A defeat device is any auxiliary control system in a motor vehicle or engine—typically software or hardware—that detects emissions testing conditions and temporarily alters engine parameters to comply with regulatory limits, while disabling or reducing emission controls during normal operation, resulting in higher pollutant output such as nitrogen oxides (NOx) in real-world driving.[1][2] This practice violates the U.S. Clean Air Act's prohibition on such devices, enacted to ensure emission controls function under foreseeable operating conditions rather than solely in laboratory simulations.[3][4]The concept gained prominence through regulatory enforcement against aftermarket tampering and original equipment manufacturer (OEM) implementations, with the most extensive case involving Volkswagen AG's installation of defeat device software in approximately 590,000 U.S. diesel vehicles (model years 2009–2015) equipped with 2.0-liter engines, enabling NOx emissions up to 40 times legal limits on public roads.[5][2] This scheme, uncovered via independent testing by the International Council on Clean Transportation and confirmed by U.S. Environmental Protection Agency (EPA) and California Air Resources Board investigations, extended globally to about 11 million vehicles, prompting recalls, civil penalties exceeding $14.7 billion in the U.S. alone, and criminal charges against company executives for fraud and obstruction.[6][7] Similar devices have appeared in heavy-duty diesels and aftermarket "tuners" that reprogram enginecontrol units to prioritize performance over emissions, often marketed for fuel economy gains but contributing to widespread tampering violations.[8][4]Defeat devices highlight tensions in emissions regulation, where lab-based type-approval tests diverge from dynamic real-world cycles, incentivizing manufacturers to exploit detection algorithms based on factors like steering angle, speed, or test duration; European Union directives similarly ban them, emphasizing verifiable control effectiveness across operating modes.[9][10] Consequences include elevated public health risks from excess NOx, linked to respiratory issues and premature deaths, as quantified in post-scandal analyses, alongside eroded trust in "clean diesel" marketing that understated trade-offs between greenhouse gases and local air toxics.[11]Enforcement has intensified, with EPA targeting aftermarket sales and states conducting inspections, though challenges persist in detecting sophisticated software adaptations amid evolving vehicle electronics.[3][12]
Definition and Technical Aspects
Legal Definition
In the United States, the term "defeat device" is defined under federal regulations implementing the Clean Air Act as an auxiliary emission control device (AECD) that reduces the effectiveness of the emission control system under conditions reasonably expected in normal vehicle operation and use, unless specific exemptions apply.[13] An AECD itself is any element of design sensing parameters such as temperature, vehicle speed, engine RPM, transmission gear, manifold vacuum, or others to activate, modulate, delay, or deactivate emission controls.[13] Exemptions include conditions substantially replicated in certification test cycles (e.g., federal emission procedures, fuel economy tests under 40 CFR part 600, or air conditioning efficiency tests), protections against vehicle damage or accidents, requirements beyond mere engine starting, or justifications for emergency vehicles to maintain speed, torque, or power during abnormal emission system conditions.[13] This definition, codified in 40 CFR § 86.1803-01, supports prohibitions under Clean Air Act section 203(a)(3) (42 U.S.C. § 7522(a)(3)), which bans manufacturing, selling, or installing parts bypassing emission controls, with civil penalties up to $50,386 per violation (adjusted for inflation) and potential criminal liability.In the European Union, Regulation (EC) No 715/2007 defines a defeat device as any element of design sensing temperature, vehicle speed, engine speed (RPM), transmission gear, manifold vacuum, or other relevant parameters to activate, deactivate, switch, or modulate an emission control system under normal driving conditions, such that it reduces effectiveness beyond test procedures like the New European Driving Cycle (NEDC) or Worldwide Harmonised Light Vehicle Test Procedure (WLTP).[14] Article 3(10) specifies that such devices are prohibited under Article 5(2) unless justified for protecting the system, engine, or catalyst from damage (e.g., low temperatures) or exclusively for engine starting.[14] The European Commission has issued guidance reinforcing detection practices for illegal defeat devices in Euro 6 vehicles, emphasizing parameters altering controls outside type-approval tests.[9] Violations can lead to type-approval revocation, fines, and recalls, as affirmed by European Court of Justice rulings holding that devices improving performance only during tests constitute defeat devices even without intent to cheat.[15]These definitions share roots in distinguishing legitimate auxiliary controls from those evading real-world emission limits, originating from U.S. EPA rulemaking in the 1970s to certify vehicles under the Clean Air Act's Title II.[10] Internationally, similar concepts appear in UNECE regulations (e.g., ECE R83, R49), but U.S. and EU frameworks provide the most detailed codifications, with enforcement focusing on diesel NOx controls post-2015 scandals.[10]
Mechanisms and Implementation
Defeat devices are primarily implemented through software embedded in the vehicle's electronic control unit (ECU), which processes inputs from onboard sensors to identify conditions associated with emissions testing on a dynamometer. These algorithms detect specific patterns, such as minimal steering wheel movement (typically less than 15 degrees), sustained low-speed operation, constant engine RPM, or predefined time-distance profiles matching certification cycles like the FTP-75. Upon recognition of these test-like conditions, the ECU switches to an enhanced emissions mode that activates full control measures, including higher rates of exhaust gas recirculation (EGR), optimized fuel injection timing and pressure, and increased urea dosing in selective catalytic reduction (SCR) systems for diesel engines.[10][16][17]In normal driving, the software reverts to a relaxed control strategy, reducing the aggressiveness of emissions countermeasures to improve fuel economy, engine performance, and component durability, thereby allowing nitrogen oxides (NOx) emissions to exceed regulatory limits by factors of 10 to 40 times in affected diesel vehicles. For example, in Volkswagen's 2.0-liter and 3.0-liter diesel engines, the ECU logic adjusted parameters like injection curve corrections (e.g., InjCrv_stNsCharCor) and delayed air mass changes during detected test cycles, while limiting EGR and SCR in real-world operation. Similar timer-based implementations, as seen in certain Fiat models using Bosch EDC17 ECUs, restrict NOx storage catalyst regeneration after approximately 26 minutes and 40 seconds to differentiate test durations from extended driving.[16][10][17]Hardware-based defeat devices are rarer but can involve auxiliary components that bypass or disable emission hardware, such as modifiable exhaust aftertreatment systems; however, regulatory focus remains on undisclosed software auxiliary emission control devices (AECDs) that fail to meet criteria for legitimate safeguards like engine protection. Detection of these mechanisms often requires firmware analysis or on-road versus laboratory emissions comparisons, as the switch logic is designed to evade standard type-approval testing.[10][16]
Distinctions from Legitimate Auxiliary Emission Control Devices
Auxiliary emission control devices (AECDs) encompass any element of vehicle design that senses parameters such as temperature, vehicle speed, engine revolutions per minute (RPM), transmission gear, or manifold vacuum to activate, modulate, delay, or deactivate components of the emission control system.[13] These devices are permissible under U.S. Environmental Protection Agency (EPA) regulations when they serve essential functions without undermining overall emission performance in typical operation.[13] In contrast, a defeat device is specifically defined as an AECD that reduces the effectiveness of the emission control system under conditions reasonably expected in normal vehicle operation and use, unless those conditions are substantially replicated in federal emission test procedures or qualify under narrow exemptions.[13][18]The primary legal distinction hinges on justification and scope: legitimate AECDs must either incorporate their deactivation conditions into standardized test cycles—such as the Federal Test Procedure (FTP) simulating urban driving—or be demonstrably necessary for engine protection, safe operation, or emergency functionality.[13] For instance, exemptions apply if deactivation prevents substantive engine damage (e.g., disabling exhaust gas recirculation during extreme high-load conditions to avoid overheating), is confined to engine cranking or starting phases (e.g., temporary fuel enrichment for cold-start stability until the catalyst reaches operating temperature), or is limited to emergency vehicles where it averts loss of speed, torque, power, or hazardous emission control malfunctions.[13][18] Manufacturers must disclose all AECDs in their certification applications, providing engineering rationale and data to verify compliance; failure to do so or designing for test-specific evasion renders the device illicit.[19]Defeat devices fail these criteria by intentionally exploiting discrepancies between laboratory testing and real-world driving, often through algorithms that detect non-road conditions like steady-state RPM, absent steering input, or dyno-specific vibrations absent on actual roads.[10] Such mechanisms prioritize passing certification tests over sustained emission reductions, resulting in elevated pollutants—sometimes by factors of 10 to 40 times standards—during everyday use.[10] Unlike legitimate AECDs, which maintain emission controls across expected operating envelopes and are vetted for protective necessity, defeat devices lack engineering justification beyond regulatory circumvention, violating Clean Air Act prohibitions.[20] This distinction underscores a causal divide: legitimate devices balance performance and durability without deliberate deception, while defeat devices embed conditional cheating to mask non-compliant hardware.[13]
Historical Context
Origins in the 1970s
The 1970 amendments to the Clean Air Act established the first federal standards for motor vehicle emissions, requiring significant reductions in hydrocarbons, carbon monoxide, and later nitrogen oxides, while prohibiting the manufacture, sale, or installation of "defeat devices"—any hardware, software, or design that senses vehicle operation conditions and reduces the effectiveness of emission controls except under circumstances unlikely to arise in normal vehicle operation or use.[21] These provisions aimed to ensure real-world compliance beyond laboratory certification tests, which involved steady-state driving cycles on dynamometers without simulating varied loads like air conditioning or highway speeds.[22] The U.S. Environmental Protection Agency (EPA), tasked with enforcement, issued guidance in 1972 stating it would refuse to certify any vehicle equipped with such devices, marking the regulatory foundation for identifying tampering early in the compliance program.[19]Early instances of defeat devices emerged shortly after standards took effect for model year 1972 vehicles, as manufacturers grappled with balancing emission reductions against performance and fuel economy under nascent catalytic converter and engine control technologies. In 1973, the EPA accused Volkswagen of installing unreported devices in its vehicles that modified pollution controls to evade standards during non-test conditions, violating reporting requirements under the Act.[22]Chrysler faced similar accusations that year for analogous mechanisms in its lineup.[21] These primitive devices often relied on mechanical switches or basic sensors detecting test-specific cues, such as minimal steering wheel movement (indicating dynamometer testing) or the absence of air conditioning compressor load, which laboratory protocols rarely activated.[23]By 1974, the EPA had levied fines exceeding $120,000 against manufacturers for failing to disclose such installations, underscoring the agency's proactive auditing through confirmatory testing that revealed discrepancies between certification and in-use emissions. These cases highlighted causal tensions: emission controls like exhaust gas recirculation or retarded ignition timing impaired drivability under load, incentivizing conditional disablement to preserve sales competitiveness, though regulators viewed them as intentional circumvention rather than legitimate auxiliary strategies.[22] Unlike later software-based iterations, 1970s devices were detectable via physical inspection or varied test matrices, prompting EPA refinements in protocols to include more realistic operating modes.[24]
Developments in the 1990s and 2000s
In the 1990s, the widespread adoption of electronic control units (ECUs) in automotive engines enabled more sophisticated software-based defeat devices, which could detect laboratory testing conditions—such as steady speeds, closed throttles, or specific durations—and temporarily activate full emission controls while disabling them during real-world operation to prioritize performance or fuel economy.[24] These mechanisms often manipulated parameters like exhaust gas recirculation (EGR) rates or fuel injection timing, allowing vehicles to pass certification tests under the U.S. Federal Test Procedure but emit higher levels of pollutants like nitrogen oxides (NOx) or carbon monoxide (CO) on roads.[25]A notable early case involved General Motors (GM), which in 1995 settled with the U.S. Environmental Protection Agency (EPA) and Department of Justice for $45 million over defeat devices in approximately 470,000 Cadillac vehicles from model years 1991 to 1995.[26] The devices, computer chips altering engine calibration, increased CO emissions by causing richer fuel mixtures under non-test conditions like low RPM or closed throttle to improve drivability and prevent engine stumble; GM did not admit liability but agreed to the penalty and remedial measures, including emission offset projects estimated to reduce pollution equivalent to the excess 100,000 tons of CO released.[27] Similarly, in 1998, the EPA settled with Ford over software in 60,000 1997 Econoline vans that reduced EGR activation during highway-like conditions outside testing, leading to elevated NOx emissions.[28]The decade's most significant enforcement action came in October 1998, when the EPA and Department of Justice announced a $1 billion settlement with seven heavy-duty diesel engine manufacturers—Caterpillar, Cummins, Detroit Diesel, Mack Trucks, Navistar, Renault Vehicules Industriels, and Volvo Truck—for installing software defeat devices in about 1.3 million engines used in trucks from the late 1980s to 1998.[25] These devices detected the 20-minute certification test cycle and fully engaged emission controls, but disabled EGR or other systems during steady highway speeds, resulting in NOx emissions up to three times legal limits in use; the agreement included an $83.4 million civil penalty—the largest in U.S. environmental history at the time—plus over $850 million for engine recalls, rebuilds, and accelerated development of cleaner technologies, projected to prevent 75 million tons of NOx over 27 years.[25] This case prompted EPA to establish in-use testing programs for heavy-duty vehicles, including the Not-To-Exceed standard by the early 2000s, which expanded verification beyond lab cycles.[24]Into the 2000s, regulatory responses built on these precedents amid tightening standards like EPA Tier 2 for light-duty vehicles (phased in 2004) and Euro 3/4 for Europe, but major OEM scandals were rarer as manufacturers shifted toward auxiliary emission controls requiring justification; however, the heavy-duty settlement's implementation continued, with ongoing recalls and NOx reduction projects through 2003.[22] Aftermarket defeat devices also proliferated with diesel popularity, though EPA enforcement focused more on OEM compliance, setting the stage for advanced software cheats in later electronic diesel systems.
Escalation in the 2010s
The 2010s marked a period of escalation in defeat device deployment, driven by increasingly stringent nitrogen oxides (NOx) limits under the European Union's Euro 5 standards, which reduced the threshold for diesel passenger cars to 180 mg/km starting September 2009 for new types and January 2011 for all registrations, followed by Euro 6's further cut to 80 mg/km from September 2014.[29] These regulations compelled widespread adoption of complex aftertreatment systems like selective catalytic reduction (SCR), which effectively lowered emissions in laboratory conditions but imposed real-world trade-offs in fuel economy, power output, and operational costs.[30]Manufacturers responded by developing advanced software algorithms integrated into engine control units, capable of discerning test cycles from normal operation via inputs such as steering angle, acceleration patterns, ambient temperature, and driving duration—rendering earlier mechanical or basic sensor-based cheats obsolete in favor of multi-parameter detection schemes that minimized detection risk.[16][30] This sophistication allowed emissions controls to activate fully only during simulated tests, while deactivating them on roads to preserve performance, with devices originating from suppliers like Bosch and customized by original equipment manufacturers (OEMs).[16]Coinciding with diesel vehicles comprising 53% of new EU passenger car sales by 2015—their market peak—this trend reflected intensified competitive pressures to promote "clean diesel" technology amid rising demand for efficient yet high-performing engines.[31] Volkswagen Group, for instance, incorporated such software in approximately 11 million diesel vehicles globally from model year 2009 onward, including popular 2.0-liter TDI variants sold extensively through the decade.[2] Similar software implementations appeared in vehicles from Fiat Chrysler, highlighting a pattern where regulatory emphasis on type-approval testing outpaced verification of real-driving emissions.[16]
Major Cases and Scandals
Volkswagen Dieselgate (2015)
The Volkswagen emissions scandal emerged in September 2015 when the United States Environmental Protection Agency (EPA) issued a notice of violation alleging that Volkswagen had installed defeat devices in diesel vehicles to circumvent federal emissions standards.[2] The issue originated from on-road testing conducted by the International Council on Clean Transportation (ICCT) in collaboration with West Virginia University during 2013 and 2014, which revealed that two Volkswagen models—a Jetta and a Passat—emitted nitrogen oxides (NOx) at levels 15 to 40 times higher than laboratory limits under real-world highway conditions.[32][33] Volkswagen admitted on September 22, 2015, that approximately 11 million vehicles worldwide were equipped with software enabling such cheating.[34]The defeat device consisted of engine control unit (ECU) software programmed to recognize emissions testing scenarios through sensors detecting specific patterns, such as limited steering wheel movement, consistent acceleration, or closed throttle positions typical of dynamometer tests.[34][7] During detected tests, the software activated full emissions controls to meet standards; otherwise, it prioritized performance, resulting in NOx emissions up to 40 times the permitted levels in normal operation.[2] Affected models primarily included 2.0-liter and 3.0-liter turbocharged direct injection (TDI) diesel engines in vehicles like the Jetta, Golf, Passat, and Audi and Porsche variants, spanning model years 2009 to 2015.[2] In the United States, around 590,000 vehicles were implicated, while Europe saw about 8 million.[2][35]Legal repercussions followed swiftly, with Volkswagen facing civil and criminal penalties under the Clean Air Act. In June 2016, the company agreed to a settlement of up to $14.7 billion in the U.S., covering vehicle buybacks, owner compensation, environmental mitigation, and civil penalties—the largest for such violations.[7] This included recalling and repairing or buying back affected 2.0-liter vehicles at an 85% rate, alongside scrappage programs for older models.[7] Globally, costs exceeded $33 billion by 2019, encompassing fines, settlements, and stock value losses.[36] Several executives, including engineers, faced U.S. charges for fraud and Clean Air Act violations, with some pleading guilty or being convicted.[35] The scandal prompted Volkswagen CEO Martin Winterkorn's resignation and accelerated the company's shift away from diesel technology.[35]
Other OEM Instances (e.g., Fiat, Mercedes)
In 2017, the U.S. Environmental Protection Agency (EPA) identified defeat devices in approximately 104,000 Fiat Chrysler Automobiles (FCA) "EcoDiesel" vehicles, including 2014-2016 Jeep Grand Cherokee SUVs and Ram 1500 pickup trucks, where software features reduced nitrogen oxide (NOx) emissions during laboratory testing but allowed higher emissions under real-world driving conditions.[37][38] These devices violated Clean Air Act prohibitions on tampering with emissions controls, leading to FCA's agreement in January 2019 to pay over $800 million in civil penalties, fund emissions fixes, and implement a recall program to remove the software from affected vehicles.[39][40] In August 2022, a U.S. federal court sentenced FCA to an additional $300 million fine for the scheme, which involved collaboration with Bosch on the enabling software, emphasizing that the vehicles emitted up to nine times the permitted NOx levels in normal operation.[41][42]Mercedes-Benz, under parent company Daimler AG, faced similar allegations for installing undisclosed software functions amounting to defeat devices in over 250,000 BlueTEC diesel vehicles sold in the U.S. from model years 2009-2016, which altered emission control performance to comply with tests while permitting higher NOx outputs—up to 16 times legal limits—in everyday driving.[43][44] This resulted in a $1.5 billion settlement in September 2020 with the U.S. Department of Justice, EPA, and California, including buybacks, modifications, and penalties, without Daimler admitting liability but acknowledging the software's role in circumventing standards.[45][46] In Europe, Mercedes issued recalls in 2023 for models like the E 300 and C 300 de, where defeat devices bypassed Euro 6 NOx limits, following investigations prompted by post-Dieselgate scrutiny.[47] A German court ruling in March 2024 confirmed that Mercedes executives knowingly approved such devices, rejecting claims of mere thermal management software.[48]Other original equipment manufacturers (OEMs) have faced probes for potential defeat devices, though fewer reached the scale of confirmed settlements seen with FCA and Daimler. For instance, Renault and PSA Peugeot Citroën recalled nearly 16 million diesel vehicles in 2016-2017 after discrepancies in real-world emissions, but French authorities found no illegal defeat devices, attributing issues to calibration differences rather than deliberate cheating hardware or software. Investigations into BMW and Opel (General Motors) yielded no verified defeat device implementations equivalent to those in Volkswagen-group or Daimler cases, with BMW emphasizing compliant auxiliary emission controls in its diesels. These instances highlight varying degrees of regulatory findings, where empirical testing often distinguished intentional circumvention from permissible optimizations.
Aftermarket Devices and Tampering
Aftermarket defeat devices encompass hardware and software modifications installed post-manufacture to circumvent emissions control systems, such as diesel particulate filters (DPF), exhaust gas recirculation (EGR) valves, and selective catalytic reduction (SCR) systems, often marketed as "delete kits" or performance tuners for improved engine power, fuel efficiency, or reduced maintenance costs.[49] These devices detect or bypass emissions testing protocols, allowing vehicles to emit higher levels of nitrogen oxides (NOx), particulate matter (PM), and other pollutants during normal operation while complying during inspections.[3] Tampering, defined under the U.S. Clean Air Act as any action that renders emissions controls inoperative, includes physical removal of components or reprogramming engine control units (ECUs), and applies to both on-road vehicles and non-road engines like heavy-duty trucks and off-road equipment.[50]Such modifications are strictly prohibited federally, with the EPA designating the prevention of aftermarket defeat devices as a National Compliance Initiative from 2020 through 2023 and beyond, due to their role in undermining certified emissions standards.[3] Violations can result in civil penalties up to $48,192 per device or per vehicle tampered, plus injunctive relief to cease sales or installations, as outlined in EPA's 2020 updated enforcement policy.[51] Proponents in diesel enthusiast communities claim these alterations address reliability issues with factory systems, such as frequent DPF clogging leading to costly repairs, but empirical data from EPA testing shows tampered vehicles can emit up to 100 times the regulated levels of certain pollutants like PM.[52]Enforcement has intensified, targeting manufacturers, sellers, and installers. In June 2024, Full Force Diesel Performance paid $525,438 in penalties for selling defeat devices over two years, affecting hundreds of vehicles.[53] Meyer Distributing settled for $7.4 million in January 2025 after distributing tens of thousands of illegal parts.[54] Criminal cases include a Louisiana firm and its owner sentenced in December 2024 for producing software that disabled emissions on motor vehicles, and a father-son duo indicted in November 2024 for smuggling $33 million worth of tuners from Canada, generating over $74 million in revenue.[55][56] Rudy's Performance Parts faced a 2024 civil suit for selling over 250,000 tampering products from 2014 to 2019.[57] A New York diesel dealer received a $50,000 fine and four years' probation in April 2024 for emissions deletions on pickup trucks.[58] These actions reflect EPA's focus on high-volume offenders, with cumulative penalties exceeding tens of millions annually, though individual vehicle owners face risks of fines or vehicle impoundment upon detection during inspections or audits.[3] Despite some regulatory shifts, such as post-Chevron deference discussions in 2024, tampering remains illegal under federal law, with states enforcing additional penalties.[59]
Regulatory Responses
United States Framework (EPA and Clean Air Act)
The United States Environmental Protection Agency (EPA) establishes and enforces emission standards for new motor vehicles and engines under Title II of the Clean Air Act (CAA), originally passed in 1970 and amended in 1977 and 1990 to strengthen mobile source controls targeting pollutants such as nitrogen oxides (NOx), particulate matter (PM), and hydrocarbons. These standards require vehicles to meet specified emission limits during federal certification testing, including the Federal Test Procedure (FTP) simulating urban driving cycles.[60]Section 203(a)(3) of the CAA forms the core prohibition against defeat devices, making it unlawful for any person to knowingly remove or render inoperative any emissions-related device or element of design installed to comply with regulations after the vehicle's sale and delivery to an ultimate purchaser, or to manufacture, sell, offer to sell, or install any part or component with the principal effect of bypassing, defeating, or rendering inoperative such controls.[61] This tampering ban applies to both original equipment manufacturers (OEMs) and aftermarket modifications, with EPA interpreting "render inoperative" to include software strategies that disable controls outside test conditions.[12]EPA regulations distinguish defeat devices from permissible auxiliary emission control devices (AECDs), defined as any design element sensing parameters like temperature, vehicle speed, engine RPM, transmission gear, or manifold vacuum to activate, deactivate, or modify emission controls.[62] A defeat device specifically constitutes an AECD that reduces emission control system effectiveness under conditions reasonably expected in normal operation and use, unless those conditions are substantially replicated in EPA-prescribed testing or justified by engineering analysis demonstrating necessity to prevent unsafe operation, engine damage, or emissions trade-offs within limits.[63] Examples include software detecting dynamometer testing via steering angle or lack of acceleration to suppress NOx aftertreatment.[1]During the certificationprocess, manufacturers submit applications for a certificate of conformity, detailing engine families, emission control systems, and all AECDs with supporting data on activationlogic and emission impacts.[60] EPA reviews these disclosures to identify potential defeat strategies, requiring justification for any AECD deactivating controls; unapproved reductions in effectiveness result in certification denial or designation as a defeat device.[64]Compliance extends to in-use testing, where EPA may conduct confirmatory or selective enforcement audits, potentially leading to recalls if real-world emissions exceed certified levels due to prohibited devices.[3]Violations under Section 203 carry civil penalties adjusted annually for inflation: as of 2024, up to $57,617 per motor vehicle or engine for manufacturers and dealers, and $4,819 per defeat device or tampered vehicle for other persons.[65][12] Knowing violations can incur criminal fines up to $250,000 for individuals or $500,000 for organizations, plus imprisonment. EPA prioritizes enforcement against aftermarket defeat devices through nationalcompliance initiatives, including settlements requiring cessation of sales and mitigation measures.[3]
European Union Regulations
The primary European Union regulation addressing defeat devices in light-duty vehicles is Regulation (EC) No 715/2007, which establishes requirements for type-approval of motor vehicles and engines with respect to emissions from light passenger and commercial vehicles.[66] Article 3(10) defines a defeat device as "any equipment or element of software installed in an engine or motor vehicle which is intended to reduce the effectiveness of emission control systems under normal use and conditions of use."[9] Article 5(2) explicitly prohibits the use of such devices that reduce the effectiveness of emission control systems, with narrowly defined exceptions only permitted where they are justified by verifiable technical reasons, such as safe operation, minimal emissions impact, or protection from damage under specific conditions like low ambient temperatures.[66] Implementing measures under Regulation (EC) No 692/2008 further specify test procedures to detect defeat devices during type-approval.[10]For heavy-duty vehicles, Directive 2001/27/EC prohibits the use of defeat devices and "irrational" emission control strategies that deactivate systems without justification, building on earlier Euro standards.[67] These prohibitions were integrated into subsequent Euro VI standards for heavy-duty engines, emphasizing consistent emission control across laboratory and real-world conditions.[67] The introduction of Euro 6 standards for light-duty vehicles via Regulation (EU) 2016/646 amended Regulation (EC) No 715/2007 to incorporate real-driving emissions (RDE) testing, requiring manufacturers to declare base emission strategies (BES) and any auxiliary emission strategies (AES) that could function as defeat devices.[68] This amendment aimed to close loopholes exposed by discrepancies between lab tests and on-road performance, mandating conformity factors to account for real-world exceedances.[69]Enforcement relies on type-approval authorities across member states, with the European Commission issuing guidance in 2023 on detecting defeat devices through data analysis, in-use testing, and evaluation of AES claims.[9] The Court of Justice of the European Union (CJEU) has clarified interpretations, ruling in 2021 (Case C-178/20) that software altering emission control solely to pass type-approval tests constitutes a prohibited defeat device, even if it enhances performance under test conditions, unless it falls under explicit exceptions.[70] A 2025 CJEU decision affirmed manufacturer liability for defeat devices in Volkswagen vehicles, reinforcing that such mechanisms violate EU law by concealing real-world emissions.[71] Violations can lead to type-approval revocation, market recalls, and fines, though implementation varies by member state due to decentralized enforcement.[72]
Enforcement Actions and Legal Precedents
In the United States, the Environmental Protection Agency (EPA) enforces prohibitions on defeat devices under Section 203(a) of the Clean Air Act, which makes it unlawful to manufacture, sell, or install parts that bypass emissions controls.[12] Major original equipment manufacturer (OEM) cases include Volkswagen's 2017 guilty plea to felony counts, resulting in a $2.8 billion criminal penalty and civil settlements totaling over $25 billion for buybacks, fixes, and consumer compensation across approximately 580,000 affected diesel vehicles.[2][73]Fiat Chrysler Automobiles (FCA) settled in January 2019, agreeing to software updates to remove defeat devices in over 100,000 diesel vehicles and pay civil penalties as part of multistate actions addressing undisclosed auxiliary emission control devices.[74][39] Daimler AG, parent of Mercedes-Benz, reached a $1.5 billion civil settlement in September 2020 for installing defeat devices in about 250,000 diesel vehicles, requiring repairs and compliance measures.[43][44]EPA has intensified actions against aftermarket defeat devices, designating their elimination a National Compliance Initiative for 2020-2023, leading to 172 civil cases with $55.5 million in penalties.[3] Examples include the August 2021 settlement with Gear Box Z, halting sales of tuning devices that increased emissions, and a December 2024 agreement with a Nashville seller to cease distribution.[75][76]Key legal precedents under the Clean Air Act affirm broad liability for defeat devices. In August 2025, the Second Circuit revived a DOJ case against EZ Lynk companies, rejecting defenses based on software's non-physical nature and internet sales, reversing prior precedent to hold manufacturers accountable regardless of distribution method.[77] A April 2024 district court ruling permitted CAA enforcement against a Canadian firm selling defeat devices to U.S. buyers, extending jurisdiction extraterritorially when effects occur domestically.[78]In the European Union, enforcement relies on type-approval regulations prohibiting defeat devices, with the Court of Justice of the EU (CJEU) providing precedents. An August 2025 CJEU ruling held Volkswagen liable for unlawful defeat devices post-type approval, maintaining manufacturer responsibility for compliance failures.[71] Earlier 2021 and 2023 CJEU decisions clarified that devices altering emissions controls outside test conditions violate prohibitions, even if improving performance during approval, facilitating member state actions against non-compliant vehicles.[70][79] These rulings have spurred national enforcements, though fines and recalls vary by country, with ongoing calls for harmonized penalties.[80]
Environmental and Health Claims
Measured Excess Emissions Data
Independent on-road testing of Volkswagen 2.0-liter TDI diesel vehicles affected by the defeat device revealed NOx emissions ranging from 15 to 40 times the certified laboratory levels under normal driving conditions, with specific measurements on U.S. models showing averages of approximately 28 times the standard during highway cycles.[81] These excesses were quantified using portable emissions measurement systems (PEMS) during real-world routes, contrasting sharply with type-approval dyno tests where emissions complied with Euro 5 and U.S. EPA limits of 180 mg/km and 0.043 g/mi, respectively.[82] Cumulative excess NOx from roughly 9 million affected Volkswagen vehicles sold in Europe and the U.S. between 2009 and 2015 totaled an estimated 526 kilotons, derived from mileage-adjusted emission factors.[83]For Mercedes-Benz diesel models equipped with alleged auxiliary emission control devices functioning as defeat mechanisms, expert PEMS analyses reported real-world NOx outputs exceeding rated limits by factors of up to 10 during dynamic driving, particularly in models like the GLE 350d under Euro 6 standards.[43] Similar evaluations in ongoing European probes indicated NOx spikes of 5 to 6 times certified values in prohibited warm-up and regeneration modes, though comprehensive fleet-wide data remains limited pending full regulatory verification.[80]Fewer quantified measurements exist for Fiat Chrysler Automobiles (FCA) instances, where Italian transport ministry tests on 2014-2017 diesel engines identified defeat software leading to on-road NOx emissions 4 to 7 times above Euro 6 type-approval figures in select Alfa Romeo and Jeep models, based on controlled road simulations.[82] These findings, while not as extreme as Volkswagen's, highlight consistent patterns of elevated emissions under non-test conditions across implicated original equipment manufacturers.
Affected Fleet
Measured NOx Excess Factor (Real-World vs. Certified)
Post-scandal regulatory audits, including EPA confirmatory testing and EU Real Driving Emissions (RDE) protocols, corroborated these disparities, attributing them directly to defeat device activation thresholds like steering angle, duration, or altitude sensors that suppressed urea injection and exhaust aftertreatment only outside dyno profiles.[2] Variability in excess factors arose from driving styles, ambient conditions, and odometer accumulation, with peer-reviewed models adjusting for fleet averages yielding annual U.S. excesses of 237 to 949 kilotons NOx from Volkswagen alone pre-recall.[84] Such data underscores the gap between controlled certification and operational emissions, though some analyses caution against overgeneralizing from outlier tests without broader sampling.[85]
Attributed Health Impacts and Empirical Limitations
Estimates of health impacts from defeat devices primarily focus on excess nitrogen oxides (NOx) emissions from affected diesel vehicles, which contribute to ground-level ozone, secondary particulate matter (PM2.5), and nitrate aerosols linked to respiratory and cardiovascular conditions. In the United States, a 2015 modeling study of Volkswagen's 2009–2015 diesel vehicles projected 59 premature deaths nationwide from excess NOx, alongside 14,300 lost workdays and economic costs of $450–5,100 million, based on atmospheric chemistry transport models and concentration-response functions from the American Cancer Society cohort. A 2024 refinement incorporating updated exposure risks confirmed approximately 60 premature deaths or future equivalents in the US from these vehicles.[11] In Europe, simulations for Volkswagen diesels sold 2008–2015 attributed 1,200 premature deaths (range 590–2,700) to excess NOx, with primary PM2.5 and ozone as key mediators, drawing on GEOS-Chem modeling and regional epidemiological data.[86] Broader assessments encompassing defeat devices in multiple manufacturers (e.g., Fiat, Mercedes) across EU and UK diesel fleets from 2009–2024 estimate 124,000 premature deaths, 98,000 new childhood asthma cases, and substantial years lived with disability from chronic obstructive pulmonary disease, though these incorporate projected future emissions and higher-end uncertainty bounds.[87][88]These projections derive from integrated assessment models coupling emission inventories with health impact functions, yet empirical limitations constrain their precision and causal inference. Uncertainties arise from quantified variabilities in excess NOx estimates (often ±50% or more), meteorological dispersion, and population exposure, propagated through Monte Carlo simulations but still yielding wide confidence intervals that can span orders of magnitude for morbidity outcomes like lost workdays (e.g., 700–18,000).[89][90] Concentration-response relationships, typically extrapolated linearly from high-exposure epidemiological cohorts (e.g., Harvard Six Cities or ACS studies), assume no safe threshold for ozone or PM2.5 effects, an assumption critiqued for potential overstatement at near-compliance ambient levels where vehicle contributions are marginal relative to industrial, powerplant, or biogenic sources.[89] Causal attribution further falters without direct, vehicle-specific health surveillance data; background pollution trends, socioeconomic confounders, and transboundary transport (e.g., 70% of modeled NOxhealth effects crossing borders) obscure isolated impacts from defeat-equipped fleets comprising <1% of total vehicleNOx in affected regions.[91] No peer-reviewed analyses demonstrate observable spikes in mortality or morbidity rates temporally aligned with scandal revelations or spatially concentrated around high-penetration areas, relying instead on counterfactual scenarios that may not reflect real-world emission controls or fleet turnover.[86]
Counterarguments on Causal Attribution and Overestimation
Critics of health impact assessments related to defeat devices argue that the causal chain from excess NOx emissions to adverse outcomes involves multiple layers of modeling with compounded uncertainties, often inadequately propagated, which can inflate estimates and obscure whether effects are distinguishable from background variability. For instance, analyses of Volkswagen's U.S. emissions have estimated 40–59 excess premature deaths, but comments on these studies highlight flaws such as reliance on limited test vehicle data to extrapolate fleet-wide excess emissions, ignoring variability in real-world performance and potential overestimation of the gap between compliant and non-compliant NOx outputs.[92] Such assumptions fail to incorporate distributions of in-use emissions, potentially leading to singular point estimates that mask ranges where impacts approach zero.[92]Causal attribution is further complicated by incomplete accounting for atmospheric chemistry and emission trade-offs. Defeat devices primarily elevated NOx, but models often overlook shifts in NO/NO₂ ratios that influence secondary particulate matter formation, as well as possible reductions in other pollutants like ammonia slip or particulates during non-test conditions, which could offset health burdens.[92] In regions with diverse NOx sources—including power plants, non-diesel vehicles, and industrial activity—isolating the marginal contribution from affected diesels (which comprised under 1% of the U.S. light-duty fleet in the relevant period) proves challenging, as ambient concentrations reflect cumulative inputs rather than vehicle-specific increments.[2]Epidemiological concentration-response functions underpinning these assessments typically assume linear relationships extending to negligible pollutant levels, yet evidence indicates thresholds beyond which effects manifest; for NO₂, a key NOx derivative, confirmed health risks emerge above an annual mean of 20 µg/m³, with limited causality below this in cleaner environments.[93] Critiques of fine particulate matter (PM₂.₅) modeling, relevant to secondary aerosols from NOx, suggest that apparent supralinearity or persistence at low exposures may stem from measurement errors, confounding variables, or model misspecification rather than direct causation, potentially overstating benefits from marginal reductions.[94] Empirical observations post-scandal, such as no detectable surges in respiratory or cardiovascular events in high-penetration areas despite revealed excesses, underscore limitations in attributing population-level harms to defeat devices amid broader air quality improvements and multifactorial disease drivers like socioeconomic status and lifestyle.[92]
Broader Implications
Economic Costs to Industry and Consumers
The Volkswagen emissions scandal, involving defeat devices in approximately 11 million diesel vehicles worldwide, imposed substantial financial burdens on the automotive industry, with the company incurring over $33 billion in cumulative costs by 2020, encompassing fines, civil penalties, criminal settlements, and vehicle remediation efforts.[2][7] In the United States alone, Volkswagen agreed to a $14.7 billion settlement in 2016, including up to $10 billion for consumer buybacks, lease terminations, and vehicle modifications, alongside a $2.8 billion criminal penalty for violating the Clean Air Act.[7][2] Globally, these expenditures extended to roughly €32 billion ($37 billion) for refits, fines, and legal proceedings by 2025, contributing to operational losses estimated at 8.45% of quarterly profits immediately following the scandal's disclosure.[95][96] Similar, though smaller-scale, costs affected other manufacturers like Fiat Chrysler and Mercedes-Benz, which faced penalties and recalls for comparable emissions manipulations, amplifying industry-wide compliance expenditures.[97]Recall and buyback programs represented a core component of these industry outlays, with Volkswagen committing to remediate or repurchase about 500,000 affected vehicles in the U.S. and 8.5 million in Europe, incurring logistical and engineering costs that strained supply chains and production timelines.[35] These efforts not only depleted capital reserves—prompting share price declines and executive resignations—but also diverted resources from innovation, as firms reallocated billions toward emissions-testing overhauls and legal defenses.[98] Spillover effects extended to competitors, with non-VW diesel models experiencing an average valuation drop of $2,057 due to eroded consumer trust in diesel technology.[99]Consumers faced indirect economic repercussions, including depreciated resale values for affected vehicles prior to settlements; for instance, the scandal triggered a sharp decline in used diesel car prices in markets like Israel, reflecting heightened scrutiny and reduced demand.[100] While direct owners benefited from compensation packages—such as full buyback at original purchase prices plus interest under the U.S. settlement—broader market shifts led to higher upfront costs for replacement vehicles, as manufacturers passed compliance investments onto pricing amid a pivot away from diesel engines toward electrification.[7] Post-fix vehicles often exhibited reduced fuel efficiency or performance, potentially increasing long-term ownership expenses, though empirical data on these differentials remains limited to anecdotal reports from remediation programs.[101] The scandal's reputational fallout further depressed diesel segment sales, constraining consumer options and elevating average vehicle costs industry-wide by fostering accelerated regulatory-driven transitions.[99]
Incentives from Regulatory Stringency
Stringent emissions regulations, such as the European Union's Euro 6 standard effective from September 2015, which limits diesel passenger car NOx emissions to 80 mg/km, impose significant technical challenges on manufacturers relying on diesel engines, which inherently produce higher NOx levels under lean-burn conditions compared to gasoline counterparts. Compliance typically necessitates advanced aftertreatment systems like selective catalytic reduction (SCR), requiring urea injection to achieve high NOx conversion efficiencies, but these add substantial costs—estimated at around $350 per BlueTec SCR unit—and can degrade fuel economy by 3-5% due to system demands.[102][103]These regulatory demands create economic incentives for evasion through defeat devices, as full real-world compliance often conflicts with performance, durability, and cost competitiveness; for instance, SCR systems increase maintenance burdens, such as diesel particulate filter replacements every 50,000 miles rather than the mandated 120,000 miles, eroding profit margins on vehicles marketed for efficiency.[16] Automakers face pressure to meet fleet-average fuel economy and emissions targets without pivoting to costlier alternatives like hybridization, prompting software-based solutions that detect lab test conditions (e.g., via steering wheel angle or ambient temperature proxies) to temporarily activate controls, thereby passing type-approval cycles like the New European Driving Cycle while optimizing normal operation for better drivability and sales appeal.[102]In the Volkswagen case, the push to introduce "clean diesel" models in the U.S. under tightening EPA Tier 2 standards (NOx limit of 0.07 g/mi by 2007) incentivized defeat devices in approximately 580,000 vehicles from 2009-2015, allowing the company to avoid immediate SCR retrofits amid internal delays and costs, preserving market share against competitors like BMW and Daimler while claiming compliance with "stringent emission requirements."[104][102] This approach yielded short-term financial benefits by sidestepping R&D investments and production line changes, though it exposed systemic risks when real-world testing revealed NOx outputs up to 40 times legal limits.[16]Critics of such stringency argue that lab-centric testing regimes, disconnected from variable real-world conditions like cold starts or load stress, amplify these incentives by rewarding test-specific optimization over robust engineering, potentially stifling innovation in balanced emission-performance trade-offs rather than fostering outright deception.[102] Empirical analyses of engine control unit firmware, such as those from Bosch used in Volkswagen models, reveal widespread implementation of detection logic across hundreds of variants, underscoring how regulatory deadlines and penalty avoidance drive such proliferation despite legal prohibitions under the Clean Air Act.[16][12]
Debates on Testing Realism and Innovation Trade-offs
Critics of traditional laboratory-based emissions testing protocols, such as the pre-2017 New European Driving Cycle (NEDC) and U.S. Federal Test Procedure (FTP), argue that these cycles fail to replicate real-world driving dynamics, including variable speeds, aggressive acceleration, and environmental factors like temperature and altitude, resulting in certified emissions levels that underestimate actual on-road outputs by factors of 2 to 7 times for nitrogen oxides (NOx) in diesel vehicles.[105] This discrepancy incentivized manufacturers to prioritize test-specific optimizations, sometimes crossing into illegal defeat devices, as engineering resources were diverted toward exploiting predictable, low-stress test conditions rather than robust real-world compliance.[106] For instance, the Volkswagenscandal revealed software that detected lab conditions and reduced emissions controls, highlighting how non-representative tests created a false compliance illusion while allowing higher real-world pollution.[107]Proponents of lab testing counter that standardized cycles provide essential reproducibility and cost-effective certification, enabling global harmonization and preventing variability from subjective real-world interpretations that could undermine enforcement uniformity. They note that post-scandal reforms, including the Worldwide Harmonized Light Vehicles Test Procedure (WLTP) introduced in Europe in 2017 and enhanced U.S. multi-cycle testing, have narrowed the lab-real gap to about 20-40% for CO2 emissions without fully abandoning controlled environments.[108] However, industry stakeholders, including automakers, contend that even updated protocols like WLTP remain insufficiently dynamic, pushing continued reliance on auxiliary real-driving emissions (RDE) tests with portable emissions measurement systems (PEMS), which impose higher validation burdens and delay vehicle launches by requiring extensive on-road data collection.[106]These realism debates intersect with innovation trade-offs, as overly rigid lab standards may stifle development of efficient internal combustion engines by enforcing compliance paths that prioritize emissions gimmicks over holistic performance gains, such as advanced turbocharging or hybrid integration tailored to actual usage.[109] Empirical evidence from the U.S. shows that tightening standards correlated with accelerated adoption of selective catalytic reduction (SCR) and exhaust gas recirculation in diesels pre-2015, yet the VW case demonstrated how unbridgeable real-world NOx challenges—stemming from diesel's inherent combustion trade-offs against fuel economy—led to circumvention rather than breakthrough tech.[106] Conversely, advocates for stringent testing assert it compels long-term shifts toward electrification, with Europe's RDE conformity factors (allowing up to 50% excess NOx initially) balancing verification rigor against innovation pace, though critics warn that excessive real-world stringency raises development costs by 10-20% and favors incumbents with resources for complex simulations over nimble startups.[110][109] Ultimately, causal analysis suggests that testing realism enhances causal accountability for emissions but risks innovation bottlenecks if not calibrated to feasible engineering margins, as evidenced by slowed diesel R&D post-Dieselgate amid regulatory pivots to battery electrics.[106]
Recent Developments (2020–2025)
EPA Policy Shifts on Aftermarket Devices
In November 2020, the U.S. Environmental Protection Agency (EPA) issued a revised enforcement policy on vehicle and engine tampering and aftermarket defeat devices under the Clean Air Act (CAA), superseding guidance from 1974. This update introduced detailed, non-exhaustive criteria for aftermarket manufacturers, sellers, and installers to demonstrate a "reasonable basis" that their products do not increase emissions beyond certified levels, such as through comparative emissions testing against stock configurations, equivalence to original equipment manufacturer parts, or state certifications like those from the California Air Resources Board. The policy emphasizes pre-existing documentation and excludes original equipment manufacturers and on-board diagnostics violations, aiming to distinguish legitimate performance enhancements from illegal defeat devices while maintaining prohibitions on tampering that bypasses emissions controls.[111][50]From fiscal year 2020 through 2023, the EPA elevated enforcement against aftermarket defeat devices—defined as parts or software like tuners and exhaust modifications that inhibit emissions systems—as a National Enforcement and Compliance Initiative (NECI), one of six high-priority areas. This period saw expanded activities, including trainings for inspectors from 26 states and localities, investigations into over 550,000 potentially tampered diesel trucks emitting excess nitrogen oxides, and settlements resolving more than 20 cases despite pandemic disruptions. The initiative targeted manufacturers, distributors, and installers, resulting in civil penalties and injunctions against sales of non-compliant products.[3]In August 2023, the EPA deprioritized aftermarket defeat devices by excluding them from the FY2024 NECI list, reclassifying enforcement as standard rather than national priority, which the Specialty Equipment Market Association attributed to industry compliance improvements like emissions certifications. However, the underlying CAA prohibitions persisted, with ongoing actions including a September 2024 settlement imposing a $2.9 million civil penalty on COBB Tuning Products for selling tuning software that disabled emissions controls on gasoline vehicles.[112][113]As of September 2025, under the second Trump administration, aftermarket emissions enforcement remained off the NECI list, aligning with a deregulatory stance that has included repeals of certain greenhouse gas standards but left CAA tampering bans intact. Industry advocates anticipate further discretion for compliant parts via programs like SEMA's emissions certification, though a five-year statute of limitations applies to most civil cases, with potential extensions for criminal violations.[114]
EU Court Rulings and Ongoing Probes
In March 2023, the European Court of Justice (ECJ) ruled that purchasers of diesel vehicles equipped with unlawful defeat devices are entitled to compensation from manufacturers if the devices caused higher emissions in real-world driving conditions compared to type-approval tests, even without proof of intent or measurable harm during normal operation.[115][116] This decision, stemming from cases involving Mercedes-Benz, clarified that such devices violate EU law under Regulation (EC) No 715/2007, facilitating claims by lowering evidentiary burdens for affected owners across member states.[117]Building on prior jurisprudence, the ECJ in July 2022 determined that "thermal window" mechanisms—software that deactivates or reduces emissions controls below certain temperatures—qualify as defeat devices unless strictly necessary for engine protection and inactive for most of the year, as these often lead to elevated NOx emissions outside testing conditions.[118][119] This ruling, in joined cases C-30/21 to C-33/21, expanded scrutiny of auxiliary emission strategies, prompting reassessments of compliance in pre-Real Driving Emissions (RDE) vehicles sold from 2010 onward.[120]On August 1, 2025, in Case C-666/23, the ECJ held that vehicle manufacturers like Volkswagen cannot evade liability for unlawful defeat devices by citing EC type-approval, as such approvals do not verify device legality, and liability persists whether the device was factory-installed or added via post-sale software updates.[71][121] The court specified that compensation may be adjusted downward based on vehicle usage duration or capped at 15% of the purchase price, but must remain sufficient to remedy the defect's impact, reinforcing manufacturer accountability under EU consumer protection directives.[122]These rulings have spurred ongoing national-level probes and litigation in EU member states, with analyses estimating millions of vehicles potentially affected by prohibited devices, though EU-wide enforcement remains fragmented across type-approval authorities.[80] Independent assessments, such as those by the International Council on Clean Transportation, have identified suspicious NOx exceedances in models from multiple makers, informing calls for expanded investigations but highlighting challenges in causal verification beyond lab discrepancies.[123] No centralized EU Commission probe into new defeat device cases was publicly active as of October 2025, with focus shifting to compliance under updated RDE protocols.
Emerging Cases and Recalls
In January 2024, the U.S. Department of Justice and California announced a $1.675 billion civil settlement with Cummins Inc. for installing software-based defeat devices in approximately 630,000 Ram 2500 and 3500 pickup trucks equipped with 6.7-liter diesel engines from model years 2013 to 2019, plus an additional 330,000 engines in off-road equipment; Cummins neither admitted nor denied the allegations but agreed to the penalty, the largest ever under the Clean Air Act. As part of the agreement, Cummins committed to recalling and repairing at least 85% of the affected Ram trucks within three years through software updates to eliminate the defeat functions, which allegedly reduced emissions controls under non-testing conditions like closed-loop operation or specific temperatures.[124] The U.S. Environmental Protection Agency estimated these devices enabled excess nitrogen oxide emissions totaling up to 2.5 million tons over the vehicles' lifetimes.Earlier in September 2020, Daimler AG settled with U.S. authorities for $1.5 billion over defeat devices in Mercedes-Benz diesel vehicles, including BlueTEC models from 2009 to 2016, affecting over 250,000 U.S. vehicles; the company admitted no criminal liability but agreed to civil penalties and a recall program to remove the devices via hardware and software fixes at no cost to owners.[44] The devices reportedly detected testing cycles and altered engine parameters to pass lab standards while emitting higher pollutants during real-world driving, contributing an estimated 7,700 tons of excess NOx in the U.S.[44]Beyond original equipment manufacturers, the EPA has pursued numerous aftermarket defeat device cases since 2020, finalizing 172 civil enforcement actions by fiscal year 2023 with $55.5 million in penalties, though these typically result in injunctions and fines rather than broad vehicle recalls.[3] Notable examples include a December 2024 settlement with a Nashville auto parts seller for distributing over 6,800 devices since 2018 that bypassed emissions systems, and a January 2025 agreement with White's Diesel Performance in Florida for installing at least 748 such devices, both requiring cessation of sales and compliance measures without mandating consumer vehicle recalls.[76][125] These actions target tuning modules and delete kits that disable selective catalytic reduction systems, often marketed for performance gains but undermining certified emissions compliance.[49]