Operation Teapot
Operation Teapot was a series of 14 nuclear detonations conducted by the United States at the Nevada Test Site from February 18 to May 15, 1955.[1] The operation focused on proof-testing a variety of compact fission devices with yields ranging from 1.2 kilotons to 43 kilotons, including spherical and linear implosion designs, some with deuterium-tritium boosting and specialized initiators.[1][2] The primary objectives included evaluating these devices for tactical roles such as air defense, anti-submarine warfare, and atomic demolition munitions, as well as assessing weapons effects on aircraft structures, cratering efficiency, and military equipment.[1] Over 11,000 Department of Defense personnel participated, with approximately 8,000 troops conducting Exercise Desert Rock VI to train in simulated nuclear battlefield conditions and observe blast, thermal, and radiation impacts.[2] Key shots encompassed the first successful UCRL linear implosion device (Tesla, 7 kilotons) and the highest-yield test (Turk, 43 kilotons), which explored thermonuclear primary concepts.[1][2] Notable for pioneering compact boosted primaries and dual-detonation events, such as Apple-1 and Wasp Prime on March 29, Operation Teapot advanced U.S. tactical nuclear capabilities amid Cold War pressures, though it exposed participants to ionizing radiation levels that later raised health concerns based on dosimetry data.[1][2]
Historical and Strategic Context
Cold War Imperatives Driving Tactical Nuclear Development
The perceived conventional military superiority of the Soviet Union and its Warsaw Pact allies in Europe during the early Cold War era necessitated innovative deterrence strategies for the United States and NATO, as Warsaw Pact forces maintained approximately 175 divisions compared to NATO's roughly 25 active divisions by the mid-1950s.[3] This numerical disparity, coupled with the Soviet acquisition of nuclear capabilities following their first atomic test in 1949, compelled U.S. policymakers to prioritize cost-effective means of offsetting potential ground invasions without relying solely on high-yield strategic bombers or intercontinental missiles.[4] Tactical nuclear weapons, designed for yields in the kiloton range suitable for battlefield deployment via artillery, aircraft, or demolition munitions, emerged as a response to enable flexible, localized responses that could disrupt massed enemy armor and infantry formations while avoiding immediate escalation to all-out nuclear war.[5] President Dwight D. Eisenhower's "New Look" national security policy, formalized in 1953, institutionalized this shift by emphasizing massive nuclear retaliation and airpower over expansive conventional forces, aiming for "more bang for the buck" through cheaper nuclear production rather than maintaining large standing armies.[6] Under this doctrine, tactical nuclear armaments were integrated into forward-deployed units, such as fighter wings and artillery batteries, to bolster NATO's defensive posture in Central Europe, where short-range delivery systems could provide disproportionate firepower against Soviet numerical advantages.[7] Eisenhower explicitly endorsed their operational use, stating in March 1955 that such weapons should be employed "exactly as you would use a bullet or anything else," reflecting a view of them as extensions of conventional firepower rather than taboo escalatory tools.[8] Operation Teapot, conducted from February to May 1955 at the Nevada Test Site, directly advanced these imperatives by proof-testing compact fission devices optimized for tactical applications, including yields as low as 1 kiloton for potential atomic demolition munitions and air-dropped bombs.[9] The series' military effects tests, specified by the Department of Defense, evaluated blast, thermal, and radiation impacts on equipment, structures, and personnel to refine ground force tactics in nuclear environments, ensuring weapons could neutralize armored divisions or fortified positions with minimal strategic fallout.[1] This development was driven by the causal necessity of credible battlefield options to deter Soviet adventurism, as unproven or unreliable tactical systems risked undermining NATO cohesion and inviting conventional overruns.[10]Transition from Operation Castle and Prior Atmospheric Tests
Operation Castle, conducted from March 1 to May 27, 1954, at the Pacific Proving Grounds, marked a milestone in thermonuclear weapon development with tests of multi-megaton dry-fuel designs, but its high yields—peaking at 15 megatons for Shot Bravo—and associated fallout incidents underscored the complexities of large-scale atmospheric detonations over oceanic sites.[11][12] This series shifted national priorities toward refining strategic capabilities, yet it created a pause in continental United States testing during 1954, following the higher-yield Nevada-based Operation Upshot–Knothole of 1953, which included detonations up to 61 kilotons and emphasized effects on structures and personnel.[10] The return to the Nevada Test Site for Operation Teapot on February 18, 1955, represented a deliberate pivot to smaller-scale atmospheric tests, prioritizing proof-of-concept for low-yield fission and boosted-fission devices suited to tactical battlefield roles rather than megaton strategic bombers.[9] Teapot's 14 detonations, with yields ranging from 1 to 43 kilotons, addressed military demands for weapons integrable into conventional forces, such as atomic artillery projectiles, demolition munitions, and air-dropped systems for ground troop support—contrasting Castle's oceanic logistics and strategic focus.[10][9] This transition facilitated direct observation and data collection on nuclear effects in continental environments, enabling real-time tactical exercises under Exercise Desert Rock VI, which involved approximately 8,000 Department of Defense personnel from Army, Navy, Marine Corps, and Air Force units to train in maneuvers amid blast, thermal, and radiological hazards.[10] Prior Nevada series had laid groundwork for fallout prediction and shielding assessments, but Teapot intensified these through dedicated projects like WT-1121-EX on radiological safety and field evaluations of equipment resilience, building causal understanding of sub-50-kiloton bursts on armored vehicles and infantry formations.[10] The doctrinal shift emphasized causal realism in nuclear warfare planning: smaller yields minimized unpredictable fallout dispersion compared to Castle's megaton events, while allowing validation of weapon reliability for prompt delivery systems like aircraft-dropped or artillery-fired rounds, informed by empirical data from tower, balloon, and surface bursts at NTS.[9] Overall, involving over 11,000 DOD participants, Teapot bridged strategic thermonuclear advances with operational tactics, prioritizing verifiable performance metrics for arsenal integration over exploratory high-yield experimentation.[10]Objectives and Technical Preparations
Primary Goals for Fission Device Proof-Testing
The fission device proof-testing in Operation Teapot sought to validate the design integrity, yield predictability, and operational reliability of low-yield nuclear weapons tailored for tactical battlefield deployment, including air defense, anti-submarine warfare, and atomic demolition applications.[1] These tests confirmed performance across yields from 1.2 kilotons (Wasp and Ess shots) to 43 kilotons (Turk shot), focusing on fission efficiency derived from implosion mechanics rather than fusion boosting predominant in prior strategic tests.[1][10] Central to these goals was the evaluation of innovative fission primaries, such as compact spherical implosion systems with beryllium tampers, hollow-pit cores for reduced weight, and deuterium-tritium boosting to increase yield without proportionally larger fissile material inventories.[1] Proof-testing incorporated neutron pulse tubes to ensure symmetric compression and ignition, addressing challenges in miniaturization for delivery via artillery, missiles, or aircraft.[1] Devices like the XW-30 warhead were certified through comparative unboosted (2 kt) and boosted (4 kt) configurations, verifying enhancements in energy output for tactical scenarios.[1] Linear implosion variants were proofed in shots such as Tesla (7 kt) and Post (2 kt) to assess manufacturability and performance simplifications suitable for mass production of field-deployable munitions.[1] These efforts extended to developing reliable fission triggers for emerging thermonuclear systems, including Class D weapons like XW-27 and XW-30, by isolating and quantifying primary-stage outputs under tower, surface, and subsurface bursts.[1][13] Radiochemical analysis of fission products from detonations provided empirical data on actual versus predicted yields and material utilization, enabling refinements in core composition and reflector designs for stockpile integration.[10] Los Alamos Scientific Laboratory oversaw nine devices, while University of California Radiation Laboratory handled three, ensuring comprehensive coverage of prototype variants prior to tactical weaponization.[10] This proof-testing phase prioritized causal validation of device physics over ancillary effects, though integrated with broader assessments of delivery system compatibility.[13]Organizational Structure and Key Participants
Operation Teapot was directed by the U.S. Atomic Energy Commission (AEC), which held primary responsibility for planning, execution, and oversight of the nuclear test series at the Nevada Test Site from February 18 to May 15, 1955.[9] The AEC appointed a Test Manager to coordinate all activities, including device assembly, detonation scheduling, and data collection, drawing on personnel from the AEC's Santa Fe Operations Office Test Division.[14] This structure ensured compliance with safety protocols and alignment with national security objectives, such as validating low-yield fission weapons for tactical applications.[15] A Joint Test Organization (JTO) facilitated collaboration among the AEC, Department of Defense (DoD), and Federal Civil Defense Administration (FCDA), with operational charts delineating responsibilities for logistics, instrumentation, and post-detonation analysis.[14] The DoD contributed extensively through Exercise Desert Rock VI and specialized projects, involving an estimated 11,000 military and civilian personnel across observer programs, simulated ground maneuvers, and effects assessments on equipment and troops.[10] Specific shots, such as WASP, TESLA, TURK, BEE, ESS, APPLE-1, MET, and APPLE-2, each incorporated over 500 DoD participants to evaluate blast, thermal, and radiation impacts on military hardware and tactics.[9] Weapon design and proof-testing were led by the Los Alamos Scientific Laboratory (LASL), which developed the boosted fission devices central to the series, focusing on yields ranging from 1 to 43 kilotons for Army and Air Force stockpiles.[16] Sandia Corporation supported non-nuclear components and delivery systems integration, while the U.S. Army Ordnance Corps and Air Force handled field deployment simulations.[17] This division of labor reflected the interagency emphasis on transitioning from strategic to tactical nuclear capabilities amid Cold War pressures.[18]Execution of the Test Series
Nevada Test Site Logistics and Safety Protocols
The Nevada Test Site (NTS), renamed from the Nevada Proving Ground during the series, hosted Operation Teapot's 14 detonations across Yucca Flat and Frenchman Flat from February to May 1955.[19] Nuclear devices were airlifted from Los Alamos National Laboratory via C-47 aircraft operated by Carco Air Service, with regular shuttle flights between Las Vegas and the Mercury base camp.[14] Installation logistics included erecting towers 300 to 500 feet high for elevated shots, preparing airdrop configurations, or emplacing subsurface devices, such as the 67-foot-deep burial for Shot ESS by the 271st Engineer Combat Battalion.[19][14] Approximately 11,000 personnel participated, supported by 837 motor vehicles logging 5.5 million miles, 1,250 work orders from 46 agencies for instrumentation and setup, and communication networks with over 230 VHF-FM mobile units, 45 base stations, and additional HF-AM radios for coordination.[19][14] Radiological safety was directed by Test Director J. C. Clark, with Lt. Col. Tom D. Collison as On-site Rad-Safe Officer commanding a group of 30 officers and about 120 enlisted from the 1st Rad-Safe Support Unit.[20] Exposure limits were set at 3.9 roentgens, though 56 personnel exceeded this threshold, receiving up to 19.3 roentgens, representing 0.5% of participants monitored via 35,000 to 50,000 film badges and pocket dosimeters.[20] Protective measures included issuing coveralls, respirators, rubber gloves, and other gear, with decontamination at checkpoints using steam, hot soapy water, and brushing to reduce contamination below thresholds like 7 mR/hr on outer clothing.[20] Contaminated areas were demarcated by radiation intensity (e.g., signs at 10 mR/hr and 100 mR/hr lines), access controlled via permits post-briefing, and equipment stored in "hot parks" if exceeding safe levels for shipment under Interstate Commerce Commission regulations.[20] Monitoring protocols featured initial post-shot surveys by ground teams (4-5 per operation) and helicopters using instruments like AN/PDR-39 and MX-5, producing 64 isointensity maps and supporting 1,165 entry parties.[20] Off-site efforts employed 4 to 6 mobile teams of two for fallout surveys, augmented by 24 air sampling stations, water and milk sampling in nearby towns, and low-level aerial reconnaissance with B-50 and B-25 aircraft.[14] Evacuation criteria included projected doses over 50 roentgens estimated biological dose or indoor sheltering at gamma rates like 2,000 mR/hr at one hour post-detonation; troops were relocated from fallout paths, such as to 14 kilometers south for Shot WASP observers.[14][19] Health physics training encompassed two 4-day courses for 105 attendees and seven 1-day sessions for 227, ensuring proficiency among roughly 400 monitors, while Desert Rock exercises capped troop exposure at 6 roentgens per test.[20][14]Chronological Overview of the 14 Detonations
Operation Teapot encompassed 14 nuclear detonations at the Nevada Test Site from February 18 to May 15, 1955, focusing on proof-testing low- to moderate-yield fission devices for tactical applications. These shots varied in yield from 1 to 43 kilotons, employing methods such as airdrops, tower detonations, and one subsurface burst to evaluate weapon performance, blast effects, and fallout patterns under diverse configurations.[21][9] The detonations proceeded as follows:| Shot Name | Date | Yield (kt) | Detonation Method | Location (NTS Area) | Notes |
|---|---|---|---|---|---|
| Wasp | February 18, 1955 | 1 | Airdrop (762 ft) | 7, Yucca Flat | Initial weapons effects test; observed by over 900 troops from safe distance.[9] |
| Moth | February 22, 1955 | 2 | Tower (300 ft) | 3, Yucca Flat | Weapons-related evaluation.[21] |
| Tesla | March 1, 1955 | 7 | Tower (300 ft) | 9, Yucca Flat | Yield exceeded predictions; observed by approximately 600 troops.[9][21] |
| Turk | March 7, 1955 | 43 | Tower (500 ft) | 2, Yucca Flat | Highest yield in series; fallout-directed observation by 500 troops.[9][21] |
| Hornet | March 12, 1955 | 4 | Tower (300 ft) | 3, Yucca Flat | Weapons-related test.[21] |
| Bee | March 22, 1955 | 8 | Tower (500 ft) | 7, Yucca Flat | Involved Marine Brigade maneuvers with helicopter elements; observed by 3,000 troops.[9][21] |
| Ess | March 23, 1955 | 1 | Subsurface (-67 ft) | 10, Yucca Flat | Created 88 m crater; first subsurface shot for atomic demolition munition effects.[9][21] |
| Apple-1 | March 29, 1955 | 14 | Tower (500 ft) | 4, Yucca Flat | Observed by over 600 troops; included structural display assessments.[9][21] |
| Wasp Prime | March 29, 1955 | 3 | Airdrop (737 ft) | 7, Yucca Flat | Follow-on airdrop validation.[21] |
| HA | April 6, 1955 | 3 | Airdrop (high altitude, ~40,000 ft) | 1, Yucca Flat | High-altitude weapons effects test.[21] |
| Post | April 9, 1955 | 2 | Tower | 9, Yucca Flat | Weapons-related evaluation.[21] |
| MET | April 15, 1955 | 22 | Tower (400 ft) | 5, Yucca Flat | Military effects test with 38 experiments; observed by 260 troops.[9][21] |
| Apple-2 | May 5, 1955 | 29 | Tower (500 ft) | 1, Yucca Flat | Supported Armored Task Force maneuvers; observed by 1,800 troops.[9][21] |
| Zucchini | May 15, 1955 | 28 | Tower (500 ft) | 7, Yucca Flat | Final weapons-related test in series.[21] |
Notable Individual Detonations
Wasp Prime: Tower Shot and Weapon Design Validation
Wasp Prime, the ninth detonation in Operation Teapot, occurred on March 29, 1955, at 10:00 a.m. PST in Area 7 of Yucca Flat at the Nevada Test Site. The device yielded 3.2 kilotons and was delivered via free-air drop from a B-36 bomber, bursting at an altitude of approximately 737 feet (225 meters) to replicate low-altitude tactical employment conditions.[1][22] This configuration allowed for empirical assessment of ground-shock and air-blast effects akin to those from tower detonations, though the airdrop emphasized delivery system integration over static emplacement.[9] The primary objective was to validate design modifications to the original Wasp device, a compact implosion-type fission weapon developed by Los Alamos Scientific Laboratory (LASL) for tactical applications such as air defense warheads. The initial Wasp shot on February 18 had achieved only a fraction of its predicted yield due to inefficiencies in the fissile core assembly, prompting redesign efforts focused on enhancing criticality through a denser uranium-235 configuration and refined neutron initiator timing. Wasp Prime incorporated these upgrades, confirming a yield increase to the targeted low-kiloton range while maintaining a lightweight profile: a 17-inch-diameter spherical pit weighing roughly 125 pounds, optimized for integration into artillery shells or missile payloads.[1][22] Telemetry and diagnostic instruments captured implosion symmetry, neutron flux, and fission efficiency data, verifying that the revisions resolved prior underperformance without compromising safety interlocks or arming sequences. Post-shot analysis by LASL affirmed the device's suitability for stockpile entry pending further scaling tests, contributing to the evolution of reliable, variable-yield tactical primaries. Military observers noted the detonation's fireballs and shockwaves provided baseline data for predicting effects on armored formations at close standoff distances, though radiation yields exceeded initial models due to unboosted fission dominance.[1][9] This validation underscored the feasibility of miniaturizing nuclear yields for battlefield use, influencing subsequent designs like the W30 warhead series.[22]Bee: Surface Burst and Fallout Generation
Shot Bee was detonated on March 22, 1955, at 5:05 a.m. Pacific Standard Time, as the sixth test in Operation Teapot at the Nevada Test Site.[2] The device, a sealed-pit deuterium-tritium gas-boosted fission warhead designated XW-25 intended for air defense applications, was positioned atop a 500-foot tower in Area 7 of Yucca Flat.[1] With a yield of 8 kilotons, the detonation occurred at a height sufficient for the fireball—approximately 150-200 meters in radius based on yield scaling laws—to interact with the ground surface, simulating aspects of a surface burst by vaporizing and irradiating soil and debris.[1] [2] This configuration was selected to evaluate weapon performance while generating measurable local fallout for radiological effects studies, including impacts on military personnel and equipment.[1] The low-altitude tower placement facilitated significant fallout production, as the rising fireball entrained surface material into the stem of the mushroom cloud, rendering it radioactive through neutron activation and fission product condensation.[2] Initial post-detonation surveys recorded radiation levels of 10 roentgens per hour (R/h) near ground zero, with fallout contours of 0.01 to 0.1 R/h extending eastward due to prevailing winds.[2] This dispersal pattern contributed to Operation Teapot's overall release of approximately 24,500 kilocuries of iodine-131, resulting in an estimated 41 million person-rads of thyroid exposure across downwind populations, as calculated from empirical dispersion models and monitoring data.[1] Bee's fallout served as a controlled dataset for assessing dose rates, contamination persistence, and mitigation strategies, informing tactical nuclear doctrine on radiological hazards in battlefield scenarios.[1] [2] Military exercises under Exercise Desert Rock VI incorporated Bee's effects, with Marine Corps units and other troops positioned to observe the burst and advance through the fallout zone to test maneuvers under simulated nuclear conditions.[2] Data from dosimeters and environmental sampling confirmed higher local doses from neutron-induced activity in soil compared to pure air bursts, validating the test's utility for generating realistic fallout profiles without full subsurface burial.[1] These measurements, derived from instruments deployed by the Armed Forces Special Weapons Project and Los Alamos Scientific Laboratory, underscored the causal link between burst height, yield, and fallout intensity, with Bee providing empirical evidence that tower shots at this scale produce cratering and debris lofting akin to surface detonations.[2]MET: Multi-Event Test Configuration
The MET shot, the twelfth detonation in Operation Teapot, occurred on April 15, 1955, at 11:15 a.m. local time in Frenchman Flat at the Nevada Test Site.[23][15] The test utilized a tower configuration with the fission device positioned atop a 500-foot steel tower, detonated at a height of burst of 500 feet above ground zero to simulate an airburst for optimal assessment of military effects.[15] This setup yielded an explosive force of 22 kilotons, lower than initially anticipated for the associated Project 6.2 retest on radiation effects to electronics.[23] The configuration supported 38 projects under the Military Effects Group, the largest participation of its kind in the series, focusing on blast, thermal radiation, and prompt nuclear radiation impacts on tactical equipment and personnel survival.[23][1] Arrays of military hardware, including vehicles, electronics such as electron tubes, crystal units, and radar beacons, were deployed at distances from 300 to 2,700 meters from ground zero to capture differential effects.[23] Instrumentation encompassed AN/TVS-1 high-speed cameras, MK-11 bhangmeters for yield measurement, AN/MPQ-21X radar for fireball tracking, sound microphones for overpressure, and radiation detectors including dosimeters and radiacs.[23] Aircraft such as B-36, B-47, F-84G, and B-57 conducted cloud sampling and remote measurements, while ground stations monitored gust effects and fallout patterns directed northeast.[23] Although designated as a single-detonation event, the MET configuration enabled simultaneous evaluation of multiple effects scenarios through distributed instrumentation and exposure tests, akin to simulating compounded impacts in a tactical nuclear exchange without sequential blasts.[23][1] Troop observation and indoctrination exercises were integrated, with radiological safety enforced via 1,604 film badges, ensuring data collection on human and material vulnerabilities under controlled conditions.[23] The cloud top reached 40,300 feet, providing empirical data on atmospheric propagation relevant to multi-weapon field engagements.[23]
Apple-2: High-Yield Simulation and Structural Effects
Apple-2 was detonated on May 5, 1955, at 05:10 PST from a 500-foot tower in Area 1 of the Nevada Test Site, yielding 29 kilotons—approximately double the yield of the preceding Apple-1 shot and 50 percent above the nominal design expectation.[1][24] This enhanced output enabled simulation of blast and thermal effects from higher-yield devices, supporting civil defense assessments under Operation Cue.[25] The test incorporated a modified Los Alamos Scientific Laboratory (LASL) Class "D" thermonuclear primary with increased fissile material and a radiation implosion system to evaluate weapon performance under scaled high-yield conditions.[1] The primary structural effects study involved constructing a mock civilian community, known as Survival City or Doom Town, southeast of ground zero at distances ranging from 320 to 3,000 meters.[24] This setup featured approximately 50 prefabricated and conventional houses stocked with furniture, appliances, food, and mannequins dressed in civilian attire to replicate urban vulnerability.[25] Additional targets included automobiles, utility poles, and records storage facilities to gauge blast wave propagation, overpressure damage, and thermal ignition thresholds.[26] Post-detonation analysis revealed severe structural devastation within 1,000 meters, where overpressures exceeded 5 psi demolished frame houses, shattered masonry, and ignited fires from radiant heat fluxes above 10 cal/cm².[24] At intermediate ranges (1,000–2,000 meters), structures sustained moderate damage including collapsed roofs, fractured walls, and widespread window breakage, with some interiors scorched but not fully consumed by fire.[25] Beyond 2,000 meters, effects diminished to superficial impacts like displaced furnishings and minor glazing failures, providing empirical scaling data for predicting urban resilience against yields up to 50 kilotons.[24] Project 39.4c documented these outcomes via remote photography, confirming the test's utility in validating blast radius models despite the anomalous yield increase.[2] Military effects complemented the civil focus, with Task Force Razor—comprising 1,000 troops and 89 vehicles—advancing to within 890 meters of ground zero to measure equipment integrity under simulated high-yield overpressures, revealing negligible damage to armored units from reflected shocks.[24] These findings informed hardening standards for both civilian infrastructure and tactical assets, though dust and radiation constrained maneuvers.[24]Scientific and Military Assessments
Blast Effects, Radiation Measurements, and Data Collection
Data collection during Operation Teapot employed extensive instrumentation networks, including ground-based gauges, high-speed cameras, and aerial sampling platforms, to quantify blast overpressures, shockwave propagation, and radiation outputs from the 14 detonations, which ranged in yield from 1 kiloton (Shot Wasp) to 43 kilotons (Shot Turk).[9] Blast effects were primarily assessed through Projects 1.1 and 1.10, utilizing pitot-static tubes, self-recording gauges, and parachute-borne canisters to measure static overpressure and dynamic pressure across varied surfaces such as desert soil, asphalt, and water.[22] For instance, in Shot Bee (8 kilotons, 500-foot tower burst on March 22, 1955), overpressure gauges at distances of 390 to 5,110 meters recorded peak values consistent with cube-root scaling laws, with dynamic pressures elevated on asphalt relative to water due to precursor wave interactions.[27] Shockwave photography under Project 1.2 captured wavefront coalescence and dust loading, revealing dust densities up to 75% of total pressure on desert lines during Shot MET (22 kilotons, surface burst).[28] Radiation measurements focused on prompt gamma and neutron fluxes via ion chambers, film dosimeters, gold-sulfur detectors, and chemical dosimeters, with residual fallout tracked using AN/PDR-27A meters and soil sampling. Neutron source strengths varied across shots, reaching approximately 1.5 × 10¹⁸ neutrons per kiloton for Shot 9 (3.16 kilotons), while gamma source strengths were on the order of 13.0 × 10⁹ roentgen-distance squared per kiloton.[22] In Shot Tesla (7 kilotons, 300-foot tower burst on March 15, 1955), neutron flux at 180–910 meters yielded doses contributing minimally to total exposure, with thermal neutrons accounting for at most 2% of the neutron dose across five weapons tested.[29] Post-detonation gamma dose rates near ground zero decayed as t⁻¹.², with Shot Bee registering 10 roentgens per hour initially, falling to 0.01–0.1 roentgens per hour beyond 2,500 meters downwind due to fallout dispersion eastward.[27] Cloud penetration flights under Project 2.8b measured 2–2.5 roentgens of gamma exposure during early sampling, employing lead-shielded aircraft to collect turbulence and radionuclide data.[30]| Shot | Yield (kt) | Key Blast Measurement | Key Radiation Measurement |
|---|---|---|---|
| Bee | 8 | Overpressure at 390–5,110 m via photo-theodolite gauges | 10 R/h initial gamma near GZ; 0.4 R mean film badge dose |
| Apple-2 | 29 | Dynamic pressure elevated on non-ideal surfaces | 10 R/h gamma in northwest fallout pattern |
| ESS | ~1.2 | Subsurface cratering: 67 ft depth, 150 ft radius | 6,000 R/h gamma at H+2 hours in crater ejecta |
| MET | 22 | Dust loading 5–6x higher over desert vs. water | Base surge contamination via soil throwout |