Nuclear propulsion includes a wide variety of propulsion methods that fulfill the promise of the Atomic Age by using some form of nuclear reaction as their primary power source. The idea of using nuclear material for propulsion dates back to the beginning of the 20th century. In 1903 it was hypothesised that radioactive material, radium, might be a suitable fuel for engines to propel cars, boats, and planes. H. G. Wells picked up this idea in his 1914 fiction work The World Set Free.
Surface ships, submarines, and torpedoes
Nuclear-powered vessels are mainly military submarines, and aircraft carriers. Russia and America are the only countries that currently have nuclear-powered civilian surface ships, including icebreakers
and Aircraft carriers. America currently (as of July 2018) has 11
Aircraft carriers in service, and all are powered by nuclear reactors.
They use nuclear reactors as their power plants.
Civilian maritime use
- Nuclear marine propulsion for civil use
- List of civilian nuclear ships
Military maritime use
Torpedo
Russia's Channel One Television news broadcast a picture and details of a nuclear-powered torpedo called Status-6
on about 12 November 2015. The torpedo was stated as having a range of
up to 10,000 km, a cruising speed of 100 knots, and operational depth of
up to 1000 metres below the surface. The torpedo carried a 100-megaton
nuclear warhead.
One of the suggestions emerging in the summer of 1958 from the first meeting of the scientific advisory group that became JASON was for "a nuclear-powered torpedo that could roam the seas almost indefinitely".
Aircraft and missiles
Research into nuclear-powered aircraft was pursued during the Cold War by the United States and the Soviet Union
as they would presumably allow a country to keep nuclear bombers in the
air for extremely long periods of time, a useful tactic for nuclear deterrence.
Neither country created any operational nuclear aircraft. One design
problem, never adequately solved, was the need for heavy shielding to
protect the crew from radiation sickness. Since the advent of ICBMs
in the 1960s the tactical advantage of such aircraft was greatly
diminished and respective projects were cancelled. Because the
technology was inherently dangerous it was not considered in
non-military contexts. Nuclear-powered missiles were also researched and
discounted during the same period.
Aircraft
- Convair X-6
- Myasishchev M-50 - Aviation Week hoax
- Aircraft Nuclear Propulsion - General Electric's project to build a nuclear-powered bomber
- Tupolev Tu-95LAL
Missiles
- Project Pluto - which developed the SLAM missile, that used a nuclear-powered air ramjet for propulsion
- Burevestnik nuclear-powered cruise missile announced by Vladimir Putin in 2018 .
Spacecraft
Many types of nuclear propulsion have been proposed, and some of them (e.g. NERVA) tested for spacecraft applications.Nuclear pulse propulsion
- Project Orion, first engineering design study of nuclear pulse (i.e., atomic explosion) propulsion
- Project Daedalus, 1970s British Interplanetary Society study of a fusion rocket
- Project Longshot, US Naval Academy-NASA nuclear pulse propulsion design
- AIMStar, a proposed Antimatter-catalyzed nuclear pulse propulsion craft that uses clouds of antiprotons to initiate fission and fusion within fuel pellets
- ICAN-II, a proposed manned interplanetary spacecraft that used the Antimatter-catalyzed nuclear pulse propulsion engine as its main form of propulsion
- External Pulsed Plasma Propulsion (EPPP), a propulsion concept by NASA that derives its thrust from plasma waves generated from a series of small, supercritical fission/fusion pulses behind an object in space.
Nuclear thermal rocket
- Bimodal Nuclear Thermal Rockets conduct nuclear fission reactions similar to those safely employed at nuclear power plants including submarines. The energy is used to heat the liquid hydrogen propellant. Advocates of nuclear-powered spacecraft point out that at the time of launch, there is almost no radiation released from the nuclear reactors. The nuclear-powered rockets are not used to lift off the Earth. Nuclear thermal rockets can provide great performance advantages compared to chemical propulsion systems. Nuclear power sources could also be used to provide the spacecraft with electrical power for operations and scientific instrumentation.
- NERVA - NASA's Nuclear Energy for Rocket Vehicle Applications, a US nuclear thermal rocket program
- Project Rover - an American project to develop a nuclear thermal rocket. The program ran at the Los Alamos Scientific Laboratory from 1955 through 1972.
- Project Timberwind 1987-1991
Ramjet
- Bussard ramjet, a conceptual interstellar fusion ramjet named after Robert W. Bussard.
Direct nuclear
- Fission fragment rocket
- Fission sail
- Fusion rocket
- Gas core reactor rocket
- Nuclear salt-water rocket
- Radioisotope rocket
- Nuclear photonic rocket
Nuclear electric
- Nuclear electric rocket
- Project Prometheus, NASA development of nuclear propulsion for long-duration spaceflight, begun in 2003
Russian Federal Space Agency development
Anatolij Perminov, head of the Russian Federal Space Agency, announced that it is going to develop a nuclear-powered spacecraft for deep space travel.
Preliminary design was done by 2013, and 9 more years are planned for
development (in space assembly). The price is set at 17 billion rubles
(600 million dollars).
The nuclear propulsion would have mega-watt class, provided necessary funding, Roscosmos Head stated.
This system would consist of a space nuclear power and a matrix
of ion engines.
...hot inert gas temperature of 1500 °C from the reactor turns turbines. The turbine turns the generator and compressor, which circulates the working fluid in a closed circuit. The working fluid is cooled in the radiator. The generator produces electricity for the same ion (plasma) engine...
According to him, the propulsion will be able to support human mission to Mars,
with cosmonauts staying on the Red planet for 30 days. This journey to
Mars with nuclear propulsion and a steady acceleration would take six
weeks, instead of eight months by using chemical propulsion – assuming
thrust of 300 times higher than that of chemical propulsion.
Vehicles
Cars
The idea of making cars that used radioactive material, radium,
for fuel dates back to at least 1903. Analysis of the concept in 1937
indicated that the driver of such a vehicle might need a 50-ton lead barrier to shield them from radiation.
In 1941 Dr R M Langer, a Caltech physicist, espoused the idea of a car powered by uranium-235 in the January edition of Popular Mechanics. He was followed by William Bushnell Stout, designer of the Stout Scarab and former Society of Engineers president, on 7 August 1945 in the New York Times. The problem of shielding the reactor continued to render the idea impractical.
In December 1945, a John Wilson of London, announced he had created an
atomic car. This created considerable interest. The Minister of Fuel and
Power along with a large press contingent turned out to view it. The
car did not show and Wilson claimed that it had been sabotaged. A later
court case found that he was a fraud and there was no nuclear-powered
car.
Despite the shielding problem, through the late 1940s and early
1950s debate continued around the possibility of nuclear-powered cars.
The development of nuclear-powered submarines and ships, and experiments
to develop a nuclear-powered aircraft at that time kept the idea alive.
Russian papers in the mid-1950s reported the development of a
nuclear-powered car by Professor V P Romadin, but again shielding proved
to be a problem. It was claimed that its laboratories had overcome the shielding problem with a new alloy that absorbed the rays.
In 1958 at the height of the 1950s American automobile culture there were at least four theoretical nuclear-powered concept cars proposed, the American Ford Nucleon and Studebaker Packard Astral, as well as the French Simca Fulgur designed by Robert Opron and the Arbel Symetric. Apart from these concept models, none were built and no automotive nuclear power plants ever made. Chrysler
engineer C R Lewis had discounted the idea in 1957 because of estimates
that an 80,000 lb (36,000 kg) engine would be required by a 3,000 lb
(1,400 kg) car. His view was that an efficient means of storing energy
was required for nuclear power to be practical. Despite this, Chrysler's stylists in 1958 drew up some possible designs.
In 1959 it was reported that Goodyear Tire and Rubber Company had developed a new rubber
compound that was light and absorbed radiation, obviating the need for
heavy shielding. A reporter at the time considered it might make
nuclear-powered cars and aircraft a possibility.
Ford made another potentially nuclear-powered model in 1962 for the Seattle World's Fair, the Ford Seattle-ite XXI. This also never went beyond the initial concept.
In 2009, for the hundredth anniversary of General Motors' acquisition of Cadillac, Loren Kulesus created concept art depicting a car powered by thorium.
Other
The Chrysler TV-8 was an experimental concept tank designed by Chrysler in the 1950s. The tank was intended to be a nuclear-powered medium tank capable of land and amphibious warfare. The design was never mass-produced. The Mars rover Curiosity is powered by a radioisotope thermoelectric generator (RTG), like the successful Viking 1 and Viking 2 Mars landers in 1976.