Neutronics Calculation Advances at Los Alamos: Manhattan Project to Monte Carlo

Sood, Avneet; Forster, Robert; Archer, B. J.; Little, Robert C.

doi:10.1080/00295450.2021.1956255

Cited by 6 publications

(3 citation statements)

References 49 publications

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“…It was, because these cross sections then became available for use use in accurate simulation codes. 113 Their use extended well beyond addressing the original critical mass question. The rapidly-improving neutronics simulation capability opened up the ability to rapidly explore a wealth of physics questions, to advance the technologies in both defense and civilian nuclear power arenas.…”

Section: Discussionmentioning

confidence: 99%

“…The best value today from a ENDF/B-VIII.0 and MCNP6 Monte Carlo transport calculation, 46.4±1.7 kg, is shown as a horizontal line in Figure 23. The figure also shows an accurately-calculated value of 45 kg obtained in 1952 by Bengt Carlson 112 using the Serber-Wilson neutron diffusion method 113 with three neutron energy groups (an approach that was developed by the US and the British during the Manhattan Project, 1944Project, -1945. Note that Carlson and Wilson both had connections with the Montreal/Chalk River Manhattan Project laboratories as described in this issue by Andrews, Andrews and Mason; 114 Carlson came to Los Alamos in 1945, where he spent the rest of his career.…”

Section: Criticality Uncertainty Reductionmentioning

confidence: 99%

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Nuclear Science for the Manhattan Project and Comparison to Today’s ENDF Data

Chadwick

2021

Nuclear Technology

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Nuclear physics advances in the US and Britain, from 1939-1945, are described. The Manhattan Project's work led to an explosion in our knowledge of nuclear science. A conference in April 1943 at Los Alamos provided a simple formula used to compute critical masses, and laid out the research program needed to determine the key nuclear constants. In short order, four university accelerators were disassembled and reassembled at Los Alamos, and methods were established to make measurements on extremely small samples owing to the initial lack of availability of enriched 235 U and plutonium. I trace the program that measured fission cross sections, fission emitted neutron multiplicities and their energy spectra, and transport cross sections, comparing the measurements with our best understanding today as embodied in the Evaluated Nuclear Data File ENDF/B-VIII.0. The large nuclear data uncertainties at the beginning of the project, which often exceeded 25-50%, were reduced by 1945 often to less than 5-10%. 235 U and 239 Pu fission cross section assessments in the fast MeV range were reduced with more accurate measurements, and the neutron multiplicity ν increased. By a lucky coincidence of canceling errors, the initial critical mass estimates were close to the final estimated masses. Some images from historical documents from our Los Alamos archives are shown. Many of the original measurements from these early years have not previously been widely available. Through this work, these data have now been archived in the international experimental nuclear reaction data library (EXFOR) in a collaboration with the IAEA and Brookhaven National Laboratory. ContentsI.

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Section: Discussionmentioning

confidence: 99%

Section: Criticality Uncertainty Reductionmentioning

confidence: 99%

Nuclear Science for the Manhattan Project and Comparison to Today’s ENDF Data

Chadwick

2021

Nuclear Technology

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“…8 The Theoretical Division under Hans Bethe's leadership played a central role in advancing the basic science studied during the Manhattan Project. These include shock hydrodynamics (Morgan and Archer, 9 this issue) and neutronics (Sood et al,10 this issue). Bethe and Feynman, both future Nobel laureates, developed an important equation for predicting the expected nuclear fission efficiency, as described by Lestone.…”

Section: All Possible Prioritymentioning

confidence: 99%

Thirty Minutes Before the Dawn

Carr

2021

Nuclear Technology

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The Trinity test of July 16, 1945, marked the scientific apex of the Manhattan Project. Often recognized as the symbolic birth of the nuclear age, Trinity's multifaceted legacy remains just as captivating and complex today as it did 75 years ago. This paper examines why the test was necessary from a technical standpoint, shows how Los Alamos scientists planned the event, and explores the physical and emotional aftermaths of Trinity. The author also uses rarely accessed original records to reconstruct the story of Trinity's health hazards, as seen through the eyes of radiation technicians and medical doctors as events unfolded.Trinity was conducted as the Potsdam Conference began, weeks after the collapse of Nazi Germany. It was considered necessary to let President Harry S. Truman know whether the United States possessed a nuclear capability ahead of his negotiations with Joseph Stalin, the Soviet premier. The author examines the competing priorities that drove the timetable for the test: international politics, security, and safety. Three weeks after Trinity, a gun-assembled enriched-uranium bomb called Little Boy was used against the Japanese city of Hiroshima. Three days later, Fat Man, a weaponized version of the imploding Trinity device, was dropped on Nagasaki. The author briefly examines these strikes and what impact they may have had on the Japanese surrender. The paper concludes by examining the legacy of the Trinity test 75 years into the age it helped usher in.

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Introduction

Dunn¹,

Shultis²

2023

Exploring Monte Carlo Methods

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Neutronics Calculation Advances at Los Alamos: Manhattan Project to Monte Carlo

Cited by 6 publications

References 49 publications

Nuclear Science for the Manhattan Project and Comparison to Today’s ENDF Data

Nuclear Science for the Manhattan Project and Comparison to Today’s ENDF Data

Thirty Minutes Before the Dawn

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