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| | == being upturned neck point sleepy == |
| [[File:NASA-project-orion-artist.jpg|thumb|right|An artist's conception of the NASA reference design for the Project Orion spacecraft powered by nuclear propulsion.]]
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| '''Project Orion''' was a study of a [[spacecraft]] intended to be directly propelled by a series of explosions of [[nuclear weapon|atomic bombs]] behind the craft ([[nuclear pulse propulsion]]). Early versions of this vehicle were proposed to take off from the ground with significant associated [[nuclear fallout]]; later versions were presented for use only in space.
| | The terminal, looking for a long time before the rest of the pick-up [http://www.dmwai.com/webalizer/kate-spade-11.html ケイトスペード 財布 通販] to see the body's unique Li Mei, already looks like a tired, with hair disheveled, being upturned neck point sleepy, Xiaomeng Qi come near before seen , a long lie down on a [http://www.dmwai.com/webalizer/kate-spade-10.html ケイトスペード バッグ ショルダー] chair, who is not more than sin.<br><br>apology [http://www.dmwai.com/webalizer/kate-spade-1.html kate spade トートバッグ] thicker, regardless of what it was like xing grid, which served as [http://www.dmwai.com/webalizer/kate-spade-14.html kate spade マザーズバッグ] the curse of the same body jing, wear it will suffer from similar symptoms of obsessive-compulsive disorder a class, always leave no stone unturned to find out the truth, always use make every effort to find the murderers.<br><br>She gently sit down with a shoulder against, let Li Mei head on to her shoulders, as if there is no female jing [http://www.dmwai.com/webalizer/kate-spade-6.html ケイトスペード バッグ 人気] congenital condition vase, jing team in general will be when men servants, Li Mei undoubtedly This class is really necessary, xing other conditions are not taken into account, watching Lydia tired face, Xiaomeng Qi want to do something, but unexpectedly suddenly awakened to Li Mei, she rubbed his sleepy eyes, punched yawn, Xiaomeng Qi stresses again and again I'm sorry.<br><br>'All right all right, anyway, sleep ...... Shaw place, even |
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| A 1955 [[Los Alamos Laboratory]] document states (without offering references) that general proposals were first made by [[Stanislaw Ulam]] in 1946, and that preliminary calculations were made by [[F. Reines]] and Ulam in a Los Alamos memorandum dated 1947.<ref>Everett, C.J.; Ulam S.M. On a Method of Propulsion of Projectiles by Means of External Nuclear Explosions. Part I. University of California, Los Alamos Scientific Laboratory, August 1955. See p. 5 [http://www.dtic.mil/cgi-bin/GetTRDoc?AD=ADA306631&Location=U2&doc=GetTRDoc.pdf] [http://www.webcitation.org/5uzTHJfF7 Archived]</ref> The actual project, initiated in 1958, was led by [[Ted Taylor (physicist)|Ted Taylor]] at [[General Atomics]] and physicist [[Freeman Dyson]], who at Taylor's request took a year away from the [[Institute for Advanced Study]] in [[Princeton, New Jersey|Princeton]] to work on the project.
| | == 'club certainly provide this occasion == |
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| The Orion concept offered high thrust and high [[specific impulse]], or propellant efficiency, at the same time. The unprecedented extreme power requirements for doing so would be met by nuclear explosions, of such power relative to the vehicle's mass as to be survived only by using external detonations without attempting to contain them in internal structures. As a qualitative comparison, traditional chemical rockets—such as the [[Saturn V]] that took the [[Apollo program]] to the Moon—produce high thrust with low specific impulse, whereas electric [[ion engine]]s produce a small amount of thrust very efficiently. Orion would have offered performance greater than the most advanced conventional or nuclear rocket engines then under consideration. Supporters of Project Orion felt that it had potential for cheap [[interplanetary travel]], but it lost political approval over concerns with fallout from its propulsion.<ref name="Cosmos by Carl Sagan">Cosmos by Carl Sagan</ref>
| | Xue Fei driving on.<br><br>'club certainly provide this occasion, [http://www.dmwai.com/webalizer/kate-spade-0.html ケイトスペード バッグ] but they [http://www.dmwai.com/webalizer/kate-spade-9.html kate spade 財布 ゴールド] sound good.' backseat [http://www.dmwai.com/webalizer/kate-spade-13.html ケイトスペード 人気バッグ] Lapa said.<br><br>'Oh, I really have not been.' I sin without blinking an eye lied.<br><br>'That guy, where you've been, or you pick one?' Xue Fei Tao, I sin-off with the Lord, [http://www.dmwai.com/webalizer/kate-spade-9.html ケイトスペード リボン バッグ] but such a clear sky, the way is still Zhunv curiosity aroused, three girl bite what ear said, chuckling again soon.<br><br>'few, what smile?' I asked the crime.<br><br>'We guess you are what capacity.' Xue Fei smile.<br><br>'guessed it? Tell me.' I sin asked.<br><br>'ah, producer ...... certainly filmmakers, otherwise Lanjie not so got the idea.' Xue Fei Road.<br><br>'wrong, who come.' I sin laughed.<br><br>'is the owner of it ...... there [http://www.dmwai.com/webalizer/kate-spade-12.html ケイトスペード ハンドバッグ] to see you this tie taste you know, the more low-key now more Tyrant ah.' Lapa envy authentic, Lanjie body |
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| The [[Partial Test Ban Treaty]] of 1963 is generally acknowledged to have ended the project. However, from [[Project Longshot]] to [[Project Daedalus]], [[Mini-Mag Orion]], and other proposals which reach engineering analysis at the level of considering thermal power dissipation, the principle of external [[nuclear pulse propulsion]] to maximize survivable power has remained common among serious concepts for interstellar flight without external power beaming and for very high-performance interplanetary flight. Such later proposals have tended to modify the basic principle by envisioning equipment driving detonation of much smaller fission or fusion pellets, although in contrast Project Orion's larger nuclear pulse units (nuclear bombs) were based on less speculative technology.
| | == do not inquire about Nima chaos.' I am sorry to say sin == |
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| ==Basic principles==
| | Shaoguan how much you know? Let's bigger than the provincial capital. 'Mouse can not do anything authentic.<br><br>'did not find ah, [http://www.dmwai.com/webalizer/kate-spade-10.html kate spade ハンドバッグ] mouse, you still feeling kind?' I teased crime.<br><br>'That was my first time, but also her first time, can not cherish it?' Mouse solemnly authentic.<br><br>'What first?' Sun Yi Coushang came, curiously asked, more than one crime Fuer Sun Yi laughed, his face was bared flowering, smiling mouse uncomfortable, [http://www.dmwai.com/webalizer/kate-spade-12.html ケイトスペード 財布 値段] counterassaulted Sun Yi Xun grabbed what he laughs Sun Yi said: 'I put the first run on the junior high school, you too outdated ...... Hey, I children, Shashi Hou do you drop?'<br><br>'secret police, do not inquire about Nima chaos.' I am sorry to say sin, pulling [http://www.dmwai.com/webalizer/kate-spade-13.html ケイトスペード ママバッグ] faces road.<br><br>I sin identity [http://www.dmwai.com/webalizer/kate-spade-6.html ケイトスペード 財布 セール] different now, but can not take this scare brothers, this outburst, two per vertical root middle finger poke straight to I sin. Incidentally an evaluation: 'you know you little ** hard up, sorry to say.'<br><br>took [http://www.dmwai.com/webalizer/kate-spade-5.html ケイトスペード バッグ 激安] off, this topic is broken, straight clouds night flights carrying away half |
| [[File:ProjectOrionConfiguration.png|thumb|upright=2.2|The Orion Spacecraft – key components.<ref>[http://ntrs.nasa.gov/archive/nasa/casi.ntrs.nasa.gov/19770085619_1977085619.pdf Nuclear Pulse Space Vehicle Study] Vol IV – Conceptual Vehicle Designs and Operational Systems, Fig 2.1, pp 4., NASA</ref>]] | | 相关的主题文章: |
| [[File:Orion pulse unit.png|thumb|upright=1.1|A design for a pulse unit.]] | | <ul> |
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| The Orion nuclear pulse drive combines a very high exhaust velocity, from {{convert|12|to|19|mi/s|km/s|0|sp=us|abbr=on}} in typical interplanetary designs, with [[newton (units)|meganewton]]s of thrust.<ref>Ross, F.W. – Propulsive System Specific Impulse. General Atomics GAMD-1293 8 Feb. 1960</ref> Many spacecraft propulsion drives can achieve one of these or the other, but nuclear pulse rockets are the only proposed technology that could potentially meet the extreme power requirements to deliver both at once (see [[spacecraft propulsion]] for more speculative systems).
| | == let so many honest Excellent drops == |
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| [[Specific impulse]] (Isp) measures how much thrust can be derived from a given mass of fuel, and is a standard figure of merit for rocketry. For any rocket propulsion, since the [[kinetic energy]] of exhaust goes up with velocity squared ([[kinetic energy]] = ½ mv<sup>2</sup>), whereas the [[momentum]] and thrust goes up with velocity linearly ([[momentum]] = mv), obtaining a particular level of thrust (as in a number of [[G-force|g]] acceleration) requires far more power each time that exhaust velocity and [[specific impulse]] (Isp) is much increased in a design goal. (For instance, [[Mass driver#Spacecraft-based mass drivers|the most fundamental reason]] that current and proposed [[Electrically powered spacecraft propulsion|electric propulsion]] systems of high Isp tend to be low thrust is due to their limits on available power. Their thrust is actually inversely proportional to Isp if power going into exhaust is constant or at its limit from heat dissipation needs or other engineering constraints).<ref>Dr. Anthony Zuppero, Idaho National Engineering and Environmental Laboratory. [http://neofuel.com/optimum/ "Physics of Rocket Systems"] retrieved 2012-04-24</ref> The Orion concept detonates nuclear explosions externally at a rate of power release which is beyond what nuclear reactors could survive internally with known materials and design.
| | . See envious of the team for quite a while, until the two bachelor brothers Resentment winter authentic with: 'mouse you are wrong, this is not a weakness, which [http://www.dmwai.com/webalizer/kate-spade-15.html ケイトスペード クラッチバッグ] is an advantage, he was so cheap goods are 脚踩两只船, let so many honest Excellent drops, still remain a bachelor nirvana, right, Ge Jige early anxious to sell himself, nobody wanted not!? '<br>After<br>a jealousy envy hate everyone, but is [http://www.dmwai.com/webalizer/kate-spade-15.html ケイトスペード マザーズバッグ] sadly endless winter of two brothers, then deep that .........<br><br>third volume thief arena Chapter 46 tears laughing blossoms<br><br>first cup filled wine is drained Lin Yu Jing She put the cup on the table Dayton forthright manner to [http://www.dmwai.com/webalizer/kate-spade-11.html ケイトスペードのバッグ] the sentence: filling!<br><br>I sin to jump. saw Lin Yu Jing one. again filling up. thirty-eight degrees Fen A large cup of two hundred thirty-two - [http://www.dmwai.com/webalizer/kate-spade-5.html ケイトスペード 財布 セール] so ordinary people are not going to stand in Lin Yu Jing and drink [http://www.dmwai.com/webalizer/kate-spade-10.html ケイトスペード バッグ ショルダー] half of this . before Shu-been big eyes wide open to the general looked more than sin strange to ask:... '? You do not persuade me drink less anxious I was drunk is not'<br><br>'Do not drink and plan a drunk thing. drink Well advised me to |
| | | 相关的主题文章: |
| Since weight is no limitation, an Orion craft can be extremely robust. An unmanned craft could tolerate very large accelerations, perhaps 100 [[g-force|''g'']]. A human-crewed Orion, however, must use some sort of damping system behind the pusher plate to smooth the instantaneous acceleration to a level that humans can comfortably withstand – typically about 2 to 4 ''g''.
| | <ul> |
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| The high performance depends on the high exhaust velocity, in order to maximize the rocket's force for a given mass of propellant. The velocity of the plasma debris is proportional to the square root of the change in the temperature (''T<sub>c</sub>'') of the nuclear fireball. Since fireballs routinely achieve ten million degrees Celsius or more in less than a millisecond, they create very high velocities. However, a practical design must also limit the destructive radius of the fireball. The diameter of the nuclear fireball is proportional to the square root of the bomb's explosive yield.
| | <li>[http://www.zjxssc.com/plus/feedback.php?aid=16 http://www.zjxssc.com/plus/feedback.php?aid=16]</li> |
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| The shape of the bomb's reaction mass is critical to efficiency. The original project designed bombs with a reaction mass made of [[tungsten]]. The bomb's geometry and materials focused the [[X-ray]]s and plasma from the core of nuclear explosive to hit the reaction mass. In effect each bomb would be a nuclear [[shaped charge]].
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| A bomb with a cylinder of reaction mass expands into a flat, disk-shaped wave of plasma when it explodes. A bomb with a disk-shaped reaction mass expands into a far more efficient cigar-shaped wave of plasma debris. The cigar shape focuses much of the plasma to impinge onto the pusher-plate.
| | <li>[http://goldenfish.com/plus/view.php?aid=37882 http://goldenfish.com/plus/view.php?aid=37882]</li> |
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| The maximum effective specific impulse, ''I<sub>sp</sub>'', of an Orion nuclear pulse drive generally is equal to:
| | </ul> |
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| :<math>I_{sp} = \frac{C_0 \cdot V_e}{g_n}</math> | |
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| where ''C<sub>0</sub>'' is the collimation factor (what fraction of the explosion plasma debris will actually hit the impulse absorber plate when a pulse unit explodes), ''V<sub>e</sub>'' is the nuclear pulse unit plasma debris velocity, and ''g<sub>n</sub>'' is the standard acceleration of gravity (9.81 m/s<sup>2</sup>; this factor is not necessary if ''I<sub>sp</sub>'' is measured in N·s/kg or m/s). A collimation factor of nearly 0.5 can be achieved by matching the diameter of the pusher plate to the diameter of the nuclear fireball created by the explosion of a nuclear pulse unit.
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| The smaller the bomb, the smaller each impulse will be, so the higher the rate of impulses and more than will be needed to achieve orbit. Smaller impulses also mean less ''g'' shock on the pusher plate and less need for damping to smooth out the acceleration.
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| The optimal Orion drive bomblet yield (for the human crewed 4,000 ton reference design) was calculated to be in the region of 0.15 kt, with approx 800 bombs needed to orbit and a bomb rate of approx 1 per second.{{citation needed|date=December 2012}}
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| ==Sizes of Orion vehicles==
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| The following can be found in [[George Dyson (science historian)|George Dyson]]'s book<ref>Dyson, George. Project Orion – The Atomic Spaceship 1957-1965. Penguin. ISBN 0-14-027732-3</ref> pg. 55 published in 2002. The figures for the comparison with Saturn V are taken from [[Payload (air and space craft)#Space craft|this section]] and converted from metric (kg) to US [[short ton]]s (abbreviated "t" here).
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| [[File:Project Orion Saturn-V compatibility.png|thumb|Image of the smallest Orion vehicle extensively studied, which could have had a payload of around 100 tonnes in a 8 crew round trip to Mars.<ref>http://ntrs.nasa.gov/archive/nasa/casi.ntrs.nasa.gov/20000096503_2000138021.pdf AlAA 2000-3856
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| Nuclear Pulse Propulsion - Orion and
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| Beyond
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| G.R. Schmidt, J.A. Bunornetti and P.J. Morton
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| NASA Marshall Space Flight Center
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| Huntsville, Alabama ''Two or possibly three Saturn V's would have been required to put this vehicle into orbit, and some
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| on-orbit assembly would be required. Several mission
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| profiles were considered -the one developed in
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| greatest detail was for a Mars mission. Eight
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| astronauts. With around 100 tonnes of equipment and
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| supplies. could have made a round trip to Mars in 175
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| days (most current plans call for one-way times of at
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| least nine months). Another impressive figure is that
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| as much as 45% of the gross vehicle in Earth orbit could have been payload.''</ref> On the left, the 10 meter diameter [[Saturn V]] "Boost-to-orbit" variant, requiring in-orbit assembly before the Orion vehicle would be capable of moving under its own propulsion system. On the far right, the fully assembled "lofting" configuration, in which the spacecraft would be lifted high into the atmosphere before pulse propulsion began. As depicted in the 1964 [[NASA]] document "Nuclear Pulse Space Vehicle Study Vol III - Conceptual Vehicle Designs and Operational Systems."<ref>http://ntrs.nasa.gov/archive/nasa/casi.ntrs.nasa.gov/19770085619_1977085619.pdf
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| Document ID: 19770085619
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| Updated/Added to NTRS: 2005-07-04 ''Nuclear Pulse Space Vehicle Study Vol III - Conceptual Vehicle Designs and Operational Systems.'' Shipps, P. R.
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| NASA Center for AeroSpace Information (CASI)
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| NASA-CR-60653; GA-5009-VOL-3 , 19640919; Sep 19, 1964
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| Accession ID: 77X70250</ref><ref>http://www.lepp.cornell.edu/~seb/celestia/orion/index.html</ref>]]
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| {| class="wikitable" style="text-align:center"
| |
| !
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| !Orbital<br/>test
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| !Interplanetary
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| !Advanced<br/>interplanetary
| |
| !Saturn V
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| |-
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| !Ship mass
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| | 880 t || 4,000 t || 10,000 t ||3,350 t
| |
| |-
| |
| !Ship diameter
| |
| | 25 m || 40 m || 56 m ||10 m
| |
| |-
| |
| !Ship height
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| | 36 m || 60 m || 85 m ||110 m
| |
| |-
| |
| !Bomb yield<br/>(sea level)
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| | 0.03 kt || 0.14 kt || 0.35 kt ||n/a
| |
| |-
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| !Bombs<br/>(to 300 mi [[Low Earth Orbit]])
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| | 800 || 800 || 800 ||n/a
| |
| |-
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| !Payload<br/>(to 300 mi LEO)
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| | 300 t || 1,600 t || 6,100 t ||130 t
| |
| |-
| |
| !Payload<br/>(to Moon soft landing)
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| | 170 t || 1,200 t || 5,700 t ||2 t
| |
| |-
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| !Payload<br/>(Mars orbit return) | |
| | 80 t || 800 t || 5,300 t || –
| |
| |-
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| !Payload<br/>(3yr Saturn return)
| |
| | – || – || 1,300 t || –
| |
| |}
| |
| | |
| In late 1958 to early 1959, it was realized that the smallest practical vehicle would be determined by the smallest achievable bomb yield. The use of 0.03 kt (sea-level yield) bombs would give vehicle mass of 880 tons. However, this was regarded as too small for anything other than an orbital test vehicle and the team soon focused on a 4,000 ton "base design".
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| At that time, the details of small bomb designs were shrouded in secrecy. Many Orion design reports had all details of bombs removed before release. Contrast the above details with the 1959 report by General Atomics,<ref name="GAMD-784">{{cite book| year=1959| publisher=General Atomics| title=Dimensional Study of Orion Type Spaceships| last=Dunne| coauthors=Dyson and Treshow| id=GAMD-784}}</ref> which explored the parameters of three different sizes of [[hypothetical]] Orion spacecraft:
| |
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| {| class="wikitable"
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| !
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| !"Satellite"<br/>Orion
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| !"Midrange"<br/>Orion
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| !"Super"<br/>Orion
| |
| |-
| |
| !Ship diameter
| |
| | 17–20 m || 40 m || 400 m
| |
| |-
| |
| !Ship mass
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| | 300 t || 1000–2000 t || 8,000,000 t
| |
| |-
| |
| !Number of bombs
| |
| | 540 || 1080 || 1080
| |
| |-
| |
| !Individual bomb mass
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| | 0.22 t || 0.37–0.75 t || 3000 t
| |
| |}
| |
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| The biggest design above is the "super" Orion design; at 8 million tonnes, it could easily be a city.<ref name=george>{{cite book| title=Project Orion: The True Story of the Atomic Spaceship| first=George| last=Dyson| year=2002| isbn=0-8050-7284-5| publisher=Henry Holt and Co.| location=New York, N.Y.}}</ref> In interviews, the designers contemplated the large ship as a possible [[interstellar ark]]. This extreme design could be built with materials and techniques that could be obtained in 1958 or were anticipated to be available shortly after. The practical upper limit is likely to be higher with modern materials.
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| Most of the three thousand tonnes of each of the "super" Orion's propulsion units would be inert material such as [[polyethylene]], or [[boron]] salts, used to transmit the force of the propulsion units detonation to the Orion's pusher plate, and absorb neutrons to minimize fallout. One design proposed by Freeman Dyson for the "Super Orion" called for the pusher plate to be composed primarily of uranium or a [[transuranium element|transuranic element]] so that upon reaching a nearby star system the plate could be converted to nuclear fuel.
| |
| | |
| ==Interplanetary applications==
| |
| The Orion nuclear pulse rocket design has extremely high performance. Orion nuclear pulse rockets using nuclear fission type pulse units were originally intended for use on interplanetary space flights.
| |
| | |
| Missions that were designed for an Orion vehicle in the original project included single stage (i.e., directly from Earth's surface) to Mars and back, and a trip to one of the moons of Saturn.<ref name=george/>
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| One possible modern mission for this near-term technology would be to deflect an asteroid that could collide with Earth. The extremely high performance would permit even a late launch to succeed, and the vehicle could effectively transfer a large amount of kinetic energy to the asteroid by simple impact. Also, such an unmanned mission would eliminate the need for shock absorbers, the most problematic issue of the design.
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| Nuclear fission pulse unit powered Orions could provide fast and economical interplanetary transportation with useful human crewed payloads of several thousand tonnes.
| |
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| ==Interstellar missions==
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| Freeman Dyson performed the first analysis of what kinds of Orion missions were possible to reach [[Alpha Centauri]], the nearest star system to the [[Sun]].<ref>"Nuclear Pulse Propulsion: A Historical Review" by Martin and Bond, Journal of the British Interplanetary Society, 1979 (p.301)</ref> His 1968 paper "Interstellar Transport"<ref>http://galileo.phys.virginia.edu/classes/109.jvn.spring00/nuc_rocket/Dyson.pdf</ref> (Physics Today, October 1968, p. 41–45) retained the concept of large nuclear explosions but Dyson moved away from the use of fission bombs and considered the use of one megaton [[deuterium]] fusion explosions instead. His conclusions were simple: the debris velocity of fusion explosions was probably in the 3000–30,000 km/s range and the reflecting geometry of Orion's hemispherical pusher plate would reduce that range to 750–15,000 km/s.<ref>"The Starflight Handbook" by Mallove and Matloff, John Wiley & Sons, 1989, ISBN 0-471-61912-4 (page 66)</ref>
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| To estimate the upper and lower limits of what could be done using contemporary technology (in 1968), Dyson considered two starship designs. The more conservative ''energy limited'' pusher plate design simply had to absorb all the thermal energy of each impinging explosion (4×10<sup>15</sup> joules, half of which would be absorbed by the pusher plate) without melting. Dyson estimated that if the exposed surface consisted of [[copper]] with a thickness of 1 mm, then the diameter and mass of the hemispherical pusher plate would have to be 20 kilometers and 5 million metric tons, respectively. 100 seconds would be required to allow the copper to radiatively cool before the next explosion. It would then take on the order of 1000 years for the energy-limited [[heat sink]] Orion design to reach Alpha Centauri.
| |
| | |
| In order to improve on this performance while reducing size and cost, Dyson also considered an alternative ''momentum limited'' pusher plate design where an ablation coating of the exposed surface is substituted to get rid of the excess heat. The limitation is then set by the capacity of shock absorbers to transfer momentum from the impulsively accelerated pusher plate to the smoothly accelerated vehicle. Dyson calculated that the properties of available materials limited the velocity transferred by each explosion to ~30 meters per second independent of the size and nature of the explosion. If the vehicle is to be accelerated at 1 Earth gravity (9.81 m/s<sup>2</sup>) with this velocity transfer, then the pulse rate is one explosion every three seconds.<ref>Bond & Martin, page 302</ref> The dimensions and performance of Dyson's vehicles are given in the table below
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| {| class="wikitable"
| |
| !
| |
| !"Energy Limited"<br/>Orion
| |
| !"Momentum Limited"<br/>Orion
| |
| |-
| |
| !Ship diameter (meters)
| |
| | 20,000 m || 100 m
| |
| |-
| |
| !Mass of empty ship (metric tons)
| |
| | 10,000,000 t (incl.5,000,000 t copper hemisphere) || 100,000 t (incl. 50,000 t structure+payload)
| |
| |-
| |
| !+Number of bombs = total bomb mass (each 1 Mt bomb weighs 1 metric ton)
| |
| | 30,000,000 || 300,000
| |
| |-
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| !=Departure mass (metric tons)
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| | 40,000,000 t || 400,000 t
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| |-
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| !Maximum velocity (kilometers per second)
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| | 1000 km/s (=0.33% of the speed of light) || 10,000 km/s (=3.3% of the speed of light)
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| |-
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| !Mean acceleration (Earth gravities)
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| | 0.00003 g (accelerate for 100 years) || 1 g (accelerate for 10 days)
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| |-
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| !Time to Alpha Centauri (one way, no slow down)
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| | 1330 years || 133 years
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| |-
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| !Estimated cost
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| | 1 year of [[U.S.]] [[GNP]] (1968), $3.67 Trillion || 0.1 year of U.S. GNP $0.367 Trillion
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| |}
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| Later studies indicate that the top cruise velocity that can theoretically be achieved by a [[Teller-Ulam]] thermonuclear unit powered Orion starship, assuming no fuel is saved for slowing back down, is about 8% to 10% of the [[speed of light]] (0.08-0.1c).<ref name="Cosmos by Carl Sagan"/> An atomic (fission) Orion can achieve perhaps 3%-5% of the speed of light. A nuclear pulse drive starship powered by Fusion-[[antimatter catalyzed nuclear pulse propulsion]] units would be similarly in the 10% range and pure [[Relativistic rocket|Matter-antimatter annihilation rockets]] would be theoretically capable of obtaining a velocity between 50% to 80% of the [[speed of light]]. In each case saving fuel for slowing down halves the max. speed. The concept of using a magnetic sail to decelerate the spacecraft as it approaches its destination has been discussed as an alternative to using propellant, this would allow the ship to travel near the maximum theoretical velocity.<ref>http://www.space-nation.org/images/a/a1/Mini-Mag_Orion_and_superconducting_coils_for_near-term_interstellar_transportation_LenardAndrews.pdf</ref>
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| At 0.1''c'', Orion thermonuclear starships would require a flight time of at least 44 years to reach Alpha Centauri, not counting time needed to reach that speed (about 36 days at constant acceleration of 1''g'' or 9.8 m/s<sup>2</sup>). At 0.1''c'', an Orion starship would require 100 years to travel 10 light years. The astronomer [[Carl Sagan]] suggested that this would be an excellent use for current stockpiles of nuclear weapons.<ref>Cosmos series, Episode 8</ref>
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| {{Further|Interstellar travel}}
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| ==Later developments==
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| A concept similar to Orion was designed by the [[British Interplanetary Society]] (B.I.S.) in the years 1973–1974. [[Project Daedalus]] was to be a robotic interstellar probe to [[Barnard's Star]] that would travel at 12% of the speed of light. In 1989, a similar concept was studied by the U.S. Navy and NASA in [[Project Longshot]]. Both of these concepts require significant advances in fusion technology, and therefore cannot be built at present, unlike Orion.
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| From 1998 to the present, the nuclear engineering department at Pennsylvania State University has been developing two improved versions of project Orion known as [[ICAN-II|Project ICAN]] and [[AIMStar (spacecraft)|Project AIMStar]] using compact [[antimatter catalyzed nuclear pulse propulsion]] units,<ref>http://www.engr.psu.edu/antimatter/introduction2.html</ref> rather than the large [[inertial confinement fusion]] ignition systems proposed in Project Daedalus and Longshot.<ref>{{cite web|url=http://www.engr.psu.edu/antimatter/documents.html |title=Antimatter Space Propulsion at Penn State University (LEPS) |publisher=Engr.psu.edu |date=2001-02-27 |accessdate=2009-11-15}}</ref>
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| ==Economics==
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| The expense of the fissionable materials required was thought high, until the physicist Ted Taylor showed that with the right designs for explosives, the amount of fissionables used on launch was close to constant for every size of Orion from 2,000 tons to 8,000,000 tons. The larger bombs used more explosives to super-compress the fissionables, increasing efficiency. The extra debris from the explosives also serves as additional propulsion mass.
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| The bulk of costs for historical nuclear defense programs have been
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| for delivery and support systems, rather than for production cost of the bombs directly (with warheads being 7% of the U.S. 1946-1996 expense total according to one study).<ref>Brookings Institution.[http://www.brookings.edu/projects/archive/nucweapons/figure1.aspx] Incurred Costs of U.S. Nuclear Weapons Programs, 1940-1996] retrieved 2012-01-11</ref> After initial infrastructure development and investment, the marginal cost each of additional nuclear bombs in mass production can be relatively low. In the 1980s, some U.S. thermonuclear warheads had $1.1 million estimated cost each ($630 million for 560).<ref name = astronautica>Encyclopedia Astronautica. [http://www.astronautix.com/articles/probirth.htm Project Orion] retrieved 2012-1-11</ref> For the perhaps simpler fission pulse units to be used by one Orion design, a 1964 source estimated a cost of $40000 or less each in mass production, which would be up to approximately $0.3 million each in modern-day dollars adjusted for inflation.<ref name="astronautica"/><ref>[http://146.142.4.24/cgi-bin/cpicalc.pl?cost1=40000&year1=1964&year2=2011 CPI Inflation Calculator] retrieved 2012-01-11</ref>
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| Project Daedalus later proposed fusion explosives ([[deuterium]] or tritium pellets) detonated by electron beam inertial confinement. This is the same principle behind [[inertial confinement fusion]]. However, theoretically, it might be scaled down to far smaller explosions, and require small shock absorbers.
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| ==Vehicle architecture==
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| [[File:Project-Orion propulsion-module section.png|thumb|upright=2|A design for the Orion propulsion module]]
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| From 1957 until 1964 this information was used to design a spacecraft propulsion system called "Orion", in which nuclear explosives would be thrown behind a pusher-plate mounted on the bottom of a spacecraft and exploded. The shock wave and radiation from the detonation would impact against the underside of the pusher plate, giving it a powerful "kick". The pusher plate would be mounted on large two-stage [[shock absorber]]s that would smoothly transmit acceleration to the rest of the spacecraft.
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| During take-off, there were concerns of danger from fluidic shrapnel being reflected from the ground. One proposed solution was to use a flat plate of conventional explosives spread over the pusher plate, and detonate this to lift the ship from the ground before going nuclear. This would lift the ship far enough into the air that the first focused nuclear blast would not create debris capable of harming the ship.
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| A preliminary design for the explosives was produced. It used a shaped-charge fusion-boosted fission explosive. The explosive was wrapped in a [[beryllium oxide]] "channel filler", which was surrounded by a [[uranium]] radiation mirror. The mirror and channel filler were open ended, and in this open end a flat plate of [[tungsten]] propellant was placed. The whole thing was built into a can with a diameter no larger than {{convert|6|in|cm}} and weighed just over {{convert|300|lb|kg}} so it could be handled by machinery scaled-up from a soft-drink vending machine (indeed, Coca-Cola was consulted on the design).<ref name="Jacobsen">Jacobsen, Annie (2012), Area 51: An Uncensored History of America's Top Secret Military Base, Back Bay Books, ISBN 0316202304, p.305</ref>
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| At 1 microsecond after ignition, the gamma bomb plasma and neutrons would heat the channel filler, and be somewhat contained by the uranium shell. At 2–3 microseconds, the channel filler would transmit some of the energy to the propellant, which vaporized. The flat plate of propellant formed a cigar-shaped explosion aimed at the pusher plate.
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| The plasma would cool to 14,000 °C, as it traversed the 25 m distance to the pusher plate, and then reheat to 67,000 °C, as (at about 300 microseconds) it hit the pusher plate and recompressed. This temperature emits ultraviolet, which is poorly transmitted through most plasmas. This helps keep the pusher plate cool. The cigar shaped distribution profile and low density of the plasma reduces the instantaneous shock to the pusher plate.
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| The pusher plate's thickness would decrease by about a factor of 6 from the center to the edge, so that the net velocity of the inner and outer parts of the plate are the same, even though the momentum transferred by the plasma increases from the center outwards.
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| At low altitudes where the surrounding air is dense, [[compton scattering|gamma scattering]] could potentially harm the crew and a radiation refuge would be necessary anyway on long missions to survive [[solar flare]]s. Radiation shielding effectiveness increases exponentially with shield thickness (see [[gamma ray]] for a discussion of shielding), so on ships with mass greater than a thousand tons, the structural bulk of the ship, its stores, and the mass of the bombs and propellant would provide more than adequate shielding for the crew.
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| Stability was initially thought to be a problem due to inaccuracies in the placement of the bombs, but it was later shown that the effects would tend to cancel out.<ref>Teichmann, T. – The angular effects due to asymmetric placement of axial symmetric explosives: GAMD-5823, 26 Oct 1963</ref><ref>David, C. V. Stability study of Nuclear Pulse Propulsion (Orion) Engine System. GAMD-6213, 30 Apr 1965</ref>
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| Numerous model flight tests (using conventional explosives) were conducted at [[Point Loma, San Diego]] in 1959. On November 14, the one-meter model, called "Hot Rod" (or "putt-putt"), first flew using [[RDX]] (chemical explosives) in a controlled flight for 23 seconds to a height of 56 meters. Film of the tests has been transcribed to video<ref>{{cite web|author=August 6, 2007 |url=http://www.youtube.com/watch?v=E3Lxx2VAYi8 |title=Project Orion |publisher=YouTube |date= |accessdate=2009-11-15}}</ref> shown on the BBC TV program "To Mars by A-Bomb" in 2003 with comments by Freeman Dyson and [[Arthur C. Clarke]]. The model landed by parachute undamaged and is in the collection of the Smithsonian National Air and Space Museum.
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| The first proposed shock absorber was merely a ring-shaped airbag. However, it was soon realized that, should an explosion fail, the 500 to 1000 ton pusher plate would tear away the airbag on the rebound. So a two-stage, detuned spring/piston shock absorber design was developed. On the reference design, the first stage mechanical absorber was tuned 4.5 times the pulse frequency whilst the second stage gas piston was tuned to 1/2 times the pulse frequency. This permitted timing tolerances of 10 ms in each explosion.
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| The final design coped with bomb failure by overshooting and rebounding into a 'center' position. Thus, following a failure (and on initial ground launch) it would be necessary to start (or restart) the sequence with a lower yield device. In the 1950s methods of [[Variable yield|adjusting bomb yield]] were in their infancy and considerable thought was given to providing a means of 'swapping out' a standard yield bomb for a smaller yield one in a 2 or 3 second time frame (or to provide an alternative means of firing low yield bombs). Modern variable yield devices would allow a single standardized explosive to be 'tuned down' (configured to a lower yield) automatically.
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| The bombs had to be launched behind the pusher plate fast enough to explode 20 to 30 m beyond it every 1.1 seconds or so. Numerous proposals were investigated, from multiple guns poking over the edge of the pusher plate to rocket propelled bombs launched from 'roller coaster' tracks, however the final reference design used a simple gas gun to shoot the devices through a hole in the center of the pusher plate.
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| ==Potential problems==
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| Exposure to repeated nuclear blasts raises the problem of ''ablation'' (erosion) of the pusher plate. However, calculations and experiments indicate that a steel pusher plate would ablate less than 1 mm if unprotected. If sprayed with an oil, it need not ablate at all (this was discovered by accident; a test plate had oily fingerprints on it, and the fingerprints suffered no ablation). The absorption spectra of [[carbon]] and [[hydrogen]] minimize heating. The design temperature of the shockwave, 67,000 °C, emits [[ultraviolet]]. Most materials and elements are opaque to ultraviolet, especially at the 340 MPa pressures the plate experiences. This prevents the plate from melting or ablating.
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| One issue that remained unresolved at the conclusion of the project was whether or not the turbulence created by the combination of the propellant and ablated pusher plate would dramatically increase the total ablation of the pusher plate. According to Freeman Dyson, during the 1960s they would have had to actually perform a test with a real nuclear explosive to determine this; with modern simulation technology, this could be determined fairly accurately without such empirical investigation.
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| Another potential problem with the pusher plate is that of [[spall]]ing—shards of metal—potentially flying off the top of the plate. The shockwave from the impacting plasma on the bottom of the plate passes through the plate and reaches the top surface. At that point spalling may occur, damaging the pusher plate. For that reason, alternative substances (e.g., plywood and fiberglass) were investigated for the surface layer of the pusher plate, and thought to be acceptable.
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| If the conventional explosives in the nuclear bomb detonate, but a nuclear explosion does not ignite (a dud), shrapnel could strike and potentially critically damage the pusher plate.
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| True engineering tests of the vehicle systems were said to be impossible because several thousand nuclear explosions could not be performed in any one place. However, experiments were designed to test pusher plates in nuclear fireballs. Long-term tests of pusher plates could occur in space. Several of these tests almost flew.{{citation needed|date=October 2008}} The shock-absorber designs could be tested at full-scale on Earth using chemical explosives.
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| But the main unsolved problem for a launch from the surface of the Earth was thought to be [[nuclear fallout]]. Any explosions within the magnetosphere would carry fissionables back to earth unless the spaceship were launched from a polar region such as a barge in the higher regions of the Arctic, with the initial launching explosion to be a large mass of conventional high explosive only to significantly reduce fallout; subsequent detonations would be in the air and therefore much cleaner. [[Antarctica]] is not viable, as this would require enormous legal changes as the continent is presently an international wildlife preserve.
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| Freeman Dyson, group leader on the project, estimated back in the 1960s that with conventional [[nuclear weapons]] (a large fraction of yield from fission), each launch would cause statistically on average between 0.1 and 1 fatal cancers from the fallout.<ref name="disturbing">Disturbing the Universe – Freeman Dyson</ref> That estimate is based on [[Linear no-threshold model|no threshold]] model assumptions, a method often used in estimates of statistical deaths from other major industrial activities, such as how modern-day U.S. regulatory agencies frequently implement regulations on more conventional pollution if one life or more is predicted saved per $6 million to $8 million of economic costs incurred.<ref>New York Times. [http://www.nytimes.com/gwire/2011/01/18/18greenwire-epa-plans-to-revisit-a-touchy-topic-the-value-75301.html?pagewanted=all "EPA Plans to Revisit a Touchy Topic -- the Value of Saved Lives"] retrieved 2012-1-11</ref> Each few million dollars of efficiency indirectly gained or lost in the world economy may statistically average lives saved or lost, in terms of opportunity gains versus costs.<ref>[http://www.phyast.pitt.edu/~blc/book/chapter8.html "Understanding Risk"] retrieved 2012-1-11</ref> Indirect effects could matter for whether the overall influence of an Orion-based space program on future human global mortality would be a net increase or a net decrease, including if change in launch costs and capabilities affected [[space exploration]], [[space colonization]], the odds of [[Space and survival|long-term human species survival]], [[space-based solar power]], or other hypotheticals.
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| Danger to human life was not a reason given for shelving the project – those included lack of mission requirement (no-one in the US Government could think of any reason to put thousands of tons of payload into orbit), the decision to focus on rockets (for the Moon mission) and, ultimately, the signing of the [[Partial Test Ban Treaty]] in 1963. The danger to electronic systems on the ground (from [[Nuclear electromagnetic pulse|electromagnetic pulse]]) was not considered to be significant from the sub-kiloton blasts proposed since solid-state integrated circuits were not in general use at the time.
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| Orion-style nuclear pulse rockets can be launched from above the [[magnetosphere]] so that charged ions of fallout in its exhaust plasma are not trapped by the Earth's magnetic field and are not returned to Earth.
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| From many smaller detonations combined, the fallout for the entire launch of a 6,000 [[short ton]] (5,500 [[metric ton]]) Orion is equal to the detonation of a typical 10 [[TNT equivalent|megaton]] (40 [[petajoule]]) nuclear weapon as an [[airburst]], and therefore most of its fallout would be the comparatively dilute [[Nuclear fallout|delayed fallout]], if pessimistically assuming the use of nuclear explosives with a high portion of total yield from fission, it would produce a combined fallout total similar to the [[airburst|surface burst]] yield of the [[Ivy Mike|''Mike'' shot]] of [[Operation Ivy]](10.4 Megaton) in 1952, although the comparison is not quite perfect, as due to its surface burst location, ''Ivy Mike'' created a large amount of [[nuclear fallout|early fallout]] contamination. Historical above-ground nuclear weapon tests included 189 [[megaton]]s of fission yield and caused average global radiation exposure per person peaking at 0.11 mSv/a in 1963, with a 0.007 mSv/a residual in [[Background radiation#Overview|modern times]] (superimposed upon other sources of exposure, primarily natural [[background radiation]] which averages 2.4 mSv/a globally but varies greatly, such as 6 mSv/a in some high-altitude cities).<ref>UNSCEAR [http://www.unscear.org/docs/reports/2008/09-86753_Report_2008_GA_Report.pdf "Sources and Effects of Ionizing Radiation"] retrieved 2012-1-11</ref><ref>[http://www.aradnj.com/radiation2.html "Radiation Risk"] retrieved 2012-1-11</ref> Any comparison would be influenced by how population dosage is affected by detonation locations, with very remote sites preferred.
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| With special designs of the nuclear explosive, Ted Taylor estimated that fission product fallout could be reduced tenfold, or even to zero if a [[pure fusion weapon|pure fusion explosive]] could be constructed instead. A 100% pure fusion explosive has yet to be successfully developed according to declassified US government documents, although relatively clean PNEs ([[Peaceful nuclear explosions]]) were tested for canal excavation by the Soviet Union in the 1970s with 98% fusion yield in the ''Taiga'' test's 15 [[kiloton]] devices (only 0.3 [[kiloton]]s fission).<ref name="disturbing"/><ref>[http://www.bibliotecapleyades.net/ciencia/ciencia_uranium27.htm The Soviet Program for Peaceful Uses of Nuclear Explosions] by Milo D. Nordyke. Science & Global Security, 1998, Volume 7, pp. 1-117</ref>
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| The vehicle and its test program would violate the [[Partial Test Ban Treaty]] of 1963 as currently written, which prohibited all nuclear detonations except those conducted underground, both as an attempt to slow the arms race and to limit the amount of radiation in the atmosphere caused by nuclear detonations. There was an effort by the US government to put an exception into the 1963 treaty to allow for the use of nuclear propulsion for spaceflight, but Soviet fears about military applications kept the exception out of the treaty. This limitation would affect only the US, Russia, and the United Kingdom. It would also violate the [[Comprehensive Nuclear-Test-Ban Treaty]] which has been signed by the United States and China, as well as the de-facto moratorium on nuclear testing that the declared nuclear powers have imposed since the 1990s. Project Orion however would not violate the [[Outer Space Treaty]] which bans nuclear weapons in space, but not peaceful uses of nuclear explosions.
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| It has been suggested that the restrictions of the Treaty would not apply to the Project Daedalus fusion microexplosion rocket. Daedalus class systems use pellets of one gram or less ignited by particle or laser beams to produce very small fusion explosions with a maximum explosive yield of only 10–20 tons of TNT equivalent.
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| The launch of such an Orion nuclear bomb rocket from the ground or from [[low Earth orbit]] would generate an [[Nuclear electromagnetic pulse|electromagnetic pulse]] that could cause significant damage to [[computer]]s and [[satellite]]s, as well as flooding the [[Van Allen radiation belt|van Allen belt]]s with high-energy radiation. This problem might be solved by launching from very remote areas, because the EMP footprint would be only a few hundred miles wide. The Earth is well shielded by the Van Allen belts. In addition, a few relatively small space-based [[electrodynamic tether]]s could be deployed to quickly eject the energetic particles from the capture angles of the Van Allen belts.
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| An Orion spacecraft could be boosted by non-nuclear means to a safer distance, only activating its drive well away from Earth and its attendant satellites. The Lofstrom [[launch loop]] or a [[space elevator]] hypothetically provide excellent solutions, although in the case of the space elevator existing [[carbon nanotubes]] composites do not yet have sufficient [[tensile strength]]. All chemical rocket designs are extremely inefficient (and expensive) when launching mass into orbit, but could be employed if the result were viewed as worth the cost.
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| ==People==
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| *[[Stanislaw Ulam]]
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| *[[Jaromir Astl]], Explosives Engineer
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| *[[Freeman Dyson]], Physicist
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| *[[Ted Taylor (physicist)|Ted Taylor]], Project Director
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| *[[Lew Allen]], Contract Manager
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| *Edward Giller, USAF Liaison
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| *Donald Prickett, USAF Liaison
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| ==Operation Plumbbob==
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| {{main|Operation Plumbbob}}
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| A test similar to the test of a pusher plate occurred as an accidental side effect of a nuclear containment test called "[[Pascal-B]]" conducted on 27 August 1957.<ref>{{cite web| url=http://nuclearweaponarchive.org/Usa/Tests/Plumbob.html#PascalB| title=Operation Plumbbob|date=July 2003| accessdate=2006-07-31}}</ref> The test's experimental designer Dr. Brownlee performed a highly approximate calculation that suggested that the low-yield nuclear explosive would accelerate the massive (900 kg) steel capping plate to six times [[escape velocity]].<ref>{{cite web| url=http://nuclearweaponarchive.org/Usa/Tests/Brownlee.html| title=Learning to Contain Underground Nuclear Explosions| first=Robert R.| last=Brownlee|date=June 2002| accessdate=2006-07-31}}</ref> The plate was never found, but Dr. Brownlee believes that the plate never left the atmosphere (for example it could have been vaporized by compression heating of the atmosphere due to its high speed). The calculated velocity was sufficiently interesting that the crew trained a high-speed camera on the plate, which unfortunately only appeared in one frame, but this nevertheless gave a very high lower bound for the speed.
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| ==Appearances in fiction==
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| {{main|List of stories featuring nuclear pulse propulsion}}
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| The novel by Arthur C. Clarke, ''2001: A Space Odyssey'', included a ship "Discovery 1" using this drive. The vehicle in the movie did not use this idea since Stanley Kubrick was disillusioned with nuclear power after making Dr. Strangelove or: How I Learned to Stop Worrying and Love the Bomb.
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| The ''[[Star Trek: The Original Series]]'' episode "For the World is Hollow and I Have Touched the Sky" features a generation ship, constructed out of a hollowed-out iron asteroid, propelled using "Orion class nuclear pulse engines" in which fission bombs were detonated in shafts. It appeared to have been traveling for about 10,000 years, and had travelled about 30 light years on its own power.
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| The 1998 film Deep Impact featured a spacecraft named Messiah, which utilized the "Orion drive" and appears to be a variant of nuclear detonation propulsion. In the film, the drive is credited to the Russians.
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| ==See also==
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| *[[Mini-Mag Orion]]
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| *[[Magnetic sail]]
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| *[[Project Prometheus]]
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| *[[Project Daedalus]]
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| *[[Project Longshot]]
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| *[[Project Valkyrie]]
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| *[[NERVA|NERVA, Nuclear Engine for Rocket Vehicle Application]]
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| ==References==
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| {{reflist|2}}
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| ==Further reading==
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| {{div col|2}}
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| *{{cite book|last=McPhee|first=John|title=The Curve of Binding Energy|publisher= Farrar, Straus and Giroux|year=1994|isbn=978-0-374-51598-0}}
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| *"Nuclear Pulse Propulsion (Project Orion) Technical Summary Report" RTD-TDR-63-3006 (1963–1964); GA-4805 Vol. 1, Reference Vehicle Design Study, Vol. 2, Interaction Effects, Vol. 3, Pulse Systems, Vol. 4, Experimental Structural Response. (From the National Technical Information Service, U.S.A.)
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| *"Nuclear Pulse Propulsion (Project Orion) Technical Summary Report" 1 July 1963 – 30 June 1964, WL-TDR-64-93; GA-5386 Vol. 1, Summary Report, Vol. 2, Theoretical and Experimental Physics, Vol. 3, Engine Design, Analysis and Development Techniques, Vol. 4, Engineering Experimental Tests. (From the National Technical Information Service, U.S.A.)
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| *"Dynamic America; a history of General Dynamics Corporation and its predecessor companies", John Niven, Courtlandt Canby, and Vernon Welsh Designer, Erik Nitsche, 1960 [http://spacebombardment.blogspot.com/2005/10/dynamic-america.html Page Image]
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| *General Atomics, [http://ntrs.nasa.gov/archive/nasa/casi.ntrs.nasa.gov/19650058729_1965058729.pdf ''Nuclear Pulse Space Vehicle Study, Volume I -- Summary''], September 19, 1964
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| *General Atomics, [http://ntrs.nasa.gov/archive/nasa/casi.ntrs.nasa.gov/19770085619_1977085619.pdf ''Nuclear Pulse Space Vehicle Study, Volume III -- Conceptual Vehicle Designs And Operational Systems''], September 19, 1964
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| *General Atomics, [http://ntrs.nasa.gov/archive/nasa/casi.ntrs.nasa.gov/19660072847_1966072847.pdf ''Nuclear Pulse Space Vehicle Study, Volume IV -- Mission Velocity Requirements And System Comparisons''], February 28, 1966
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| *General Atomics, [http://ntrs.nasa.gov/archive/nasa/casi.ntrs.nasa.gov/19660072846_1966072846.pdf ''Nuclear Pulse Space Vehicle Study, Volume IV -- Mission Velocity Requirements And System Comparisons (Supplement)''], February 28, 1966
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| *NASA, [http://ntrs.nasa.gov/archive/nasa/casi.ntrs.nasa.gov/19760065935_1976065935.pdf ''Nuclear Pulse Vehicle Study Condensed Summary Report (General Dynamics Corp)''], January </div>
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| *[http://books.google.com/books?id=r_Gu4f0QxrkC&printsec=frontcover&dq=project+orion&hl=en&ei=1UjLTN7BNYP-8AaGo5WlAQ&sa=X&oi=book_result&ct=result&resnum=1&ved=0CCwQ6AEwAA#v=onepage&q&f=false '''Project Orion: The True Story of the Atomic Spaceship''' By George Dyson (2003)] (Google Books Link)
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| {{div col end}}
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| ==External links==
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| {{commons|Project Orion|Project Orion (nuclear propulsion)}}
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| *[http://www.spacedaily.com/news/nuclearspace-03h.html The case for Orion]
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| *[http://www.webofstories.com/people/freeman.dyson/116 Freeman Dyson talking about Project Orion]
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| *[http://www.islandone.org/Propulsion/ProjectOrion.html Project Orion: Its Life, Death, and Possible Rebirth]
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| *[http://www.u.arizona.edu/~tuvas/ Electromagnetic Pulse Shockwaves as a result of Nuclear Pulse Propulsion]
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| *[http://web.archive.org/web/20071022133749rn_1/www.mfbb.net/nuclearrockets/nuclearrockets-about12.html Nuclear Rocket Board: "Pulse Propulsion Document Library"]: Archive copy of Forum page w/links to original Orion docs
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| *[http://www.ted.com/talks/view/id/221 George Dyson talking about Project Orion] at [[TED (conference)|TED]]
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| *[http://www.educatedearth.net/video.php?id=4471 To Mars by A-Bomb] Watch at Educated Earth
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| *[http://www.youtube.com/watch?v=V1vKMTYa40A: YouTube Project Orion Clip] Short Clip on the Orion Spacecraft
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| {{nuclear propulsion}}
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| {{US manned space programs}}
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| {{DEFAULTSORT:Project Orion (Nuclear Propulsion)}}
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| [[Category:Nuclear spacecraft propulsion|Orion]]
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| [[Category:Proposed spacecraft]]
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| [[Category:Single-stage-to-orbit]]
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| [[Category:Space access]]
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| [[Category:Engineering projects|Orion]]
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| [[Category:Freeman Dyson]]
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| [[Category:Interstellar travel]]
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| {{link FA|de}}
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