Nick Roberti Joins Toronto Air Taxi Startup NectAir

U.S. EXIM Bank Provides $15 Million Loan to Embraer’s Air Taxi Unit Financing to Support U.S. Supply Chain and Development The U.S. Export-Import Bank (EXIM), in partnership with the Private Export Funding Corporation (PEFCO), has extended a $15 million loan to Eve Air Mobility, the electric vertical takeoff and landing (eVTOL) air taxi subsidiary of Brazilian aerospace giant Embraer. This financing is intended to strengthen Eve’s U.S.-based supply chain by reimbursing the company for electric batteries and engineering services already procured from BAE Systems Inc., a critical American supplier responsible for the energy storage system in Eve’s forthcoming air taxi. Eve, which operates from both Brazil and Melbourne, Florida, clarified that the loan is a one-time reimbursement exclusively tied to U.S. activities and not linked to any future funding installments. Steve Brecken, a spokesperson for Eve, emphasized that the EXIM Bank and PEFCO financing is directly connected to the procurement of batteries and engineering solutions from BAE Systems, underscoring the strategic importance of this partnership. Strategic Partnerships and Industry Context EXIM Bank, as the official export credit agency of the United States, typically intervenes to support exporters when private sector financing options are limited. This loan comes amid a challenging financial environment for advanced air mobility companies, where competition is intensifying and investor confidence is cautious. While the infusion of capital may enhance Eve’s appeal to investors, broader industry challenges—such as anticipated increases in aviation insurance costs in 2026—could moderate enthusiasm. Eve’s supplier network is extensive and includes notable companies such as Beta Technologies for electric pusher motors, Nidec Corporation for propulsion systems, Thales for sensors and computing, Honeywell for guidance and navigation, Garmin for its G3000 Integrated Flight Deck, Crouzet for pilot controls, Aciturri for wing structures, and Duc Hélice Propellers for rotors. The collaboration with BAE Systems dates back to 2021, when BAE invested $10 million in Eve and began exploring a defense variant of the eVTOL in conjunction with Embraer Defense and Security. In 2022, BAE signed a nonbinding agreement to potentially order up to 150 Eve aircraft. Eve highlighted that incorporating BAE Systems’ batteries into the overall eVTOL sales and export package simplifies procurement for international customers by offering a comprehensive and integrated solution. Progress in Aircraft Development and Future Plans The $15 million loan is expected to mitigate risks associated with Eve’s aircraft development and testing programs. In December, Eve marked a significant milestone with the maiden flight of a full-scale, nonconforming prototype at its São Paulo facility. This remotely piloted hover flight, lasting approximately one minute, yielded valuable data on airframe design, control systems, and propulsion. The prototype also validated the integration of Embraer’s fifth-generation fly-by-wire system, a technology shared with Embraer’s E2 commercial jets and KC-390 military transport aircraft. Looking ahead, Eve plans to construct six conforming prototypes to support a comprehensive flight test campaign. Additional hover flights are scheduled before the aircraft transitions to wingborne forward flight, a critical capability that distinguishes eVTOL aircraft. Pilot training will be conducted through a joint venture between Embraer and CAE, ensuring operational readiness. As Embraer advances its air taxi ambitions, the company is simultaneously focusing on enhancing the A-29 Super Tucano’s counter-unmanned aircraft system capabilities and has issued a robust executive jet delivery forecast. This positions Embraer favorably in a business jet market that experienced significant downturns in 2025. Meanwhile, competitors in the air taxi sector may seek similar financial support or accelerate research and development efforts to keep pace with Eve’s progress.

Autonomous Helicopter Proteus Completes Maiden Flight, Advancing UK Defense Capabilities The United Kingdom has achieved a significant milestone in defense technology with the successful maiden flight of Proteus, the country’s first autonomous full-size helicopter. Developed by Leonardo in Yeovil under a £60 million program commissioned by the Royal Navy, Proteus is designed to unlock the potential of uncrewed aerial systems, marking a pivotal advancement in British military innovation. A Historic Flight and Its Strategic Significance Proteus completed its inaugural flight at Predannack Airfield in Cornwall after extensive ground trials at Leonardo’s Yeovil facility. During this initial mission, the helicopter operated its flying controls independently, without human intervention, executing a short test routine that validated the performance of its systems, sensors, and engines. This autonomous operation underscores the aircraft’s capability to function reliably in complex environments. Luke Pollard, Minister for Defence Readiness and Industry, hailed the event as a proud moment for British innovation, emphasizing the critical role autonomous systems will play in national security. Pollard highlighted that such technologies are essential for protecting maritime domains while minimizing risks to personnel. Commodore Steve Bolton further elaborated on the broader implications, stating that Proteus represents the Royal Navy’s commitment to technological leadership, enhancing operational effectiveness amid increasingly complex maritime threats. Nigel Colman, managing director at Leonardo, expressed satisfaction with the collaboration, noting the company’s unique position as the UK’s sole end-to-end rotary wing manufacturer and the significance of seeing Proteus take flight for the first time. Challenges and Industry Implications While the successful flight marks a technological breakthrough, it also introduces new challenges for the defense sector. Regulatory complexities remain a significant hurdle, with internal divisions within regulatory bodies and fluctuating market valuations posing potential risks to sector stability. The emergence of Proteus is likely to intensify competition, prompting other defense programs such as the U.S. Army’s Future Long-Range Assault Aircraft and the U.S. Air Force’s Collaborative Combat Aircraft initiatives to accelerate their autonomous platform developments. Market responses to these advancements are expected to be mixed, with heightened sensitivity to policy shifts. Changes in tariffs, interest rates, or economic indicators could amplify market volatility, reflecting the broader financial impact of innovation within the defense industry. Proteus’s maiden flight not only demonstrates the UK’s commitment to maintaining technological leadership in defense but also signals evolving strategic priorities and market dynamics within the global defense landscape.

GE Aerospace Restructures Commercial Engine Leadership Amid Executive Transition GE Aerospace has announced a significant reorganization of its commercial engine leadership, appointing Mohamed Ali as President and CEO of an expanded Commercial Engines and Services (CES) division. This restructuring, unveiled on January 15, consolidates the entire lifecycle of the company’s commercial engine business—including engineering, supply chain, manufacturing, and aftermarket services—under Ali’s unified leadership. The move merges the previously separate CES and Technology & Operations (T&O) teams, aiming to streamline operations and enhance alignment between new engine production, service maintenance, product safety, and quality control. Leadership Transition and Strategic Realignment The leadership overhaul coincides with the planned retirement of Russell Stokes, a 29-year veteran of GE, who will remain with the company through July 2026 to facilitate a smooth transition. Stokes has been instrumental in driving operational transformations and played a key role in establishing GE Aerospace as an independent entity. CEO Lawrence Culp acknowledged Stokes’s contributions in laying the company’s operational foundation and described Ali’s extensive experience in both technology and customer-facing roles as an ideal fit for the expanded leadership position. In a related development, GE Aerospace appointed Jason Tonich as Chief Commercial Sales & Customer Officer. Tonich will oversee a consolidated sales team and report directly to CEO Larry Culp. This change is intended to bring customer relations closer to the executive level and better integrate sales efforts with the company’s broader operational strategy. Market Context and Outlook The restructuring occurs amid heightened market interest in GE Aerospace, driven by strong demand for commercial jet engines and aftermarket services. The company’s stock has reached record levels, trading around $317 as of December 23, 2025, supported by increased engine production and a steady influx of new orders. Analysts highlight that any incremental increases in production from Airbus and Boeing could translate into higher engine shipments and additional services revenue, contingent on maintaining supply chain stability. Notably, recent agreements such as GE Aerospace’s contract with Emirates to supply 130 GE9X engines for 65 Boeing 777-9 aircraft have reinforced the company’s market position. Nonetheless, analysts caution that ongoing supply chain challenges and other operational risks remain critical factors to monitor. These leadership changes precede GE Aerospace’s upcoming fiscal report, with fourth-quarter and full-year 2025 earnings scheduled for release on January 22.

Boeing Warned of MD-11 Engine Bearing Risk Years Before Deadly UPS Crash The US National Transportation Safety Board (NTSB) has identified a progressive fatigue failure in a critical engine pylon bearing as the cause of the fatal crash of a UPS-operated McDonnell Douglas MD-11 in November 2025. The catastrophic engine separation occurred during takeoff at Louisville’s Muhammad Ali International Airport, resulting in at least 12 fatalities. This revelation has raised significant concerns regarding the adequacy of inspection protocols, manufacturer guidance, and regulatory oversight in preventing such a disaster. Early Warnings from Boeing Boeing had flagged potential issues with the MD-11’s spherical bearing race—the component securing the engine to the wing—as early as 2011. In a service bulletin issued that year, the manufacturer documented four prior bearing failures across three different aircraft. Although none of these incidents had led to safety events, Boeing recommended enhanced inspections and maintenance focused on lubrication and visual checks. Notably, the bulletin did not call for replacement of the bearing assemblies nor did it classify the component as safety-critical. This guidance, now central to the NTSB’s investigation, stopped short of advocating for more intrusive inspections or a redesign of the bearing. Investigators are scrutinizing whether Boeing’s risk assessment and the resulting inspection regime sufficiently accounted for the bearing’s critical role in the aircraft’s structural integrity. Design Legacy and Unanticipated Failure Mode The MD-11’s engine mount design has been in service for decades and was not previously regarded as a safety-of-flight critical item. While wear and corrosion in pylon bearings are recognized maintenance concerns for aging widebody aircraft, the specific progressive fatigue failure identified by the NTSB had not been considered a direct threat to engine retention. Examination of the wreckage revealed clear evidence of long-term deterioration, including beach marks and crack propagation features, indicating that the bearing had been weakening internally over an extended period before the final failure. This finding has shifted the investigation’s focus from a singular mechanical anomaly to the adequacy of long-term inspection and monitoring practices. Scrutiny of Inspection Regimes The MD-11’s maintenance program primarily relied on visual inspections of the pylon bearing assembly at prescribed intervals, consistent with manufacturer recommendations and regulatory requirements at the time. However, the fatigue cracking originated internally, in areas not visible without disassembly or specialized non-destructive testing techniques. The NTSB is now evaluating whether the inspection methods prescribed by Boeing and accepted by regulators were capable of detecting such internal degradation before it reached a critical stage. The investigation continues to focus on the failed aft mount assembly in the left engine pylon and whether earlier, more rigorous intervention could have averted the tragedy. As the inquiry progresses, its findings are expected to prompt a broader review of inspection standards and risk assessments for aging aircraft components throughout the aviation industry.

The Crucial Role of Aircraft Structures Alongside Engines When considering the factors that determine an aircraft’s reliability, engines and avionics often dominate the conversation. However, a comprehensive examination of aerospace history and manufacturing practices reveals that aircraft safety is deeply rooted in structural engineering and certified production processes. Beyond the visible thrust and navigation systems lies a complex framework of components and assemblies that, while largely unseen by passengers, are essential to the aircraft’s overall integrity and performance. The Importance of Structural Engineering in Aviation Aircraft structures are not merely passive frameworks; they are critical safety systems designed to withstand a variety of stresses and protect occupants under both normal and extreme conditions. Regulatory authorities and engineering experts consistently emphasize that every element—from fuselage sections to floor beams and attachment points—must maintain predictable performance throughout decades of service. This unwavering focus on structural integrity forms the foundation upon which all other aircraft systems depend, a principle that has guided aerospace manufacturing since the inception of commercial flight. Advances and Challenges in Aerospace Manufacturing The evolution of aircraft structures has closely paralleled developments in materials science. Early aircraft utilized wood and fabric, but the mid-20th century saw a transition to aluminum alloys, enabling pressurized cabins and higher operational altitudes. Modern aircraft incorporate a sophisticated blend of aluminum, titanium, and advanced composite materials to achieve optimal strength, weight, and durability. These material innovations are driven primarily by certification standards, fatigue management, and safety considerations rather than passenger comfort. Despite these advancements, the aerospace industry faces significant challenges. Ongoing supply chain disruptions affect the availability of high-grade alloys and composite materials essential for structural components. Trade restrictions, including tariffs and embargoes, further complicate access to critical resources for both airframes and engines. Additionally, a shortage of skilled machinists and inspectors, combined with lengthy qualification processes for even minor manufacturing changes, has led airlines to extend the operational life of older aircraft. This trend increases maintenance demands and places additional strain on structural reliability. Certification as the Cornerstone of Structural Production Certification processes are integral to aerospace manufacturing, shaping design and production from the earliest stages. Manufacturers must rigorously demonstrate that aircraft structures can endure operational loads, resist fatigue, withstand fire and heat, and maintain long-term durability. Companies such as STELIA Aerospace are frequently recognized in technical and procurement documentation for their certified production of aircraft structures and interiors, highlighting the industry’s emphasis on traceability and regulatory compliance over mere visibility. The Critical Role of Fasteners in Structural Integrity The reliability of aircraft structures also depends heavily on the quality and certification of fasteners. Aerospace fasteners—including bolts, rivets, and fittings—are carefully selected to meet specific load requirements and environmental conditions. An individual aircraft may contain millions of these components, each subject to stringent documentation and certification standards. The failure of even a single fastener category can jeopardize the entire structure, underscoring the importance of rigorous material specifications and traceability protocols. Documentation: The Foundation of Aviation Safety Throughout the history of aerospace, meticulous documentation has been as vital as the physical materials themselves. The value of every component is inseparable from its certification records, manufacturing data, and inspection histories, which accompany the aircraft throughout its operational lifespan. In an era marked by supply chain volatility and extended aircraft service lives, the discipline of structural engineering and comprehensive documentation remains the cornerstone of aviation safety.

Dubai to Launch Commercial Air Taxi Services by Year-End Dubai is set to introduce commercial air taxi services before the close of 2026, according to the emirate’s Roads and Transport Authority (RTA). Mattar Al Tayer, RTA Director General and Chairman, announced that electric air taxis developed by U.S.-based Joby Aviation will soon begin carrying passengers, marking a significant step in the city’s transportation evolution. Advancing Urban Mobility with Electric Air Taxis The new air taxis aim to provide a faster alternative to road travel, particularly during peak traffic hours. Journeys that currently take up to 45 minutes by car could be reduced to approximately 10 minutes by air. These fully electric aircraft produce zero operational emissions and are designed for quiet operation in densely populated urban environments. Each vehicle accommodates a pilot and up to four passengers, with a maximum range of 160 kilometers (100 miles) and speeds reaching 320 km/h (200 mph) on a single charge. To facilitate the service, the RTA is developing several dedicated “vertiports.” The first vertiport will be located near Dubai International Airport, with additional sites planned in strategic locations such as Downtown Dubai, Dubai Marina, and Palm Jumeirah. The air taxi service will be integrated into Dubai’s existing public transport network, enabling passengers to book flights through digital platforms. While pricing has not yet been disclosed, officials have indicated that the service will be positioned as a premium transport option. Challenges and Industry Context Despite the ambitious timeline, the rollout faces several challenges. Regulatory approval remains a critical hurdle, as authorities work to ensure the safety and compliance of the new aircraft with aviation standards. Technological readiness is another concern, requiring reliable battery performance, robust infrastructure, and seamless integration with current transport systems. Market acceptance will also be essential, as residents and visitors adjust to this novel mode of urban mobility. Dubai’s initiative comes amid rapid global advancements in electric vertical takeoff and landing (eVTOL) technology. Competitors such as Archer Aviation are making significant progress, forming strategic partnerships and accelerating research and development to establish themselves in this emerging market. The traditional aviation sector has responded with a mixture of skepticism and interest, closely monitoring regulatory developments and consumer demand. As Dubai positions itself at the forefront of urban air mobility, the success of its commercial air taxi program may influence the development and adoption of similar projects worldwide.

Dubai Sets Timeline for Launch of Air and Self-Driving Taxis Dubai has announced that the infrastructure supporting its ambitious air taxi project, developed in collaboration with Skyports and leading aviation partners, will be fully operational by the end of this year. Mattar Al Tayer, Director-General of Dubai’s Roads and Transport Authority, emphasized that the initiative has benefited from extensive consultations with global experts and has been refined through international forums such as the World Governments Summit. With these preparations complete, Dubai is now positioned to commence the commercial deployment of both air and self-driving taxis. Strategic Ambitions and Industry Challenges This announcement represents a significant milestone in Dubai’s broader strategy to establish itself as a global leader in urban mobility innovation. Despite the progress, the rollout faces considerable challenges, including navigating complex regulatory environments and addressing public safety concerns. Additionally, Dubai will enter a competitive landscape dominated by established autonomous vehicle companies such as Tesla and Waymo, both of which continue to advance their self-driving taxi technologies at a rapid pace. Market analysts anticipate that Dubai’s initiative could stimulate increased investor interest in the autonomous vehicle sector, as cities worldwide accelerate efforts to implement next-generation transportation solutions. Countries including China and Kazakhstan are also intensifying their self-driving taxi programs, heightening the global competition for technological leadership in this emerging field. Global Market Outlook and Dubai’s Role The global market for autonomous vehicles is expected to experience significant growth in the coming years, driven by ongoing technological innovation and evolving regulatory frameworks. Industry leaders are focusing on advancing their technologies while ensuring compliance with safety and legal standards to solidify their market positions. Dubai’s entry into this competitive arena underscores its commitment to adopting cutting-edge mobility solutions and highlights the complex challenges and opportunities faced by cities integrating autonomous transport into their urban infrastructure. As Dubai moves toward the commercial launch of its air and self-driving taxis, the city’s progress will be closely monitored by industry stakeholders and policymakers worldwide. The unfolding regulatory, safety, and competitive dynamics in this rapidly evolving sector will provide critical insights into the future of urban mobility.

France Commits to Airbus VSR700 Uncrewed Aerial Vehicles for Naval Modernization Contract Award and Strategic Significance On 14 January 2026, the French Armament General Directorate (DGA) officially awarded a contract to Airbus Helicopters and Naval Group for the production of six VSR700 uncrewed aerial systems. These drones are slated for deployment by the French Navy beginning in 2028, representing a pivotal advancement in France’s naval modernization efforts through the integration of cutting-edge unmanned technologies. Bruno Even, CEO of Airbus Helicopters, expressed the company’s commitment to delivering a reliable and high-performance platform that will enhance the French Navy’s operational sovereignty and mission effectiveness. He highlighted the establishment of a dedicated industrial framework designed to support serial production while upholding stringent aeronautical safety and performance standards. Capabilities and Integration The VSR700 will be configured primarily for Intelligence, Surveillance, and Reconnaissance (ISR) missions. It will be equipped with a suite of advanced sensors, including a surveillance radar, an electro-optical system, and an Automatic Identification System (AIS) receiver. Naval Group will manage the integration of the VSR700 into the naval vessels’ architecture, ensuring seamless connectivity with existing combat systems through the Steeris® Mission System. Derived from the crewed Cabri G2 helicopter developed by Hélicoptères Guimbal, the VSR700 serves as a dual-use platform. Its naval military variant was developed under the French Navy and DGA’s SDAM (Système de drone aérien de la Marine) programme in collaboration with Naval Group. The system has undergone rigorous testing both on land and at sea, designed to augment crewed helicopters by extending a vessel’s intelligence-gathering and surveillance reach. While initially focused on ISR roles, the VSR700’s versatility allows it to support logistics, armed reconnaissance, and even civil applications such as firefighting and disaster relief. Challenges and Market Implications The integration of the VSR700 into existing French naval systems may encounter technical challenges, potentially affecting delivery timelines as the new technology is assimilated into operational fleets. This development is anticipated to have broader implications for the defense sector, stimulating increased interest in uncrewed aerial vehicles for surveillance and reconnaissance missions. Competitors, including Leonardo Helicopters—which has developed autonomous rotorcraft for the UK Royal Navy—may accelerate their own UAV programs in response. As global defense priorities shift towards unmanned systems, the market is expected to witness intensified innovation and competition in this domain. Airbus has also showcased the VSR700’s capability to operate collaboratively with crewed helicopters through its HTeaming solution, further enhancing operational flexibility for the French Navy.

China’s Domestic 1,200 kW Turboprop Engine Passes Ignition Test A domestically developed 1,200-kilowatt-class turboprop engine has successfully completed its ignition test in Harbin, Heilongjiang Province, marking a significant milestone for China’s aviation industry. This achievement highlights China’s ongoing efforts to achieve self-reliance in critical aerospace technologies and reflects its expanding ambitions to compete with established global manufacturers. Technical Advancements and Capabilities The engine, designated ATP120A, was developed by Harbin Dongan Civil Aviation Engine Co., a subsidiary of the Aero Engine Corporation of China (AECC). During the recent ignition test, the ATP120A demonstrated stable ground operation at temperatures as low as -30 degrees Celsius (-22 degrees Fahrenheit). Engineered for low fuel consumption, extended service life, and reduced operational costs, the ATP120A has now entered the testing and verification phase. According to AECC, the engine is designed with strong environmental adaptability, capable of functioning in extreme conditions ranging from high-altitude cold regions to hot, humid environments with high salt exposure. Its potential applications include general aviation and unmanned aerial vehicles, with future prospects for integration into hydrogen and hybrid propulsion systems. Implications for the Global Aviation Market This breakthrough is poised to have significant implications for the global turboprop engine market. By offering a cost-effective and reliable alternative, China’s new engine could challenge established manufacturers such as Pratt & Whitney and Rolls-Royce. Industry analysts anticipate that these competitors may respond with enhanced features or revised pricing strategies to maintain their market positions. The success of the ATP120A also bolsters China’s prospects for exporting advanced turboprop aircraft, potentially increasing its share in the international aviation market. China’s pursuit of indigenous aviation technology forms part of a broader strategy to reduce dependence on foreign suppliers. Despite notable progress in both defense and commercial aviation, many Chinese aircraft, including the Comac C919, still rely on foreign-made engines such as the LEAP1-C from CFM International, a joint venture between GE Aerospace and Safran. The development of homegrown engines is regarded as a critical step toward achieving full technological sovereignty. Broader Context of China’s Aviation Ambitions The establishment of the Commercial Aircraft Corporation of China (Comac) in 2008 laid the foundation for these ambitions. Since then, China has introduced several aircraft models, including the ARJ21 regional jet and the C919 narrow-body airliner, both designed to compete with Western manufacturers. The C919, which began regular flights in May 2023, is seen as a direct competitor to Airbus and Boeing, particularly as plans for a lengthened version advance. China’s rapid progress in aviation is supported by substantial investments in research and development across multiple high-tech sectors. From materials science to quantum computing, Chinese innovation is increasingly recognized on the global stage. The successful ignition test of the ATP120A not only underscores China’s growing technological capabilities but also signals its intent to become a leading force in the global aviation industry.

Mercuria and Airborne Capital Launch Open-Ended Aircraft Fund Mercuria Investment Co. (MIC), a subsidiary of Mercuria Holdings (MHD), in partnership with Ireland-based Airborne Capital Limited (ACL), has announced the launch of MACH OE, an open-ended aircraft fund. This initiative represents a strategic departure from their previous closed-ended aircraft funds, which were primarily designed for Japanese investors. According to Mercuria Holdings, MACH OE will be the first open-ended aircraft fund in this sector managed by a Japan-based asset manager. Fund Structure and Investment Strategy MACH OE is structured to provide stable returns by investing in widely used aircraft types leased to a select group of high-quality airlines. The open-ended nature of the fund offers investors enhanced flexibility, allowing them to determine their timing for entry and exit. The fund aims to manage assets totaling approximately JPY 150 billion or more. The Development Bank of Japan is expected to participate as an anchor investor, with additional support anticipated from institutional investors including financial institutions, pension funds, corporations, and educational institutions. Daiwa JPI Alternative Investments Co. (DKAI), a subsidiary of Daiwa Securities Group Inc., will assist the fund by facilitating investor introductions and providing operational services. Furthermore, DKAI has entered into a memorandum of understanding with MIC and ACL, establishing a strategic business alliance to bolster the fund’s development. Market Context and Competitive Landscape The launch of MACH OE occurs amid a competitive and potentially saturated business aviation sector. Other financiers, such as JetLoan Capital, are actively expanding their market presence, intensifying competition for both assets and investors. Market responses to MACH OE are expected to be mixed; while some investors may view the fund as a timely opportunity to benefit from growing demand for aircraft financing, others may approach with caution due to concerns over oversupply and heightened competition. Competitors are likely to respond with aggressive marketing strategies or by forming new strategic partnerships to protect their market share. The success of MACH OE will hinge on its ability to distinguish itself within a crowded marketplace and to adeptly navigate the evolving regulatory environment governing aviation finance. By introducing an open-ended fund structure and leveraging strategic partnerships, Mercuria and Airborne Capital aim to attract a diverse investor base. The fund’s performance and market reception will be closely monitored as the aviation finance sector continues to develop.