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| '''Specific impulse''' (usually abbreviated ''I''<sub>sp</sub>) is a way to describe the efficiency of [[rocket engine|rocket]] and [[jet engine|jet]] engines. It represents the [[force]] with respect to the amount of [[propellant]] used per unit time.<ref name="QRG1">{{cite web|url=http://www.qrg.northwestern.edu/projects/vss/docs/propulsion/3-what-is-specific-impulse.html|title=What is specific impulse?|publisher=Qualitative Reasoning Group|accessdate=22 December 2009}}</ref> If the "amount" of propellant is given in terms of [[mass]] (such as in kilograms), then specific impulse has units of [[velocity]]. If it is given in terms of weight (such as in [[kilopond]]s or [[newtons]]), then specific impulse has units of time (seconds). The conversion constant between the two versions of specific impulse is '''[[standard gravity|g]]'''.<ref name="SINasa">{{cite web|url=http://www.grc.nasa.gov/WWW/K-12/airplane/specimp.html|title=Specific impulse|last=Benson|first=Tom|date=11 July 2008|publisher=NASA|accessdate=22 December 2009}}</ref> The higher the specific impulse, the lower the propellant [[flow rate]] required for a given [[thrust]], and in the case of a rocket the less propellant is needed for a given [[delta-v]] per the [[Rocket equation|Tsiolkovsky rocket equation]].
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| The '''actual exhaust velocity''' is the average speed of the exhaust jet as it leaves the vehicle. The '''effective exhaust velocity''' is the exhaust velocity that would be required to produce the same thrust in a vacuum. The two are identical for an ideal rocket working in a vacuum, but are radically different for an [[air-breathing jet engine]] that obtains extra thrust by accelerating air. Specific impulse and effective exhaust velocity are proportional.
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| Specific impulse is a useful value to compare engines, much like ''miles per gallon'' or ''liters per 100 kilometers'' is used for cars.<ref name=sutton/> A propulsion method with a higher specific impulse is more propellant-efficient.<ref name="QRG1" /><ref name=ars20130414>
| | In another case, just one male [http://tsptalk.mobi/leaving.php?u=http%3A%2F%2Fcctvdvrreviews.com&error=DIFFERENT_DOMAIN&back=http%3A%2F%2Ftsptalk.mobi%2F&imz_s=1a7os3d995291ar05boma6td93 cctv dvr configuration internet] might find having a DVR enabling him to turn into a couch potato. You might [http://Www.Tradeboats.Com.au/externalsearchstart/?return=http://cctvdvrreviews.com free cctv dvr software windows 7] be surprised to know that using IP CCTV is a bit more useful than having analogue CCTV installed. Cctv dvr software upgrade One family may find having a [http://azuria-Wiki.com/index.php?title=How_To_Slap_Down_A_16_Port_Dvr_Card DVR indispensable] since they can more readily control what their [http://azuria-Wiki.com/index.php?title=How_To_Slap_Down_A_16_Port_Dvr_Card children] are watching on television.<br><br>In many retail institutions, police stations, prisons, together with high security scientific and manufacturing facilities, the application of wireless CCTV video cameras are normal. Some believe that even if CCTV footage is never viewed, the very fact that it can be recorded [http://publications.gc.ca/site/archivee-archived.html?url=http://cctvdvrreviews.com zmodo 16 channel cctv dvr hdmi security system reviews] and archived is really a violation of privacy rights.<br><br>If you can't think about much to create in your letter other than "Hi. Online websites sell various kinds of clothing and they are the best spot to start. most; [http://maville.aweb4u.info/lirelasuite.php?url=http://cctvdvrreviews.com maville.aweb4u.info], jenis dvr cctv In simple terms, your essay will be created specifically for each customer, so that is could fulfill the needs and terms of one's order. The following are just several examples of health publications that you just could work for as being a freelance writer. |
| {{cite news|last=Hutchinson|first=Lee |title=New F-1B rocket engine upgrades Apollo-era design with 1.8M lbs of thrust |url=http://arstechnica.com/science/2013/04/new-f-1b-rocket-engine-upgrades-apollo-era-deisgn-with-1-8m-lbs-of-thrust/ |accessdate=2013-04-15 |newspaper=ARS technica |date=2013-04-14 |quote=''The measure of a rocket's fuel efficiency is called its specific impulse (abbreviated as "ISP"—or more properly Isp). ... 'Mass specific impulse...describes the thrust-producing efficiency of a chemical reaction and it is most easily thought of as the amount of thrust force produced by each pound (mass) of fuel and oxidizer propellant burned in a unit of time. It is kind of like a measure of miles per gallon (mpg) for rockets.<nowiki>'</nowiki>''}}</ref>
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| Another number that measures the same thing, usually used for air breathing jet engines, is [[Thrust specific fuel consumption|specific fuel consumption]]. Specific fuel consumption is inversely proportional to specific impulse and effective exhaust velocity.
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| ==General considerations== | |
| The amount of propellant is normally measured either in units of mass or weight. If mass is used, specific impulse is an impulse per unit mass, which [[dimensional analysis]] shows to be a unit of speed, and so specific impulses are often measured in meters per second and are often termed '''effective exhaust velocity'''. However, if propellant weight is used instead, an impulse divided by a force (weight) turns out to be a unit of time, and so specific impulses are measured in seconds. These two formulations are both widely used and differ from each other by a factor of ''[[standard gravity|g]]'', the dimensioned [[Physical constant|constant]] of [[standard gravity|gravitational acceleration]] at the surface of the Earth.
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| Note that the rate of gain of momentum of a rocket (including fuel) per unit time is equal to the thrust.
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| The higher the specific impulse, the less propellant is needed to produce a given thrust during a given time. In this regard a propellant is more efficient if the specific impulse is higher. This should not be confused with energy efficiency, which can even decrease as specific impulse increases, since propulsion systems that give high specific impulse require high energy to do so.<ref>http://www.geoffreylandis.com/laser_ion_pres.htp</ref>
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| In addition it is important that [[thrust]] and specific impulse not be confused with one another. The specific impulse is a measure of the ''impulse per unit of propellant'' that is expended, while thrust is a measure of the momentary or peak force supplied by a particular engine. In many cases, propulsion systems with very high specific impulses—some [[ion thruster]]s reach 10,000 seconds—produce low thrusts.<ref name="exploreMarsnow">{{cite web|url=http://www.exploremarsnow.org/MissionOverview.html|title=Mission Overview|publisher=exploreMarsnow|accessdate=23 December 2009}}</ref>
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| When calculating specific impulse, only propellant that is carried with the vehicle before use is counted. For a chemical rocket the propellant mass therefore would include both fuel and [[oxidizer]]; for air-breathing engines only the mass of the fuel is counted, not the mass of air passing through the engine.
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| ==Units==
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| {| class="wikitable"
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| |+ Imperial and SI units for various rocket motor performance measurements.
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| !
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| ! Specific impulse (by weight)
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| ! Specific impulse (by mass)
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| ! Effective exhaust velocity
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| ! Specific fuel consumption
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| !SI
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| |=X seconds
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| |=(9.8066 X) N•s/kg
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| |=(9.8066 X) m/s
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| |=(101,972/X) g/kN•s
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| |-
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| !Imperial units
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| |=X seconds
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| |=X lbf•s/lb
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| |=(32.16 X) ft/s
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| |=(3,600/X) lb/lbf•h
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| |}
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| By far the most common unit used for specific impulse today is the second, and this is used both in the SI world as well as where Imperial units are used. Its chief advantages are that its units and numerical value are identical everywhere, and essentially everyone understands it. Nearly all manufacturers quote their engine performance in these units and it is also useful for specifying aircraft engine performance.<ref>http://www.grc.nasa.gov/WWW/k-12/airplane/specimp.html</ref>
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| The effective exhaust velocity in units of m/s is also in reasonably common usage. For rocket engines it is reasonably intuitive, although for many rocket engines the effective exhaust speed is considerably different from the actual exhaust speed due to, for example, fuel and oxidizer that is dumped overboard after powering turbo-pumps. For air-breathing engines the effective exhaust velocity is not physically meaningful, although it can be used for comparison purposes nevertheless.<ref>http://www.qrg.northwestern.edu/projects/vss/docs/propulsion/3-what-is-specific-impulse.html</ref>
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| The N•s/kg is not uncommonly seen, and is numerically equal to the effective exhaust velocity in m/s (from [[Newton's second law]] and the definition of the Newton.)
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| Another equivalent unit is [[Thrust specific fuel consumption|specific fuel consumption]]. This has units of g/kN.s or lb/lbf•h and is inversely proportional to specific impulse. Specific fuel consumption is used extensively for describing the performance of air-breathing jet engines.<ref>http://www.grc.nasa.gov/WWW/k-12/airplane/sfc.html</ref>
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| ==Specific impulse in seconds==
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| ===General definition===
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| For all vehicles specific impulse (impulse per unit weight-on-Earth of propellant) in seconds can be defined by the following equation:<ref name=sutton>Rocket Propulsion Elements, 7th Edition by George P. Sutton, Oscar Biblarz</ref>
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| :<math>F_\text{thrust} = I_\text{sp} \cdot \dot m \cdot g_0,</math>
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| where:
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| :<math>F_\text{thrust}</math> is the thrust obtained from the engine, in [[newton (unit)|newton]]s (or [[poundal]]s),
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| :<math>I_\text{sp}</math> is the specific impulse measured in seconds,
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| :<math>\dot m</math> is the [[mass flow rate]] in kg/s (lb/s), which is negative the time-rate of change of the vehicle's mass (since propellant is being expelled),
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| :<math>g_0</math> is the [[Standard gravity|acceleration at the Earth's surface]], in m/s<sup>2</sup> (or ft/s<sup>2</sup>).
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| (When working with [[English unit]]s, it is conventional to divide both sides of the equation by ''g''<sub>0</sub> so that the left-hand side of the equation has units of lbs rather than expressing it in [[poundal]]s.)
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| This ''I<sub>sp</sub>'' expressed in seconds is somewhat physically meaningful—if an engine's thrust could be adjusted to equal the initial weight of its propellant (measured at one [[standard gravity]]), then ''I''<sub>sp</sub> is the duration the propellant would last.{{Citation needed|date=July 2011}}
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| The advantage of this formulation is that it may be used for rockets, where all the reaction mass is carried on board, as well as aeroplanes, where most of the reaction mass is taken from the atmosphere. In addition, it gives a result that is independent of units used (provided the unit of time used is the second).
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| [[Image:Specific-impulse-kk-20090105.png|thumb|center|700px|The specific impulse of various jet engines]]
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| ===Rocketry===
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| In rocketry, where the only reaction mass is the propellant, an equivalent way of calculating the specific impulse in seconds is also frequently used. In this sense, specific impulse is defined as the thrust integrated over time per unit [[weight]]-on-Earth of the propellant:<ref name="SINasa"/>
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| :<math>I_{\rm sp}=\frac{v_{\rm e}}{g_{\rm 0}}</math><ref name="SINasa"/>
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| where
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| ''I''<sub>sp</sub> is the specific impulse measured in seconds
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| <math>v_{\rm e}</math> is the average exhaust speed along the axis of the engine in (ft/s or m/s)
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| ''g<sub>0</sub>'' is the acceleration at the Earth's surface (in ft/s<sup>2</sup> or m/s<sup>2</sup>).
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| In rockets, due to atmospheric effects, the specific impulse varies with altitude, reaching a maximum in a vacuum. This is because the exhaust velocity isn't simply a function of the chamber pressure, but is a function of the difference between the interior and exterior of the combustion chamber. | |
| It is therefore important to note if the specific impulse is vacuum or lower sea level. Values are usually indicated with or near the units of specific impulse (e.g. 'sl', 'vac').
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| ==Specific impulse as a speed (effective exhaust velocity)==
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| Because of the geocentric factor of ''g''<sub>0</sub> in the equation for specific impulse, many prefer to define the specific impulse of a rocket (in particular) in terms of thrust per unit mass flow of propellant (instead of per unit weight flow). This is an equally valid (and in some ways somewhat simpler) way of defining the effectiveness of a rocket propellant. For a rocket, the specific impulse defined in this way is simply the effective exhaust velocity relative to the rocket, v<sub>e</sub>. The two definitions of specific impulse are proportional to one another, and related to each other by:
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| :<math>v_{\rm e} = g_0 I_{\rm sp} \,</math>
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| where
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| :<math>I_{\rm sp} \,</math> - is the specific impulse in seconds
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| :<math>v_{\rm e} \,</math> - is the specific impulse measured in [[metre per second|m/s]], which is the same as the effective exhaust velocity measured in m/s (or ft/s if g is in ft/s<sup>2</sup>)
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| :<math>g_0 \,</math> - is the acceleration due to gravity at the Earth's surface, 9.81 m/s<sup>2</sup> (in [[English units]] units 32.2 ft/s<sup>2</sup>).
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| This equation is also valid for air-breathing jet engines, but is rarely used in practice.
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| (Note that different symbols are sometimes used; for example, ''c'' is also sometimes seen for exhaust velocity. While the symbol <math>I_{sp}</math> might logically be used for specific impulse in units of N•s/kg, to avoid confusion it is desirable to reserve this for specific impulse measured in seconds.)
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| It is related to the [[thrust]], or forward force on the rocket by the equation:
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| :<math>\mathrm{F_{\rm thrust}}=v_{\rm e} \cdot \dot m \,</math><ref>[http://books.google.co.uk/books?id=KEPgEgX2BEEC&lpg=PA68&ots=irB_Z0CinI&dq=effective%20exhaust%20velocity&pg=PA68#v=onepage&q=effective%20exhaust%20velocity&f=false Aerospace Propulsion Systems By Thomas A. Ward]</ref>
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| where
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| :<math>\dot m</math> is the propellant mass flow rate, which is the rate of decrease of the vehicle's mass
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| A rocket must carry all its fuel with it, so the mass of the unburned fuel must be accelerated along with the rocket itself. Minimizing the mass of fuel required to achieve a given push is crucial to building effective rockets. The [[Tsiolkovsky rocket equation]] shows that for a rocket with a given empty mass and a given amount of fuel, the total change in [[velocity]] it can accomplish is proportional to the effective exhaust velocity.
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| A spacecraft without propulsion follows an orbit determined by the gravitational field. Deviations from the corresponding velocity pattern (these are called [[delta v|Δ''v'']]) are achieved by sending exhaust mass in the direction opposite to that of the desired velocity change.
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| ===Actual exhaust speed versus effective exhaust speed===
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| Note that '''effective''' exhaust velocity and '''actual''' exhaust velocity can be significantly different, for example when a rocket is run within the atmosphere, atmospheric pressure on the outside of the engine causes a retarding force that reduces the specific impulse and the effective exhaust velocity goes down, whereas the actual exhaust velocity is largely unaffected. Also, sometimes rocket engines have a separate nozzle for the turbo-pump turbine gas, and then calculating the effective exhaust velocity requires averaging the two mass flows as well as accounting for any atmospheric pressure.{{Citation needed|date=July 2011}}
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| For air-breathing jet engines, particularly [[turbofan]]s, the actual exhaust velocity and the effective exhaust velocity are different by orders of magnitude. This is because a good deal of additional momentum is obtained by using air as reaction mass. This allows for a better match between the airspeed and the exhaust speed which saves energy/propellant and enormously increases the effective exhaust velocity while reducing the actual exhaust velocity.{{Citation needed|date=July 2011}}
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| ==Energy efficiency==
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| ===Rockets===
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| For rockets and rocket-like engines such as ion-drives a higher <math>I_{sp}</math> implies lower energy efficiency: the power needed to run the engine is simply:
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| :<math>\frac {dm} {dt} \frac { v_e^2 } {2}</math>
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| where v<sub>e</sub> is the actual jet velocity.
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| whereas from momentum considerations the thrust generated is:
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| :<math>\frac {dm} {dt} v_e</math>
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| Dividing the power by the thrust to obtain the specific power requirements we get:
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| :<math>\frac {v_e} {2}</math>
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| Hence the power needed is proportional to the exhaust velocity, with higher velocities needing higher power for the same thrust, causing less energy efficiency per unit thrust.
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| However, the total energy for a mission depends on total propellant use, as well as how much energy is needed per unit of propellant. For low exhaust velocity with respect to the mission delta-v, enormous amounts of reaction mass is needed. In fact a very low exhaust velocity is not energy efficient at all for this reason; but it turns out that neither are very high exhaust velocities.
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| Theoretically, for a given [[delta-v]], in space, among all fixed values for the exhaust speed the value <math>v_\text{e}=0.6275 \Delta v</math> is the most energy efficient for a specified (fixed) final mass, see [[Spacecraft_propulsion#Energy|energy in spacecraft propulsion]].
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| However, a variable exhaust speed can be more energy efficient still. For example, if a rocket is accelerated from some positive initial speed using an exhaust speed equal to the speed of the rocket no energy is lost as kinetic energy of reaction mass, since it becomes stationary.<ref>Note that this limits the speed of the rocket to the maximum exhaust speed.</ref> (Theoretically, by making this initial speed low and using another method of obtaining this small speed, the energy efficiency approaches 100%, but requires a large initial mass.) In this case the rocket keeps the same [[momentum]], so its speed is inversely proportional to its remaining mass. During such a flight the kinetic energy of the rocket is proportional to its speed and, correspondingly, inversely proportional to its remaining mass. The power needed per unit acceleration is constant throughout the flight; the reaction mass to be expelled per unit time to produce a given acceleration is proportional to the square of the rocket's remaining mass.
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| Also it is advantageous to expel reaction mass at a location where the [[gravity potential]] is low, see [[Oberth effect]].
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| ===Air breathing===
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| Air-breathing engines such as [[turbojet]]s increase the momentum generated from their propellant by using it to power the acceleration of inert air rearwards. It turns out that the amount of energy needed to generate a particular amount of thrust is inversely proportional to the amount of air propelled rearwards, thus increasing the mass of air (as with a [[turbofan]]) both improves energy efficiency as well as <math>I_{sp}</math>.
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| ==Examples==
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| {{Specific impulse examples}}
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| :''For a more complete list see: [[Spacecraft propulsion#Table of methods]]''
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| An example of a specific impulse measured in time is 453 [[second]]s, which is equivalent to an [[effective exhaust velocity]] of 4,440 [[metre per second|m/s]], for the [[Space Shuttle Main Engine]]s when operating in a vacuum.<ref>http://www.astronautix.com/engines/ssme.htm</ref> An air-breathing jet engine typically has a much larger specific impulse than a rocket; for example a [[turbofan]] jet engine may have a specific impulse of 6,000 seconds or more at sea level whereas a rocket would be around 200–400 seconds.<ref>http://web.mit.edu/16.unified/www/SPRING/propulsion/notes/node85.html</ref>
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| An air-breathing engine is thus much more propellant efficient than a rocket engine, because the actual exhaust speed is much lower, the air provides an oxidizer, and air is used as reaction mass. Since the physical exhaust velocity is lower, the kinetic energy the exhaust carries away is lower and thus the jet engine uses far less energy to generate thrust (at subsonic speeds).<ref>http://www.dunnspace.com/isp.htm</ref> While the '''actual''' exhaust velocity is lower for air-breathing engines, the '''effective''' exhaust velocity is very high for jet engines. This is because the effective exhaust velocity calculation essentially assumes that the propellant is providing all the thrust, and hence is not physically meaningful for air-breathing engines; nevertheless, it is useful for comparison with other types of engines.<ref>http://www.britannica.com/EBchecked/topic/198045/effective-exhaust-velocity</ref>
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| The highest specific impulse for a chemical propellant ever test-fired in a rocket engine was 542 seconds (5,320 m/s) with a [[Tripropellant rocket|tripropellant]] of [[lithium]], [[fluorine]], and [[hydrogen]]. However, this combination is impractical; see [[rocket fuel]].<ref>ARBIT, H. A., CLAPP, S. D., DICKERSON, R. A., NAGAI, C. K., [http://www.aiaa.org/content.cfm?pageid=406&gTable=mtgpaper&gID=40999 Combustion characteristics of the fluorine-lithium/hydrogen tripropellant combination.] AMERICAN INST OF AERONAUTICS AND ASTRONAUTICS, PROPULSION JOINT SPECIALIST CONFERENCE, 4TH, CLEVELAND, OHIO, Jun 10-14, 1968.</ref>
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| [[Nuclear thermal rocket]] engines differ from conventional rocket engines in that thrust is created strictly through thermodynamic phenomena, with no chemical reaction.<ref>http://trajectory.grc.nasa.gov/projects/ntp/index.shtml</ref> The nuclear rocket typically operates by passing hydrogen gas through a superheated nuclear core. Testing in the 1960s yielded specific impulses of about 850 seconds (8,340 m/s), about twice that of the Space Shuttle engines.
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| A variety of other non-rocket propulsion methods, such as [[ion thruster]]s, give much higher specific impulse but with much lower thrust; for example the [[Hall effect thruster]] on the [[SMART-1]] satellite has a specific impulse of 1,640 s (16,100 m/s) but a maximum thrust of only 68 millinewtons.<ref>http://www.mendeley.com/research/characterization-of-a-high-specific-impulse-xenon-hall-effect-thruster/</ref> The [[Variable specific impulse magnetoplasma rocket]] (VASIMR) engine currently in development will theoretically yield 10,000−300,000 m/s but will require a large electricity source and a great deal of heavy machinery to confine even relatively diffuse plasmas, and so will be unusable for high-thrust applications such as launch from planetary surfaces.<ref>http://www.nasa.gov/vision/space/travelinginspace/future_propulsion.html</ref>
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| ===Larger engines===
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| Here are some example numbers for larger jet and rocket engines:
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| {{Thrust engine efficiency}}
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| ===Model rocketry===
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| Specific impulse is also used to measure performance in model rocket motors. Following are some of Estes' claimed values for specific impulses for several of their rocket motors:<ref>Estes 2011 Catalog www.acsupplyco.com/estes/estes_cat_2011.pdf</ref> [[Estes Industries]] is a large, well-known American seller of model rocket components. The specific impulse for these model rocket motors is much lower than for many other rocket motors because the manufacturer uses black powder propellant and emphasizes safety rather than maximum performance. The burn rate and hence chamber pressure and maximum thrust of model rocket motors is also tightly controlled.
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| {| class="wikitable"
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| |-
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| |+ align="bottom" style="caption-side: bottom" | Specific impulses for several commercially available Estes rocket motors.
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| ! rowspan="1"|Engine||Total impulse (Ns)||Fuel weight (N)||Specific impulse (s)
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| |-----
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| | Estes A10-3T ||2.5||0.0370||67.49
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| |-----
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| | Estes A8-3 ||2.5||0.0306||81.76
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| |-----
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| | Estes B4-2 ||5.0||0.0816||61.25
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| |-----
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| | Estes B6-4 ||5.0||0.0612||81.76
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| |-----
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| | Estes C6-3 ||10||0.1223||81.76
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| |-----
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| | Estes C11-5 ||10||0.1078||92.76
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| |-----
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| | Estes D12-3 ||20||0.2443||81.86
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| |-----
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| | Estes E9-6||30||0.3508||85.51
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| |}
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| ==See also==
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| {{div col}}
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| *[[Jet engine]]
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| *[[Impulse (physics)|Impulse]]
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| *[[Tsiolkovsky rocket equation]]
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| *[[System-specific impulse]]
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| *[[Specific energy]]
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| *[[Thrust specific fuel consumption]] - fuel consumption per unit thrust
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| *[[Specific thrust]] - thrust per unit of air for a duct engine
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| *[[Heating value]]
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| *[[Energy density]]
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| *[[Delta-v (physics)]]
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| *[[Rocket propellant]]
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| *[[Liquid rocket propellants]]
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| {{div col end}}
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| ==References==
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| {{Reflist|2}}
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| ==External links==
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| *[http://software.lpre.de/ RPA - Design Tool for Liquid Rocket Engine Analysis]
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| *[http://www.braeunig.us/space/propel.htm List of Specific Impulses of various rocket fuels]
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| {{Use dmy dates|date=July 2011}}
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| {{DEFAULTSORT:Specific Impulse}}
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| <!--Categories-->
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| [[Category:Rocket propulsion]]
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| [[Category:Spacecraft propulsion]]
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| [[Category:Physical quantities]]
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| [[Category:Classical mechanics]]
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| [[Category:Engine technology]]
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