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Bevatron

The Bevatron was a weak-focusing located at (LBNL) in , designed to accelerate protons to energies of up to 6.2 GeV and operational from 1954 to 1993. Constructed in the early 1950s under the direction of Ernest O. Lawrence at a cost of $9.6 million, it represented a pinnacle of postwar "" funded by the U.S. Atomic Energy Commission, occupying 125,000 square feet and weighing 10,000 tons with its massive 184-inch magnet. The accelerator gained worldwide renown for enabling the 1955 discovery of the by physicists and , a breakthrough in confirming the existence of that earned them the 1959 . In the 1960s, Bevatron beams interacting with liquid-hydrogen bubble chambers developed by Luis Alvarez revealed numerous subatomic resonances and provided key evidence for SU(3) flavor symmetry, contributing to Alvarez's 1968 Nobel Prize in Physics for his work on particle classification. Overall, research at the Bevatron was linked to four Nobel Prizes in Physics during its early decades, underscoring its role in advancing hadron physics and the . In the 1970s, the Bevatron was upgraded by coupling it with the SuperHILAC linear accelerator to create the Bevalac, which accelerated heavy ions to relativistic speeds and pioneered studies in nuclear matter under extreme conditions as well as ion-beam cancer radiotherapy. Decommissioned in 1993 as higher-energy facilities like the Tevatron emerged, the Bevatron was demolished between 2009 and 2012 to make way for modern infrastructure, including the Integrative Genomics Building housing the DOE Joint Genome Institute, with additional major research facilities completed by 2025. In 2021, its site was designated a National Historic Physics Site by the American Physical Society, recognizing its enduring legacy in particle physics and beyond.

History and Development

Conception and Construction

In the aftermath of , , director of the Radiation Laboratory, envisioned a new to probe fundamental questions in . Motivated by Paul Dirac's 1928 theoretical prediction of particles, including the as the negatively charged counterpart to the proton, Lawrence proposed in 1946 a capable of accelerating protons to energies up to 10 GeV—sufficient to produce antiproton-proton pairs through high-energy collisions. This ambition marked a shift from earlier cyclotrons toward synchrotrons, leveraging weak focusing principles to achieve unprecedented energies for testing Dirac's hypothesis. Securing funding proved challenging amid postwar budget constraints, but Lawrence's persistence paid off. In 1947, he sought approval from the for an initial $9.6 million budget to construct a 10 GeV , designed primarily by the lab's chief engineer William Brobeck. The AEC granted approval in 1948, adjusting the to a more feasible 6 GeV machine while maintaining the core objective; the final cost aligned closely with the original estimate at approximately $9.6 million. Key contributors to the conception included Edwin McMillan, who advanced the synchrotron's phase stability concept essential for beam control, and Robert Thornton, who contributed to the overall framework. Construction commenced with groundbreaking in September 1949 at the Radiation Laboratory site on the "hill" above the UC campus, selected for its existing infrastructure and proximity to facilities. Under Brobeck's engineering leadership and oversight from associate director Cooksey, who managed lab operations and resource allocation, the project progressed rapidly: the massive 9,700-ton yoke began installation in August 1950, encircling a 120-foot-diameter within a dedicated circular building. The featured a 220-foot-diameter, 40-foot-high magnet room with attached shop-and-office and mechanical wings (310 by 71.5 feet), designed for efficient integration of the accelerator's components, including injection systems and control areas. The first proton was circulated on February 15, 1954, with the machine reaching its full design energy of 6.2 GeV on April 1, 1954.

Initial Operation and Milestones

The Bevatron's commissioning began shortly after construction completion in late January 1954, with the first low-energy proton beam successfully circulated through the in February of that year. Initial operations focused on ramping up beam energies as tuning progressed, with the machine attaining its full design energy of 6.2 GeV in , marking a key milestone that positioned it as the world's highest-energy at the time and enabling prompt high-energy physics experiments. Early operation encountered several technical challenges, including vacuum system issues where initial pump-downs of the 100,000-cubic-foot required up to 72 hours to reach pressures of 10^{-5} mm , later improved to 12-24 hours through enhanced drying procedures. Magnet tuning proved critical for stability, necessitating adjustments to the field (n value) by about 0.1 to optimize focusing and prevent beam loss. Radiation shielding also demanded attention, with the enclosed in 5-foot-thick walls to mitigate and gamma from beam interactions, ensuring safe access for operators during non-pulse periods. The Bevatron operated in pulsed mode, with each cycle lasting approximately 5 seconds—comprising a 2-second magnet current ramp-up to 8,333 amperes and a 3-second flat-top—driven by two motor-generator sets delivering a combined peak power of 100 MW through . Repetition rates reached up to 10 pulses per minute, supporting sustained experimental runs. Initial beam intensities were very low, around 10^5 protons per pulse in early operation, growing rapidly to 10^{10} protons per pulse by October 1954, providing sufficient flux for early target bombardments. These operational benchmarks, achieved ahead of initial projections for full capability, facilitated immediate investigations into predicted particles like the , aligning with the accelerator's foundational motivations.

Design and Technical Features

Accelerator Principles and Specifications

The Bevatron functioned as a weak-focusing , relying on the principle of weak focusing to achieve radial and vertical beam stability. In this method, the varies with radius such that the field index n = -\frac{r}{B} \frac{dB}{dr} \approx 0.6, ensuring oscillatory motion of particles around the equilibrium orbit without strong focusing elements. This value of n balances stability conditions, with radial tune \nu_r = \sqrt{1 - n} and vertical tune \nu_z = \sqrt{n}, preventing excessive during acceleration. Designed to accelerate protons to 6.2 GeV , the Bevatron achieved this specification upon commissioning in 1954. At such energies, protons are highly relativistic (\beta \approx 0.991), necessitating synchronous ramping of the RF —from approximately 360 kHz at injection to 2.45 MHz at full energy—and the to maintain constant orbit radius while preserving phase stability and compensating for the near-constant . The proton orbit had a circumference of approximately 400 feet (122 meters), structured around four 90° magnet quadrants with a mean radius of about 50 feet. These , totaling around 10,000 tons, featured a 30-cm gap and 125-cm pole-face width to accommodate the and beam aperture. Power demands were met by two motor-generator sets, each with a 70-ton rotating at ~900 rpm, providing inductive of roughly 1.25 GJ total; this system delivered peak currents up to 8400 A at 15,250 V during the ~2-second ramp, yielding ~128 MW instantaneous power to the magnets while enabling energy recovery efficiencies above 90% through flywheel inertia and minimal resistive losses. The maximum synchrotron energy follows from the equilibrium condition in weak focusing: E = \frac{q B r}{\sqrt{1 + n}} where q is the proton charge, B the peak (~15 kG), r the radius, and n the field index; this relation accounts for the effective rigidity adjusted by focusing geometry.

Key Engineering Components

The Bevatron's main was a massive electromagnets system consisting of a 10,000-ton laminated iron arranged in 144 sectors around a 120-foot , providing the bending for proton orbits. The featured a 30-cm (12-inch) vertical gap to accommodate the beam , allowing for the weak focusing to stabilize particle trajectories within the . Powered by motor-generator sets delivering up to 8400 amperes at 15,250 volts , the system achieved peak fields sufficient to accelerate protons to 6.2 GeV , with the iron minimizing ripple and ensuring uniform across the . This engineering feat required precise alignment of the laminated core to handle the high currents without excessive heating or saturation. The vacuum system was critical for minimizing beam scattering and losses, comprising a doughnut-shaped aluminum encircling the with tangent tanks extending the total effective length to approximately 2 miles. Maintained at pressures around 10^{-6} to prevent residual gas interactions, the system relied on ion pumps distributed along the quadrants and straight sections, supplemented by oil diffusion pumps in the early configuration. Bake-out procedures, involving heating the chamber to 200–300°C under controlled conditions, were employed to desorb surface contaminants and achieve the required , ensuring beam lifetimes of several thousand turns per pulse. Proton injection into the Bevatron was facilitated by a 10 MeV linear accelerator, serving as the predecessor to the later for initial beam capture at the machine's low-energy phase. The linac, based on the , delivered pulses of up to 10^{12} protons at 10 MeV directly into the median plane of the Bevatron orbit via an electrostatic inflector, enabling efficient phase-space matching for acceleration from injection energy onward. This system included pre-acceleration stages from a to condition the beam before linac entry, minimizing emittance growth during transfer. Radiation shielding around the Bevatron consisted of 5-foot-thick walls encircling the ring, designed to attenuate neutrons and gamma rays produced during operation. These walls, poured in modular blocks for assembly, provided adequate protection for personnel in adjacent areas while allowing access ports for beam lines. Beam dumps, constructed from high-density materials like and lead encased in bunkers, absorbed extracted or lost protons at full , preventing beyond shielded zones. Control systems for the Bevatron employed early analog computers to synchronize key parameters, such as the rising with radiofrequency and injection timing. These systems, including function generators and feedback loops, monitored beam position and magnet current in , adjusting voltages to maintain stability throughout the cycle. The analog setup, housed in the central , relied on servomechanisms for precise , enabling reliable operation despite the machine's scale and the era's computational limitations.

Major Scientific Achievements

Discovery of the Antiproton

The prediction of originated from Paul Dirac's 1928 relativistic quantum equation for the , which yielded solutions implying the existence of particles with the same mass but opposite charge to known particles, including protons. This theoretical framework suggested proton- pair production required kinetic energies exceeding twice the proton rest mass, approximately 1.88 GeV in the center-of-mass frame, necessitating a high-energy accelerator like the Bevatron to achieve the required 6 GeV proton beam. The discovery confirmed the symmetry between matter and , validating Dirac's hole theory and extending it beyond electrons to baryons. In 1955, an experimental team led by and , including Clyde Wiegand and Thomas Ypsilantis, utilized the Bevatron at the , to search for antiprotons. The method involved accelerating protons to 6.2 GeV and directing them onto a copper target to produce particle-antiparticle pairs through collisions. Secondary particles were analyzed using a magnetic spectrometer to select negatively charged tracks with momentum around 1.19 GeV/c, followed by detection with scintillation counters (S1, S2, S3) for time-of-flight measurements over a 12-meter baseline and Cerenkov counters (C1, C2) to restrict velocities to β ≈ 0.75–0.78, corresponding to particles with mass approximately 1836 times the (m_p). This setup distinguished antiprotons from lighter mesons like π⁻ and K⁻ by their velocity and mass signatures, with antiprotons identified as having negative charge, proton-equivalent mass (within 5%), and no decay observed en route. The experiment yielded about 60 antiproton events amid millions of interactions, with an antiproton production rate of roughly 1 per 62,000 mesons at peak energy. These results were announced at a on October 19, 1955, and detailed in the seminal paper published in . For their leadership in this breakthrough, Segrè and received the 1959 , recognizing the confirmation of antimatter's existence and its implications for symmetry.

Antineutron Discovery and Early Particle Physics

In 1956, a team led by Bruce Cork, Glen Lambertson, Oreste Piccioni, and William Wenzel at the Lawrence Berkeley Laboratory's Bevatron conducted an experiment that resulted in the discovery of the . High-energy protons accelerated to 6.2 GeV were directed onto a target to produce antiprotons via pair creation, which were then extracted and incident on a target to induce charge-exchange reactions: \bar{p} + p \to \bar{n} + n. The resulting antineutrons traveled a short distance before annihilating in a downstream iron plate, where each annihilation event generated multiple gamma rays detected by an array of scintillation counters arranged around the plate. This setup allowed the identification of neutral particles with annihilation characteristics distinct from other secondaries, confirming the presence of antineutrons with a production rate consistent with theoretical expectations for charge exchange. The measured of the was approximately 1838 times the (m_e), precisely matching that of the and supporting the Dirac prediction of particles having identical es to their counterparts. This came from kinematic reconstruction of the gamma-ray energies and momenta, which aligned with the expected rest for a neutral . The discovery built on the prior observation at the same facility, extending studies to neutral baryons and validating charge conjugation symmetry in the strong interaction. Beyond the , early Bevatron operations in the mid-1950s facilitated the identification and study of V⁰ particles, neutral decays observed as characteristic V-shaped tracks in cloud chambers or counter coincidences, including neutral kaons (K⁰) and lambda hyperons (Λ⁰). These experiments involved proton beams interacting with internal or external targets, revealing production mechanisms for strange particles through associated production, where is conserved in strong interactions. Representative cross-sections from these runs showed kaon production rates on the order of millibarns at 6 GeV, significantly lower than interactions (tens of millibarns), highlighting the suppression due to the mass and contributing to the development of theory. These investigations marked the Bevatron's transition from simple counter-based setups—relying on and Cerenkov detectors for timing and measurements—to more sophisticated configurations integrating multiple detectors for multi-particle event analysis. This evolution enabled higher statistics in studies, with interaction rates improving from initial low-yield runs to systematic scans of energies and materials, laying groundwork for later precision measurements.

Experimental Innovations

Liquid-Hydrogen Bubble Chamber

The liquid-hydrogen bubble chamber represented a pivotal advancement in particle detection, spearheaded by Luis Alvarez at the University of California's Radiation Laboratory in Berkeley. Building on Donald Glaser's 1952 invention of the using , Alvarez initiated development of a liquid-hydrogen version in early 1953 to enable studies of proton-proton interactions with a pure target. The first such chamber, a small 10-inch-diameter model holding 0.9 liters of , became operational in May 1956 and was integrated with the Bevatron accelerator for initial experiments. This marked the debut of hydrogen-based bubble chambers, which offered superior resolution for tracking charged particles compared to earlier diffusion chambers or photographic emulsions. The flagship 72-inch-diameter chamber, completed in 1959, featured a cylindrical volume of approximately 520 liters of maintained at 25–29 under 6 atmospheres of , with the entire system weighing several tons due to its robust stainless-steel and cryogenic . Sensitivity was achieved through rapid via a large that reduced to 3 atmospheres in 18 milliseconds, creating a superheated state where ionizing particles induced bubble formation along their tracks for about 10 milliseconds. The chamber included a 5-inch-thick optical for beam entry and was surrounded by a to minimize thermal gradients. This design allowed for high-fidelity visualization of particle trajectories in a up to 18 kG, enabling precise measurements. Integration with the Bevatron involved directing high-energy proton beams directly into the chamber's fiducial volume, synchronized with expansion cycles timed to the accelerator's approximately 1-second spill duration. Events were captured using a stereoscopic camera system with three or four synchronized lenses (f/2.2, 125 mm ), producing multiple views per expansion for three-dimensional reconstruction; a single run could yield hundreds of thousands of photographs, facilitating the analysis of millions of interactions over extended operations. The medium provided a low-mass target ideal for mimicking free proton collisions, with track resolutions down to millimeters for short-lived particles, far surpassing prior detectors like scintillation counters. Alvarez's innovations in the earned him the 1968 , shared for the invention and its application in discovering new particle resonances, such as the rho (ρ) and omega (ω) mesons, which provided early evidence supporting the of hadrons. These tools transformed high-energy physics by enabling systematic scans of interaction topologies, though they required meticulous film scanning and event reconstruction by teams of physicists.

Other Detection and Instrumentation Advances

In conjunction with the primary visual tool of the liquid-hydrogen , the Bevatron utilized and Cerenkov counters for precise particle identification in high-energy experiments. counters, which detect charged particles via light flashes in scintillating materials coupled to tubes, were employed to define particle trajectories and measure flight times between detection points, as demonstrated in the 1955 search where counters S1 and S2 timed negative particles separated by 12 meters. Cerenkov counters, relying on the emission of coherent radiation from particles exceeding the of light in a medium, provided velocity measurements to distinguish particles of equal but differing masses; for instance, counters C1 and C2 selected antiprotons with β ≈ 0.75 by responding only to velocities in a narrow range. These counters achieved identification accuracies sufficient for rare event isolation, with time-of-flight resolutions around 10 nanoseconds and velocity selectivity better than 5%. By the late , chambers and emerging multi-wire proportional chambers tracking capabilities beyond simple counters. chambers, introduced around at the Bevatron, visualized particle paths through ionized gas sparks triggered by high-voltage pulses synchronized with beam spills, offering spatial resolutions of about 100 microns and enabling studies of short-lived interactions without the density limitations of emulsions. Multi-wire proportional chambers, with wires spaced at 2 mm in gas-filled volumes, provided position-sensitive detection with efficiencies over 95% for relativistic particles, as tested in 1973 Bevatron experiments on heavy-ion responses where they resolved tracks in intense flux environments. These devices supported event selection, reducing background in counter-triggered setups. Magnetic spectrometers were integral for momentum analysis, bending charged particle tracks in uniform external magnetic fields to measure curvature radii via p = qBr, where p is , q charge, B , and r radius. At the Bevatron, such spectrometers, often paired with spark chambers for track visualization, analyzed secondary particles from 6.2 GeV proton interactions, achieving momentum resolutions of 1-2% for pions up to 1 GeV/c in experiments like K-meson mass determinations. This setup allowed precise kinematic reconstruction, essential for calculations in decay studies. Automated scanning and computational analysis streamlined from chamber films and emulsions. The Franckenstein , developed in at Lawrence Berkeley Laboratory, used flying-spot microscopes and to measure track coordinates from photographic records at rates of 5-10 events per hour, outputting data to punch cards for geometric reconstruction. By the mid-1960s, digital computers like the LRL 7090 processed these inputs via least-squares fitting algorithms to reconstruct 3D tracks, improving efficiency for large datasets from Bevatron exposures and reducing manual labor from months to days per experiment. Radiation monitoring and safety instrumentation were critical given the Bevatron's intense production. Fixed area monitors, including BF3 proportional counters for neutrons and chambers for gammas, continuously surveyed beam lines and experimental halls, with alarms triggered above 10 m/hour; personnel dosimeters tracked cumulative exposures, maintaining levels below 5 /year in the 1950s-1960s era. These systems, informed by early radiological protocols, mitigated risks from activated components and sky-shine, enabling safe prolonged operations. These advances contributed to resonance spectroscopy by enabling detailed studies of pion-meson and excitations in proton-nucleon collisions. Counter-spectrometer arrays identified π-mesons through decay topologies and invariant masses, while chambers tracked multi-body final states revealing resonances like the Σ*(1385) via πN → Σ* → Λπ decays, with cross-sections measured at 4 GeV/c π-p interactions confirming Δ-exchange mechanisms. Such instrumentation facilitated the mapping of excited states up to 2 GeV masses, establishing key features of the decuplet and octet.

Evolution into the Bevalac

Upgrade and Integration with SuperHILAC

In the early 1970s, the Bevatron underwent significant modifications to enable the acceleration of heavy ions at relativistic energies, driven by the scientific motivation to investigate nuclear collisions involving heavy projectiles, which promised insights into nuclear matter under extreme conditions. This upgrade addressed the limitations of the original proton-focused design by adapting the accelerator for ions with higher charge-to-mass ratios, allowing studies of relativistic heavy-ion interactions that were inaccessible with lighter particles. Initial heavy-ion operations began in 1971, when the Bevatron successfully accelerated beams of ions using an adapted Penning ion gauge () source originally from the HILAC, achieving extraction energies of up to 2.1 GeV per without external injection. These trials demonstrated the feasibility of heavy-ion acceleration but were limited by low beam intensities due to recombination losses in the residual gas. To overcome this, the SuperHILAC—a 72-meter Alvarez-type linear accelerator operational since 1972 and capable of accelerating any ion species up to to 8.5 MeV per —was selected as the . The SuperHILAC's design, with its drift-tube structure and radiofrequency quadrupole pre-accelerator, provided well-matched, low-emittance beams essential for efficient transfer. The core of the integration involved constructing a 250-meter transfer line in 1973 to connect the SuperHILAC to the Bevatron, enabling the injection of pre-accelerated heavy ions into the at energies around 8-10 MeV per . This line incorporated magnetic elements for beam matching and a 45-meter vertical drop to align the accelerators, which were housed in separate buildings. In Bevalac mode, multiple pulses from the SuperHILAC—operating at a 1-2 Hz repetition rate—were stacked into the Bevatron over several cycles (one every 4-6 seconds), accumulating higher beam currents by leveraging the synchrotron's phase-space acceptance. The facility, renamed the Bevalac upon commissioning in August 1974, marked the world's first operational relativistic heavy-ion accelerator, with initial beams of and ions delivered for experiments. Engineering challenges during the upgrade included adapting ion sources for higher charge states, such as fully stripping nitrogen ions via thin aluminum foils (40 µg/cm²) to achieve q/m ratios suitable for the proton linac's 40% increased gradient. Vacuum requirements were also elevated to 10^{-7} Torr or better in the Bevatron to minimize charge exchange and recombination, which had previously caused 90% beam loss for partially stripped ions; this necessitated extensive pumping upgrades and bakeable components. These adaptations, tested rigorously in 1971 trials, ensured reliable operation for heavier ions post-integration, though beam intensities remained modest at around 10^8 particles per pulse initially.

Heavy Ion Acceleration and Applications

The Bevalac's capability to accelerate heavy ions to relativistic energies enabled groundbreaking studies in , particularly through collisions that recreated extreme conditions akin to those in the early shortly after the . These high-energy nucleus-nucleus interactions produced hot, dense states of , often described as nuclear fireballs, where temperatures exceeded 10^12 and densities reached several times that of normal . Such fireballs provided a analog for the quark-gluon phase , allowing researchers to probe the equation of state of under compression. A key discovery from these experiments was the phenomenon of collective flow, first observed in relativistic heavy-ion collisions at the Bevalac using the Plastic Ball detector in reactions such as + and Nb + Nb at 400 MeV per nucleon. This azimuthal anisotropy in particle emission revealed hydrodynamic behavior in the expanding fireball, indicating pressure gradients and collective motion of matter, which informed models of the . Further experiments extended these observations to higher energies, confirming the transition from directed flow at lower energies to antiflow at higher ones, driven by the stiffness of interactions. In addition to flow dynamics, Bevalac collisions facilitated the production and study of exotic particles, including those involving strange quarks. Neutral strange particles like K^0 and Λ were measured in near-threshold Ni + Ni collisions, providing insights into strangeness enhancement as a signature of quark-gluon plasma formation. Hypernuclei, bound states of hyperons and nucleons, were produced using heavier ion beams such as 16O, enabling spectroscopy of strange matter and tests of hyperon-nucleon interactions within nuclear environments. These results highlighted the role of strange quark production in dense matter, with enhanced yields compared to proton-induced reactions. Beyond fundamental , the Bevalac's heavy-ion beams found critical applications in , particularly in for cancer. Heavy-ion radiotherapy at the Bevalac began in 1973 with ions, followed by treatments using and carbon ion beams starting in 1977, which offer superior dose localization via the , sparing healthy tissue while targeting tumors. Over the next 15 years, more than 430 patients received with ions heavier than , primarily at 670 MeV per , for conditions like tumors and soft-tissue sarcomas, demonstrating improved local control rates. These efforts established the biophysical rationale for heavy-ion radiotherapy, influencing subsequent facilities worldwide. The Bevalac also served as a vital tool for simulating cosmic ray environments, emulating high-energy astrophysical events to study radiation effects on materials and biology. Heavy-ion beams mimicked galactic cosmic ray fragmentation and penetration, enabling ground-based tests of spacecraft shielding and human tissue response to space radiation. Experiments exposed electronics and biological samples to iron and other heavy ions, revealing single-event upsets and DNA damage patterns relevant to long-duration space missions. This work supported NASA programs by providing calibrated data on secondary particle production in simulated interstellar propagation. At its peak, the Bevalac achieved beams at 1 GeV per , the highest energies then available for the heaviest ions, enabling comprehensive studies across , , and astrophysical domains. By 1993, the facility had supported thousands of experiments, advancing understanding of relativistic heavy-ion interactions and their applications.

Decommissioning and Legacy

Shutdown and Demolition Process

In October 1992, (LBNL) announced the impending shutdown of the Bevatron, also known as the Bevalac, citing shifts in research priorities and funding toward newer facilities such as the (RHIC) at and other advanced accelerators, following the machine's long career in high-energy and heavy-ion physics. The final beam was delivered on February 21, 1993, marking the end of operations after nearly 40 years, with the last experiment conducted by a collaboration studying relativistic heavy ions. Decommissioning began immediately after shutdown and extended through 2008, involving the systematic removal of equipment, including the disassembly of the 180-foot-diameter apparatus and approximately 750-800 massive shielding blocks totaling 12,000-16,000 tons. This phase included comprehensive efforts, such as to address asbestos-containing materials like siding in Building 51, conducted by certified contractors under LBNL's Asbestos Management Program, and radiological surveys to characterize and manage low-level (e.g., at levels around 15-30 pCi/g) in components and , ensuring compliance with Department of Energy () Order 5400.5 for safe disposal at licensed facilities like Envirocare in . Hazardous materials, including lead and , were also removed and handled per regulatory standards, with about 200 cubic yards of potentially contaminated excavated and surveyed. Demolition of Building 51 and the Bevatron structure received environmental approval through a Environmental Assessment in 2006, with a Finding of No Significant Impact issued in 2008. Work commenced in July 2009, utilizing heavy machinery such as cranes, excavators, and hoe-ram hammers to dismantle over 22,000 tons of building materials, 12,000-16,000 tons of shielding blocks, and 12,000-15,000 tons of accelerator components, generating approximately 4,700 truck trips for debris transport. The project, which incorporated $14.4 million from the American Recovery and Reinvestment Act of 2009, was completed in early 2012 at a total cost of about $50 million, including and site restoration through backfilling with 20,000 cubic yards of clean fill, leveling, and hydro-seeding with native grasses. The deep underground foundation slab and most retaining walls were preserved in place for potential future site development, while shallow foundations and tunnels were fully demolished. The shutdown prompted a ceremonial on , 1993, attended by nearly 100 current and former LBNL staff, where accelerator pioneer Ed Lofgren turned off the final beam, joined by Nobel laureate and other key figures in a nostalgic gathering documented for LBNL archives. As progressed, a farewell ceremony was held on November 6, 2009, drawing about 200 participants, including retirees and staff, to honor the facility's legacy amid the ongoing dismantling, with remarks from project managers and a slide show recapping its history.

Historical Recognition and Impact

The Bevatron's scientific achievements garnered significant recognition, including four Nobel Prizes awarded for particle physics research conducted there in the late 1950s and early 1960s. In 1959, and received the for their discovery of the using the accelerator in 1955. Luis Alvarez was awarded the 1968 for his development of the hydrogen bubble chamber and the subsequent identification of multiple resonance particles in Bevatron experiments. The discovery in 1956 by a team led by further exemplified the accelerator's role in research, though it did not yield a separate Nobel. In 2021, the designated the Bevatron site as a , honoring its pivotal role in confirming antimatter's existence and advancing high-energy physics. Beyond individual awards, the Bevatron pioneered the "" model of large-scale, government-funded collaborative research, involving multidisciplinary teams and substantial resources that became a template for modern facilities. It served as a training ground for generations of physicists, engineers, and technicians, fostering expertise in accelerator operations and experimental techniques that influenced subsequent careers at institutions worldwide. The facility's legacy endures through preserved archives at , documenting its operational history and experimental data for ongoing scholarly study. Following its decommissioning in 1993 and the demolition of Building 51 between 2009 and 2012, the Bevatron site was repurposed for the Integrative Genomics Building, which now hosts the Department of Energy Joint Genome Institute and related initiatives. The accelerator's innovations in technology and heavy-ion acceleration directly informed advancements in heavy-ion therapy for , with early Bevalac experiments at the site paving the way for clinical applications now operational at facilities like the GSI Helmholtz Centre for Heavy Ion Research in .