perhaps most promisingly, the US Ballistic Missile Defense program sponsored the Super High Altitude Research Project (SHARP) in the 1980s. Developed at Lawrence Livermore Laboratory, it is a light-gas gun and has been used to test fire objects at Mach 9.

After cancellation of SHARP, lead developers John Hunter founded the Jules Verne Launcher Company in 1996 and the Quicklaunch company. As of September 2012, Quicklaunch was seeking to raise $500 million to build a gun that could refuel a propellant depot or send bulk materials into space.[8][9][10]

Ram accelerators have also been proposed as an alternative to light-gas guns. Other proposals use electromagnetic techniques for accelerating the payload, such as coilguns and railguns.
In fiction
The firing of a space gun in Jules Verne's From the Earth to the Moon

The first publication of the concept may be Newton's cannonball in the 1728 book A Treatise of the System of the World, although it was primarily used as a thought experiment regarding gravity.[11]

Perhaps the most famous representation of a space gun is in Jules Verne's novel, From the Earth to the Moon (loosely interpreted into the early film Le Voyage dans la Lune), in which astronauts fly to the moon aboard a ship launched from a cannon. Another famous example is the hydrogen accelerator cannon used by the Martians to launch their invasion in H. G. Wells' book The War of the Worlds. Wells also used the concept in the climax of the 1936 movie Things to Come. The device was featured in films as late as 1967, such as Jules Verne's Rocket to the Moon.

In the video game Ultima: Worlds of Adventure 2: Martian Dreams, Percival Lowell builds a space gun to send a spacecraft to Mars.

The 2015 video game "SOMA", features a space gun used to launch satellites.

Gerald Bull's assassination and the Project Babylon gun were also the starting point for Frederick Forsyth's 1994 novel The Fist of God. In Larry Bond's 2001 novella and 2015 novel Lash-Up, China uses a space gun to destroy American GPS satellites.
See also
Portal icon Spaceflight portal

Newton's cannonball
Space elevator
Launch loop
Space fountain
Tether propulsion
Non-rocket spacelaunch


Newton, Isaac (1728). A Treatise of the System of the World. F. Fayram. pp. 6–12.
Newton's cannonball
"StarTram2010: Maglev Launch: Ultra Low Cost Ultra High Volume Access to Space for Cargo and Humans". Retrieved April 28, 2011.
Clarke, Victor C., Jr. (1970-04-10). "An Essay On the Application and Principle of Gravity-Assist Trajectories For Space Flight" (PDF). Jet Propulsion Laboratory, California Institute of Technology: 7. Retrieved 2013-08-13. "By induction then, it is obvious that the process of diverting a spacecraft from one planet to another might be continued indefinitely, if the planets were in favorable positions."
Minovitch, Michael (August 23, 1961). "A Method For Determining Interplanetary Free-Fall Reconnaissance Trajectories" (PDF). Jet Propulsion Laboratory Technical Memos (TM-312-130): 38–44.
Anton Sukup (1977). "David PURLEY Silverstone crash". Retrieved July 31, 2006.
RAF staff (6 April 2005). "RAF History - Bomber Command 60th Anniversary". Bomber Command: Campaign Diary. RAF. Archived from the original on 6 July 2007. Retrieved 23 October 2013.
"". Retrieved November 11, 2011.
"Jules Verne Launcher Company Concept". Retrieved November 11, 2011.
"A Cannon for Shooting Supplies into Space". Retrieved November 11, 2011. > [4.0 Space Guns] v1.1.4 / chapter 4 of 7 / 01 jun 08 / greg goebel / public domain

External links

FAS space gun page
The 150 Kiloton Nuclear Verne Gun

Space Encyclopedia

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