Buckeye Bullet
The Buckeye Bullet is a series of experimental electric land speed vehicles developed by students at The Ohio State University since 2000, aimed at breaking international and national speed records while advancing electric vehicle technology through hands-on engineering projects.[1] Initiated at Ohio State's Center for Automotive Research under the advisement of faculty like Giorgio Rizzoni, the Buckeye Bullet Electric Vehicle Team has focused on designing custom streamliner vehicles tested primarily at the Bonneville Salt Flats in Utah, emphasizing innovations in batteries, motors, power electronics, and aerodynamics.[1][2] The first iteration, Buckeye Bullet 1, completed in 2004, set the U.S. record for battery electric vehicles at 314.958 mph using nickel-metal hydride batteries, marking the project's debut in high-speed EV racing.[3] In partnership with Monaco-based Venturi Automobiles, the team produced the Venturi Buckeye Bullet 2 in 2009, the world's first hydrogen fuel cell-powered land speed vehicle, which achieved an international record of 302.877 mph.[1][3] A modified version, Buckeye Bullet 2.5, transitioned to lithium-ion batteries and set a new battery electric vehicle world record of 307.666 mph in 2010.[3] The series' most notable achievement is the Venturi Buckeye Bullet 3, developed over six years by a core team of about 10 undergraduate and graduate students, which in 2016 established the current FIA-certified world land speed record for electric vehicles at a two-way average of 341.4 mph (with a one-way peak of 358 mph), powered by over two megawatts from A123 Systems lithium-ion batteries and dual custom Venturi electric motors.[2]Project Background
Founding and Objectives
The Buckeye Bullet project originated in 1993 at The Ohio State University (OSU), when Department of Mechanical Engineering Chair Larry Kennedy requested that Giorgio Rizzoni, a professor in the same department, advise a new student racing team focused on electric vehicles.[4] This initiative built on OSU's growing emphasis on automotive research, providing students with practical experience in EV design and competition through participation in the Formula Lightning series from 1993 to 2000, where the team raced the battery-powered Smokin’ Buckeye vehicle.[4] The project was formally launched in 2000 during a farewell dinner for the Formula Lightning series, conceived on a napkin sketch by Jeff Kletrovets of Shoemaker Electric, marking a shift toward building a custom streamliner to challenge the then-standing electric land speed record of 245 mph.[4][1] The primary objectives of the Buckeye Bullet have centered on advancing electric vehicle technology through innovative engineering, demonstrating the feasibility of high-performance EVs, and offering interdisciplinary hands-on experiences for OSU students in areas such as design, fabrication, testing, and high-speed racing.[1] By targeting land speed records for battery-electric and alternative fuel vehicles, the project aimed to push the boundaries of sustainable transportation while fostering collaboration across engineering disciplines at OSU's Center for Automotive Research.[4][1] These goals have emphasized not only technical breakthroughs but also real-world application, preparing students for careers in the evolving automotive industry.[1] Initially focused on battery-electric vehicles, the project saw its first streamliner, Buckeye Bullet 1, completed and tested in 2003–2004, establishing a foundation for record-attempting runs.[1] Over time, the scope expanded to include hydrogen fuel cell technology with the development of Buckeye Bullet 2 in 2009, broadening the emphasis on diverse alternative propulsion systems.[1] This evolution progressed from pursuing U.S. national records to international partnerships, such as with Venturi Automobiles, with ambitions to surpass the 400 mph barrier by the mid-2010s, reflecting growing global interest in ultra-high-speed sustainable vehicles.[4][1]Team and Collaborations
The Buckeye Bullet project is spearheaded by a student-led multidisciplinary team at The Ohio State University, comprising undergraduate and graduate students primarily from engineering fields such as mechanical, electrical, and aerospace engineering. A core group of about 10 students drives the vehicle's development, with contributions from approximately 40 additional students and alumni, enabling hands-on experience in advanced electric vehicle design.[2] Faculty advisors from the university's Center for Automotive Research (CAR), including Giorgio Rizzoni and David Cooke, provide oversight to guide technical progress and ensure project alignment with educational goals.[1][5] The team's organizational structure emphasizes student autonomy, with leadership roles rotating annually among members to foster skill development and fresh perspectives, while faculty maintain continuity and expertise in areas like automotive systems integration. Based at CAR, the group operates through focused working units dedicated to critical components, including aerodynamics for drag reduction, powertrain optimization, chassis fabrication, electronics integration, and on-track testing protocols. This setup allows participants to apply classroom knowledge to real-world challenges in a collaborative environment.[6][7] Key partnerships have been instrumental to the project's success, notably the collaboration with Venturi Automobiles, a Monaco-based electric vehicle specialist, which began around 2010 and supplies custom electric motors, technical expertise, and substantial sponsorship funding for vehicles from the Buckeye Bullet 2 onward.[3][2] Earlier efforts, such as the Buckeye Bullet 1, drew on industry support including high-performance bearings from SKF to handle extreme speeds and loads.[8] Battery systems for subsequent iterations were provided through partnerships with A123 Systems, enhancing energy density and power delivery.[9] Funding for the initiative comes from a mix of Ohio State University grants, corporate sponsorships from automotive and technology firms, and contributions from alumni networks, supporting annual operations, component procurement, and travel to testing sites like the Bonneville Salt Flats.[1][3]Vehicle Iterations
Buckeye Bullet 1
The Buckeye Bullet 1 represented the inaugural effort of The Ohio State University's student engineering team to develop a high-performance electric streamliner for land speed racing, with design and construction spanning from 2001 to 2004. This battery-powered vehicle featured a lightweight carbon fiber body optimized for minimal drag and maximum stability at extreme speeds, embodying a classic streamliner configuration with enclosed wheels and a narrow profile to reduce aerodynamic resistance. The team's focus on integrating advanced electric components marked the project's entry into competitive racing, leveraging hands-on engineering to address the limitations of contemporary battery technology.[10][3] The powertrain centered on a pack of nickel-metal hydride (NiMH) batteries supplied by Cobasys, comprising approximately 12,000 cells that delivered around 100 kWh of energy storage, paired with two AC induction motors providing a peak output of 400 horsepower. The vehicle's dimensions—measuring 31 feet in length and 2 feet in width, with a height under 3 feet—contributed to its exceptionally low drag coefficient of 0.15, enabling efficient high-speed performance while maintaining a curb weight of about 4,000 pounds. These specifications were tailored to comply with land speed racing regulations while prioritizing energy efficiency and power delivery for short, intense runs on the salt flats.[11][12] Initial testing occurred at the Bonneville Speedweek in 2004, where the Buckeye Bullet 1 achieved a one-way top speed of 314.958 mph, establishing a U.S. record for battery-electric vehicles in its class. However, early runs revealed significant challenges with battery thermal management, as the intense discharge rates caused overheating that constrained run durations and required careful monitoring to prevent performance degradation or safety risks. These experiences provided critical insights into electric propulsion limits, informing subsequent iterations while highlighting the vehicle's pioneering role in demonstrating battery technology's potential for ultra-high-speed applications.[10][3]Buckeye Bullet 2
The Buckeye Bullet 2 represented a significant evolution in the project, shifting from battery-electric propulsion to hydrogen fuel cell technology during its development from 2006 to 2008. Built by engineering students at The Ohio State University in collaboration with Venturi Automobiles as the lead sponsor, along with partners like Ballard Power Systems and Ford, it became the world's first hydrogen fuel cell-powered land speed record vehicle.[3][1] The vehicle weighed approximately 2,600 pounds and featured a liquid hydrogen storage tank, marking a bold experiment in alternative energy for high-speed applications.[3] The powertrain centered on a Ballard fuel cell stack rated at 150 kW continuous output, which was modified by the team to exceed 600 kW peak, supplemented by lithium-ion batteries to handle acceleration demands.[3][13] This setup drove twin electric motors producing over 700 horsepower, enabling efficient power delivery in a streamliner configuration optimized for the Bonneville Salt Flats.[3][14] Key design elements included an enclosed cockpit for enhanced driver safety, an advanced cooling system to manage fuel cell temperatures during sustained high-speed runs, and a remarkably low drag coefficient of 0.13 achieved through computational fluid dynamics modeling.[3][15] The vehicle debuted at the Bonneville Salt Flats in 2008, where early testing addressed challenges like hydrogen boil-off from the cryogenic tank, resolved through specialized insulation to maintain fuel integrity.[3][13] In performance testing, the Buckeye Bullet 2 achieved an average speed of 286.476 mph over two runs in 2008, establishing an initial benchmark for fuel cell vehicles and highlighting the viability of hydrogen propulsion in extreme conditions.[3] This effort set the stage for further refinements, culminating in an FIA-certified world record of 302.877 mph in the fuel cell category the following year.[16][1]Buckeye Bullet 2.5
The Buckeye Bullet 2.5, developed by students at The Ohio State University between 2009 and 2010, represented a return to pure battery-electric propulsion by adapting the chassis and body of its predecessor, the fuel cell-powered Buckeye Bullet 2. This iteration replaced the hydrogen fuel cell system with a high-capacity lithium-ion battery pack, enabling higher power delivery while maintaining the streamliner's core aerodynamic envelope. The vehicle weighed approximately 4,300 pounds, a reduction from the heavier fuel cell setup, which contributed to improved acceleration potential.[17] The powertrain featured an electric traction system supplied by Venturi Automobiles, consisting of dual motors that delivered a peak output exceeding 600 kW (over 800 horsepower). The battery pack comprised 1,600 cylindrical lithium-ion cells from A123 Systems, providing the high discharge rates necessary for sustained high-speed runs without the logistical complexities of hydrogen storage. Optimized wheel fairings and minor aerodynamic refinements helped achieve a drag coefficient of around 0.13, minimizing air resistance at extreme velocities. These upgrades focused on enhancing energy efficiency and power density to bridge the gap between earlier electric designs and future all-wheel-drive iterations.[9][3][17][18] Testing occurred at the Bonneville Salt Flats in August 2010, where the vehicle faced variable wind conditions that complicated stable runs. Driven by professional test pilot Roger Schroer, the Buckeye Bullet 2.5 completed two qualifying passes, averaging 307.666 mph to establish a new FIA-certified world land speed record for battery-electric vehicles. This achievement surpassed the prior mark of 245.5 mph and underscored the viability of advanced lithium-ion technology for ultra-high-performance applications.[10][9][19]Buckeye Bullet 3
The Venturi Buckeye Bullet 3 (VBB-3), developed from 2010 to 2016 through a collaboration between The Ohio State University's Center for Automotive Research and Monaco-based Venturi Automobiles, represented the project's most ambitious iteration as a four-wheel-drive electric streamliner designed to exceed 400 mph. This vehicle built on prior models by incorporating advanced student-led engineering to push the boundaries of electric land speed racing, with construction emphasizing lightweight composites and high-power density systems for sustained high-speed performance over short bursts of approximately 90 seconds.[2][3][20] Measuring 37.2 feet (11.35 meters) in length and weighing over 3.5 metric tons (approximately 7,700 pounds), the VBB-3 featured a slender space-frame chassis with a carbon fiber cockpit tub for structural integrity and reduced mass. Its aerodynamic profile achieved a drag coefficient of 0.13 through extensive wind tunnel testing and computational fluid dynamics simulations conducted at Ohio State University, optimizing the streamlined shape to minimize resistance while ensuring stability at extreme velocities without protrusions like vents or intakes. The design relied on closed-loop cooling systems to maintain efficiency, allowing the vehicle to prioritize low-drag geometry over traditional heat dissipation methods.[21][18][22] The powertrain consisted of eight lithium iron phosphate battery packs from A123 Systems, comprising around 2,000 cells configured for high-discharge rates without active cooling, delivering an average voltage of approximately 735 volts. These packs powered two custom permanent-magnet AC motors—one per axle—each rated at up to 1,500 horsepower, yielding a total peak output of 3,000 horsepower (over 2 megawatts) and enabling rapid acceleration from standstill to over 300 mph. The system's oil-cooled motors and water-cooled inverters were engineered for the demanding six-mile runs typical of land speed attempts, with torque distributed across all wheels for optimal traction on the salt flats.[20][23][3][2] In September 2016, the VBB-3 underwent record attempts at the Bonneville Salt Flats in Utah, driven by veteran racer Roger Schroer from Ohio State's Transportation Research Center. Despite challenging weather conditions over multiple years of preparation, the vehicle achieved a peak one-way speed of 358 mph (576 km/h) and a certified two-way average of 341.4 mph (549.4 km/h) on September 19, surpassing the previous electric vehicle land speed record of 307.6 mph set by the team in 2010 and earning official recognition from the Fédération Internationale de l'Automobile. This performance underscored the VBB-3's role as the culmination of the Buckeye Bullet project's evolution toward ultra-high-speed electric propulsion.[2][24]Technical Innovations
Powertrain and Energy Systems
The Buckeye Bullet series marked a pivotal shift in energy storage for high-performance electric vehicles, beginning with nickel-metal hydride (NiMH) batteries in the inaugural model. The Buckeye Bullet 1 featured approximately 10,000 C-cell NiMH batteries weighing around 2,000 pounds, which supplied power to a custom 400-horsepower three-phase AC induction motor for short-duration acceleration runs.[25] This configuration provided reliable energy delivery but was limited by the lower energy density and discharge rates of NiMH technology compared to later advancements. A key innovation in the second iteration involved integrating a hydrogen fuel cell system to explore alternative propulsion. The Buckeye Bullet 2 utilized recycled proton exchange membrane (PEM) fuel cell stacks donated by Ballard Power Systems, originally designed for city buses, paired with liquid hydrogen storage at cryogenic temperatures to achieve high power output.[13] The system delivered up to 250 kW continuously, with modifications enabling peak powers around 540 kW through re-engineered gas supply dynamics, demonstrating approximately 50% efficiency typical of PEM fuel cells in such applications.[26] This hybrid approach highlighted the potential of fuel cells for sustained high-power bursts, though challenges in hydrogen handling and system integration influenced the project's pivot back to pure battery-electric designs. Subsequent models, including the Buckeye Bullet 2.5 and 3, advanced to lithium-ion batteries for superior performance metrics. These vehicles incorporated A123 Systems lithium iron phosphate cells in configurations yielding over two megawatts of peak power, with the Buckeye Bullet 3 using eight packs to drive dual custom motors from Venturi Automobiles.[2] The power electronics featured bespoke inverters optimized for 90-second acceleration profiles, supporting high-discharge rates exceeding 50C for brief intervals without active thermal management, as the short run times minimized heat buildup.[20] Power-to-weight ratios improved dramatically across iterations, from roughly 0.1 hp/lb in the NiMH era to about 0.35 hp/lb in lithium-ion variants, driven by denser energy storage at approximately 125 Wh/kg at the cell level.[7][27] These developments emphasized scalable, high-rate energy conversion tailored to land speed demands, influencing broader electric vehicle powertrain architectures.Aerodynamics and Chassis Design
The aerodynamic design of the Buckeye Bullet vehicles embodies a streamliner philosophy optimized for ultra-high-speed stability and efficiency, featuring a teardrop-shaped body to minimize pressure drag while emphasizing skin friction dominance. This configuration, combined with fully enclosed wheels and fender designs that redirect airflow around tire wells, achieves exceptionally low drag coefficients, such as approximately 0.135 for the Buckeye Bullet 3 as determined through computational fluid dynamics (CFD) validation. These elements collectively reduce aerodynamic resistance, enabling the vehicles to approach speeds exceeding 300 mph with minimal power loss to drag.[11][11][18] The chassis construction evolved across iterations to prioritize lightweight rigidity and structural integrity under extreme loads, transitioning from a steel space frame in early models like Buckeye Bullet 1 to advanced composite monocoque structures in Buckeye Bullet 2 and beyond. Carbon fiber composite skins with aluminum honeycomb sandwich panels provide high stiffness in torsion and bending, essential for preventing vibrations at speeds over 300 mph, while maintaining a low overall vehicle mass. By Buckeye Bullet 3, the design incorporated four-wheel drive with independent axles, enhancing traction and stability compared to the rear-wheel-drive setup of prior versions, all while integrating seamlessly with the aerodynamic shell to minimize frontal area.[28][28][7] Testing methodologies relied heavily on advanced simulations to validate these designs, given the limitations of physical facilities for hypersonic-equivalent flows. CFD tools such as OpenFOAM for incompressible flows at 200 mph and ANSYS Fluent for compressible regimes up to 400 mph, utilizing meshes with over 40 million cells, enabled precise analysis of pressure distributions, velocity contours, and boundary layer behavior. Wind tunnel testing on scaled models, including those with rolling roads from earlier iterations like Buckeye Bullet 2, supplemented CFD by assessing yaw stability and downforce generation, with a focus on rear-biased negative lift to ensure handling without excessive drag penalties. Tire selection emphasized low-rolling-resistance slicks optimized for high-speed salt flat conditions, contributing to overall vehicle dynamics.[29][11][30]Achievements and Legacy
Land Speed Records
The Buckeye Bullet project has established multiple land speed records in electric and hydrogen fuel cell vehicle categories at the Bonneville Salt Flats in Utah, under the governance of the United States Fuel Economy Racing Association (USFRA) and Fédération Internationale de l'Automobile (FIA). These records adhere to standard rules requiring a two-way average speed over a measured mile or kilometer, with both runs completed in opposite directions within one hour to account for wind and track conditions.[31][24] In October 2004, the Buckeye Bullet 1, powered by nickel-metal hydride batteries, set a U.S. battery electric land speed record with a one-way speed of 314.958 mph. This achievement marked the project's initial milestone in high-speed electric vehicle performance.[8][1] The Buckeye Bullet 2 advanced the project into hydrogen fuel cell technology, setting an international record for fuel cell vehicles in September 2009 with a two-way average speed of 302.877 mph. This record highlighted the viability of alternative powertrains for extreme speeds under USFRA certification.[17] Building on battery electric advancements, the Buckeye Bullet 2.5 achieved a world battery electric land speed record in August 2010, recording a two-way average of 307.666 mph and earning FIA certification as the fastest electric vehicle at the time.[9][3] The Buckeye Bullet 3 further elevated the benchmarks in September 2016, establishing an updated world electric land speed record with a two-way average of 341.264 mph, surpassing the previous mark by 33.598 mph and securing FIA certification. No subsequent records have been set by the Buckeye Bullet vehicles as of 2025.[2][24][32]| Vehicle | Year | Record Type | Speed (mph, average unless noted) | Certification | Venue |
|---|---|---|---|---|---|
| Buckeye Bullet 1 | 2004 | U.S. battery electric | 314.958 (one-way) | USFRA | Bonneville |
| Buckeye Bullet 2 | 2009 | International hydrogen fuel cell | 302.877 | USFRA | Bonneville |
| Buckeye Bullet 2.5 | 2010 | World battery electric | 307.666 | FIA | Bonneville |
| Buckeye Bullet 3 | 2016 | World electric | 341.264 | FIA | Bonneville |