Editing Prompt criticality

{{Short description|Sustained nuclear fission achieved solely by prompt neutron emission}}
{{Use dmy dates|date=May 2018}}
In [[nuclear engineering]], '''prompt criticality''' describes a [[nuclear fission]] event in which [[Critical mass|criticality]] (the threshold for an exponentially growing nuclear fission chain reaction) is achieved with [[prompt neutron]]s alone and does not rely on [[delayed neutron]]s.  As a result, prompt supercriticality causes a much more rapid growth in the rate of energy release than other forms of criticality.  [[Nuclear weapon]]s are based on prompt criticality, while nuclear reactors rely on delayed neutrons or external neutrons to achieve criticality.

== Criticality ==
An assembly is critical if each fission event causes, on average, exactly one additional such event in a continual chain.  Such a chain is a self-sustaining fission [[nuclear chain reaction|chain reaction]]. When a [[uranium]]-235 (U-235) atom undergoes [[nuclear fission]], it typically releases between one and seven [[neutrons]] (with an average of 2.4). In this situation, an assembly is critical if every released neutron has a <sup>1</sup>/<sub>2.4</sub> = 0.42 = 42&nbsp;% probability of causing another fission event as opposed to either being absorbed by a non-fission [[Neutron capture|capture event]] or escaping from the fissile core.

The average number of neutrons that cause new fission events is called the [[nuclear chain reaction|effective neutron multiplication factor]], usually denoted by the symbols ''k-effective'', ''k-eff'' or ''k''. When ''k-effective'' is equal to 1, the assembly is called critical, if ''k-effective'' is less than 1 the assembly is said to be subcritical, and if ''k-effective'' is greater than 1 the assembly is called supercritical.

== Critical versus prompt-critical ==
In a supercritical assembly, the number of fissions per unit time, ''N'', along with the power production, increases [[Exponential growth|exponentially]] with time.  How fast it grows depends on the average time it takes, ''T'', for the neutrons released in a fission event to cause another fission.  The growth rate of the reaction is given by:

: <math>N(t) = N_0 k^\frac{t}{T} \,</math>

Most of the neutrons released by a fission event are the ones released in the fission itself.  These are called prompt neutrons, and strike other nuclei and cause additional fissions within [[nanosecond]]s (an average time interval used by scientists in the [[Manhattan Project]] was one [[shake (unit)|shake]], or 10&nbsp;ns).  A small additional source of neutrons is the [[fission product]]s.  Some of the nuclei resulting from the fission are [[radioactive isotope]]s with short [[Half-life|half-lives]], and [[nuclear reaction]]s among them release additional neutrons after a long delay of up to several minutes after the initial fission event.  These neutrons, which on average account for less than one percent of the total neutrons released by fission, are called delayed neutrons. The relatively slow timescale on which delayed neutrons appear is an important aspect for the design of nuclear reactors, as it allows the reactor power level to be controlled via the gradual, mechanical movement of control rods. Typically, control rods contain neutron poisons (substances, for example [[boron]] or [[hafnium]], that easily capture neutrons without producing any additional ones) as a means of altering ''k-effective''. With the exception of experimental pulsed reactors, nuclear reactors are designed to operate in a delayed-critical mode and are provided with safety systems to prevent them from ever achieving prompt criticality.
[[File:Criticality Diagram.png|thumb|Diagram explaining criticality types. <math>k_{\mathrm{eff}}</math> is the [[effective neutron multiplication factor]].]]
In a [[delayed criticality|delayed-critical]] assembly, the delayed neutrons are needed to make ''k-effective'' greater than one.  Thus the time between successive generations of the reaction, ''T'', is dominated by the time it takes for the delayed neutrons to be released, of the order of seconds or minutes.  Therefore, the reaction will increase slowly, with a long time constant.  This is slow enough to allow the reaction to be controlled with [[electromechanical]] [[control system]]s such as [[control rod]]s, and accordingly all [[nuclear reactor]]s are designed to operate in the delayed-criticality regime.

In contrast, a critical assembly is said to be prompt-critical if it is critical (''k&nbsp;=&nbsp;1'') without any contribution from [[delayed neutron]]s and prompt-supercritical if it is supercritical (the fission rate growing exponentially, ''k&nbsp;>&nbsp;1'') without any contribution from delayed neutrons.  In this case the time between successive generations of the reaction, ''T'', is limited only by the fission rate from the prompt neutrons, and the increase in the reaction will be extremely rapid, causing a rapid release of energy within a few milliseconds.  Prompt-critical assemblies are created by design in [[nuclear weapon]]s and some specially designed research experiments.

The difference between a prompt neutron and a delayed neutron has to do with the source from which the neutron has been released into the reactor. The neutrons, once released, have no difference except the energy or speed that have been imparted to them. A nuclear weapon relies heavily on prompt-supercriticality (to produce a high peak power in a fraction of a second), whereas nuclear power reactors use delayed-criticality to produce controllable power levels for months or years.

== Nuclear reactors ==
In order to start up a controllable fission reaction, the assembly must be delayed-critical. In other words, ''k'' must be greater than 1 (supercritical) without crossing the prompt-critical threshold. In nuclear reactors this is possible due to delayed neutrons. Because it takes some time before these neutrons are emitted following a fission event, it is possible to control the nuclear reaction using control rods.

A steady-state (constant power) reactor is operated so that it is critical due to the delayed neutrons, but would not be so without their contribution. During a gradual and deliberate increase in reactor power level, the reactor is delayed-supercritical. The exponential increase of reactor activity is slow enough to make it possible to control the criticality factor, ''k'', by inserting or withdrawing rods of neutron absorbing material. Using careful control rod movements, it is thus possible to achieve a supercritical reactor core without reaching an unsafe prompt-critical state.

Once a reactor plant is operating at its target or design power level, it can be operated to maintain its critical condition for long periods of time.

=== Prompt critical accidents ===
{{main article|Criticality accident}}
Nuclear reactors can be susceptible to prompt-criticality accidents if a large increase in reactivity (or ''k-effective'') occurs, e.g., following failure of their control and safety systems. The rapid uncontrollable increase in reactor power in prompt-critical conditions is likely to irreparably damage the reactor and in extreme cases, may breach the containment of the reactor. Nuclear reactors' safety systems are designed to prevent prompt criticality and, for [[Defense in depth (nuclear engineering)|defense in depth]], reactor structures also provide multiple layers of containment as a precaution against any accidental releases of [[radioactive]] [[fission products]].

With the exception of research and experimental reactors, only a small number of reactor accidents are thought to have achieved prompt criticality, for example [[Chernobyl disaster|Chernobyl #4]], the U.S. Army's [[SL-1]], and [[Soviet submarine K-431]]. In all these examples the uncontrolled surge in power was sufficient to cause an explosion that destroyed each reactor and released [[radioactive]] fission products into the atmosphere.

At Chernobyl in 1986, a poorly understood positive [[scram]] effect resulted in an overheated reactor core. This led to the rupturing of the fuel elements and water pipes, vaporization of water, a [[steam explosion]], and a graphite fire. Estimated power levels prior to the incident suggest that it operated in excess of 30 GW, ten times its 3 GW maximum thermal output. The reactor chamber's 2000-ton lid was lifted by the steam explosion. Since the reactor was not designed with a [[containment building]] capable of containing this catastrophic explosion, the accident released large amounts of radioactive material into the environment. 

In the other two incidents, the reactor plants failed due to errors during a maintenance shutdown that was caused by the rapid and uncontrolled removal of at least one control rod. The [[SL-1]] was a prototype reactor intended for use by the US Army in remote polar locations. At the SL-1 plant in 1961, the reactor was brought from shutdown to prompt critical state by manually extracting the central control rod too far. As the water in the core quickly converted to steam and expanded (in just a few milliseconds), the {{convert|26000|lb|kg|adj=on}} reactor vessel jumped {{convert|9|ft|1|in|m}}, leaving impressions in the ceiling above.<ref name="Tucker">{{cite book |last=Tucker |first=Todd |title=Atomic America: How a Deadly Explosion and a Feared Admiral Changed the Course of Nuclear History |isbn=978-1-4165-4433-3 |year=2009 |publisher=Free Press |location=New York |url-access=registration |url=https://archive.org/details/atomicamericahow00todd }} See summary: [http://catdir.loc.gov/catdir/enhancements/fy0904/2008013842-s.html] {{Webarchive|url=https://web.archive.org/web/20110721044652/http://catdir.loc.gov/catdir/enhancements/fy0904/2008013842-s.html |date=21 July 2011 }}</ref><ref name=ProvePrinciple15>{{cite book
  | last =Stacy
  | first =Susan M.
  | title =Proving the Principle: A History of The Idaho National Engineering and Environmental Laboratory, 1949–1999
  | publisher =[[U.S. Department of Energy]], Idaho Operations Office
  | date =2000
  | pages =138–149
  | chapter =Chapter 15: The SL-1 Incident
  | chapter-url =http://www4vip.inl.gov/publications/d/proving-the-principle/chapter_15.pdf
  | isbn =978-0-16-059185-3
  | access-date =8 September 2015
  | archive-date =29 December 2016
  | archive-url =https://web.archive.org/web/20161229141617/http://www4vip.inl.gov/publications/d/proving-the-principle/chapter_15.pdf
  | url-status =live
  }}</ref> All three men performing the maintenance procedure died from injuries. 1,100 curies of fission products were released as parts of the core were expelled. It took 2 years to investigate the accident and clean up the site. The excess prompt reactivity of the SL-1 core was calculated in a 1962 report:<ref>[http://www.id.doe.gov/foia/PDF/IDO-19313.pdf IDO-19313] {{webarchive|url=https://web.archive.org/web/20110927065809/http://www.id.doe.gov/foia/PDF/IDO-19313.pdf |date=27 September 2011 }} ''Additional Analysis of the SL-1 Excursion, Final Report of Progress July through October 1962'', November 1962.</ref>

{{Quote|The delayed neutron fraction of the SL-1 is 0.70%... Conclusive evidence revealed that the SL-1 excursion was caused by the partial withdrawal of the central control rod. The reactivity associated with the 20-inch withdrawal of this one rod has been estimated to be 2.4% δk/k, which was sufficient to induce prompt criticality and place the reactor on a 4 millisecond period.}}

In the ''K-431'' reactor accident, 10 were killed during a refueling operation. The ''K-431'' explosion destroyed the adjacent machinery rooms and ruptured the submarine's hull. In these two catastrophes, the reactor plants went from complete shutdown to extremely high power levels in a fraction of a second, damaging the reactor plants beyond repair.

==List of accidental prompt critical excursions==
A number of research reactors and tests have purposely examined the operation of a prompt critical reactor plant. [[CRAC-II|CRAC]], [[Kinetics Experiment Water Boiler reactor|KEWB]], [[SPERT-I]], [[Godiva device]], and [[BORAX experiments]] contributed to this research. Many accidents have also occurred, however, primarily during research and processing of nuclear fuel. SL-1 is the notable exception.

The following list of prompt critical power excursions is adapted from a report submitted in 2000 by a team of American and Russian nuclear scientists who studied [[criticality accident]]s, published by the Los Alamos Scientific Laboratory, the location of many of the excursions.<ref>''[https://web.archive.org/web/*/http://www.csirc.net/docs/reports/la-13638.pdf A Review of Criticality Accidents]'', Los Alamos National Laboratory, LA-13638, May 2000. Thomas P. McLaughlin, Shean P. Monahan, Norman L. Pruvost, Vladimir V. Frolov, Boris G. Ryazanov, and Victor I. Sviridov.</ref> A typical power excursion is about 1 x 10<sup>17</sup> fissions.
* [[Harry Daghlian#Criticality accident|Los Alamos Scientific Laboratory]], 21 August 1945
* [[Louis Slotin#Criticality accident|Los Alamos Scientific Laboratory]], 21 May 1946
* Los Alamos Scientific Laboratory, December 1949, 3 or 4 x 10<sup>16</sup> fissions
* Los Alamos Scientific Laboratory, 1 February 1951
* Los Alamos Scientific Laboratory, 18 April 1952
* Argonne National Laboratory, 2 June 1952
* Oak Ridge National Laboratory, 26 May 1954
* Oak Ridge National Laboratory, 1 February 1956
* Los Alamos Scientific Laboratory, 3 July 1956
* Los Alamos Scientific Laboratory, 12 February 1957
* [[Mayak Production Association]], 2 January 1958
* [[Y-12 National Security Complex|Oak Ridge Y-12 Plant]], 16 June 1958 (possible)
* Los Alamos Scientific Laboratory, [[Cecil Kelley criticality accident]], 30 December 1958
* [[SL-1]], 3 January 1961, 4 x 10<sup>18</sup> fissions or {{convert|130|MJ|kWh}}
* [[Idaho Chemical Processing Plant]], 25 January 1961
* Los Alamos Scientific Laboratory, 11 December 1962
* [[Sarov]] (Arzamas-16), 11 March 1963
* [[White Sands Missile Range]], 28 May 1965
* Oak Ridge National Laboratory, 30 January 1968
* [[Chelyabinsk-70]], 5 April 1968
* [[Aberdeen Proving Ground]], 6 September 1968
* Mayak Production Association, 10 December 1968 (2 prompt critical excursions)
* [[Kurchatov Institute]], 15 February 1971
* Idaho Chemical Processing Plant, 17 October 1978 (very nearly prompt critical)
* [[Soviet submarine K-431]], 10 August 1985<!-- Or was there a reason why K-431 was not included here? -->
* [[Chernobyl disaster]], 26 April 1986<!-- Or was there a reason why Chernobyl was not included here? -->
* Sarov (Arzamas-16), 17 June 1997
* [[Tokaimura nuclear accident|JCO Fuel Fabrication Plant]], 30 September 1999

== Nuclear weapons ==
{{main article|Nuclear weapon design}}
In the design of [[nuclear weapon]]s, in contrast, achieving prompt criticality is essential. Indeed, one of the design problems to overcome in constructing a bomb is to compress the fissile materials enough to achieve prompt criticality before the chain reaction has a chance to produce enough energy to cause the core to expand too much.  A good bomb design must therefore win the race to a dense, prompt critical core before a less-powerful chain reaction disassembles the core without allowing a significant amount of fuel to fission (known as a [[Fizzle (nuclear test)|fizzle]]). This generally means that nuclear bombs need special attention paid to the way the core is assembled, such as the [[Implosion-type nuclear weapon|implosion]] method invented by [[Richard C. Tolman]], [[Robert Serber]], and other scientists at the [[University of California, Berkeley]] in 1942.

==See also==
* [[Subcritical reactor]]
* [[Thermal neutron]]
* [[Void coefficient]]

== References and links ==
{{Reflist}}

: * <!-- Unlinked orphan reference to be first cited with a tags couple <ref> </ref> in the body of the text at the right place -->[https://web.archive.org/web/20050419134919/http://www.mans.eun.eg/facscim/PhyDept/reactor/ "Nuclear Energy: Principles"], Physics Department, Faculty of Science, Mansoura University, Mansoura, Egypt; apparently excerpted from notes from the University of Washington Department of Mechanical Engineering; themselves apparently summarized from Bodansky, D. (1996), ''Nuclear Energy: Principles, Practices, and Prospects'', AIP

== Further reading ==
* [https://www.standards.doe.gov/standards-documents/1000/1013-bhdbk-1992-v2/@@images/file ''DOE Fundamentals Handbook, Instrumentation and Control'', Volume 2 of 2. DOE-HDBK-1013/2-92 (June 1992).]

[[Category:Nuclear technology]]
[[Category:Nuclear physics|Prompt critical]]
[[Category:Nuclear weapon design]]