Technology & Innovation
GE Aerospace Tests Battery-Less Hybrid Electric Engine for Narrowbody Jets
GE Aerospace successfully tests a battery-less hybrid-electric engine system for narrowbody aircraft, advancing sustainable aviation technology.

This article is based on an official press release from GE Aerospace.
GE Aerospace Achieves Battery-Less Hybrid Electric Milestone for Narrowbody Engines
On January 26, 2026, GE Aerospace announced a significant advancement in sustainable aviation technology: the successful ground test of a hybrid-electric engine system designed specifically for narrowbody aircraft. Conducted at the company’s Peebles Test Operation in Ohio, the demonstration utilized a modified GE Passport turbofan engine integrated with embedded electric motor/generators.
According to the company’s press release, this system is distinct because it operates without energy storage batteries. Instead of relying on heavy battery packs to drive propulsion, the architecture optimizes engine performance in real-time by generating and transferring electricity directly within the engine core. This achievement marks a critical step in the company’s roadmap toward more efficient single-aisle Commercial-Aircraft.
The testing is part of NASA’s Hybrid Thermally Efficient Core (HyTEC) project and contributes directly to the CFM International RISE (Revolutionary Innovation for Sustainable Engines) program. GE Aerospace reports that the system’s performance exceeded NASA’s technical benchmarks for the project.
Technical Breakdown: A Battery-Less Architecture
The core innovation demonstrated in Ohio centers on the elimination of the “weight penalty” typically associated with hybrid-electric systems. Traditional hybrid concepts often rely on massive battery banks to store energy, which can negate efficiency gains due to the added mass. GE Aerospace’s approach bypasses this by embedding electric components directly into the engine.
Power Extraction and Injection
The system functions through a process of power transfer. Electric motor/generators extract excess power from the engine’s shaft, typically the high-pressure spool, during flight phases where the engine has surplus energy, such as cruise. This energy is not stored but is immediately redirected.
According to technical details released regarding the program, this power can be “injected” back into other components, such as the low-pressure spool, to boost efficiency during high-demand phases like takeoff or climb. This capability allows the turbofan to operate closer to its peak efficiency across a wider range of flight conditions.
Executive Commentary
Arjan Hegeman, Vice President of Future of Flight at GE Aerospace, emphasized the strategic importance of removing energy storage from the equation.
“Our latest milestone successfully demonstrated a narrowbody hybrid electric engine architecture that doesn’t require energy storage to operate. It’s a critical step to making hybrid electric flight a reality for commercial aviation…”
, Arjan Hegeman, VP of Future of Flight, GE Aerospace
Strategic Implications for Aviation
The focus on narrowbody aircraft is deliberate. Single-aisle jets, such as the Boeing 737 or Airbus A320 families, account for the majority of global aviation emissions. By developing a “drop-in” style solution that does not require a radical airframe redesign or heavy battery infrastructure, GE Aerospace aims to accelerate the timeline for hybrid-electric commercial flight.
AirPro News Analysis
We view the elimination of high-voltage battery packs as a major advantage for certification. Battery-heavy architectures face significant scrutiny regarding thermal runaway risks and fire suppression requirements. By keeping the electrical system contained within the engine’s generation and consumption cycle, GE Aerospace likely simplifies the path to FAA and EASA approval.
Furthermore, this technology appears to be a direct answer to the industry’s “weight paradox,” where the fuel saved by electric propulsion is often offset by the weight of the batteries required to power it. If the HyTEC program achieves its goal of a 5-10% reduction in fuel burn and emissions compared to 2020 baselines, it represents a commercially viable bridge to sustainability that does not rely on immature battery energy densities.
Industry Context and Competition
While GE Aerospace is advancing its battery-less concept, other major players are pursuing different hybrid strategies. Industry data indicates a diverse landscape of propulsion development:
- Pratt & Whitney: Currently working on a Hybrid-Electric Flight Demonstrator, targeting regional turboprops. Their approach, tested on a modified Dash 8-100, typically involves battery assistance for specific phases of flight.
- Rolls-Royce: Having pivoted away from small electric propulsion, the company is developing turbogenerator technology intended to power electric motors distributed across an aircraft, rather than the integral hybridization of the main jet engine seen in GE’s design.
GE Aerospace’s successful ground test positions it as a leader in the specific application of hybrid technology for large, narrowbody commercial vessels, distinct from the regional and urban air mobility focuses of some competitors.
Frequently Asked Questions
What is the main benefit of a battery-less hybrid engine?
It eliminates the significant weight of battery packs, allowing the aircraft to gain efficiency benefits from electric power transfer without carrying “dead weight.” It also reduces safety risks associated with high-voltage battery storage.
What aircraft will use this engine?
The technology is being developed for future narrowbody (single-aisle) aircraft, which are the workhorses of global commercial fleets.
Is this a fully electric engine?
No. It is a hybrid-electric turbofan. It still burns jet fuel (or Sustainable Aviation Fuel) but uses internal electric motors to optimize the engine’s efficiency and reduce overall fuel consumption.
Sources
Photo Credit: GE Aerospace
Technology & Innovation
Joby Aviation and Toyota Form eVTOL Manufacturing Joint Venture
Joby Aviation and Toyota establish a joint venture to manufacture the S4 eVTOL, with Toyota holding a 51% stake.

Joby Aviation, Inc. (JOBY) and Toyota Motor Corporation (TM) have formalized their nearly decade-long partnership by establishing a joint venture to manufacture electric vertical take-off and landing (eVTOL) aircraft. The new entity, named the Joby Toyota Aero Manufacturing Preparation Company, will focus on scaling commercial production of the Joby S4 Series eVTOL aircraft.
Announced in a press release on June 30, 2026, following a U.S. Securities and Exchange Commission (SEC) 8-K filing on June 29, 2026, the alliance combines Joby’s electric aviation technology with Toyota’s established production systems expertise. The joint venture will operate across locations in Santa Cruz, California, and Toyota City, Japan.
Joint venture structure and financial stakes
Toyota holds a 51 percent majority stake in the new manufacturing company, acquired through the purchase of 1.02 million shares for $1.02 million. Joby retains the remaining 49 percent stake, having purchased 980,000 shares for $980,000. The joint venture will be governed by a five-member board of directors, with three members designated by Toyota and two designated by Joby.
The agreement includes specific intellectual property licensing arrangements between the two parent companies. Joby will license certain aircraft-related intellectual property to the joint venture on a royalty-free basis. In return, Toyota will license manufacturing-related intellectual property to the venture, which includes certain royalty-bearing rights.
Scaling eVTOL production
The formal joint venture builds upon a foundation of significant financial and technical support from the Japanese automaker. Toyota has provided approximately $900 million in total capital to Joby to date. The automaker is already providing technical assistance as Joby establishes a series production line for the S4 eVTOL aircraft at a facility in Ohio.
In the June 30 press release, Joby Aviation founder and CEO JoeBen Bevirt highlighted the depth of the corporate relationship.
“Toyota has been by Joby’s side for nearly a decade, providing invaluable guidance and support as we built the foundation for Manufacturing our aircraft. Today’s announcement reflects the strength of our relationship and our shared confidence in the opportunity ahead.”
Toyota Motor Corporation Chairman Akio Toyoda stated that the company views air mobility as a natural extension of its philosophy of providing mobility for all, expanding its focus from the ground into the sky to bring new value to society.
Certification progress and next steps
The manufacturing alliance aligns with Joby’s ongoing Certification efforts with the U.S. Federal Aviation Administration (FAA). During the first quarter of 2026, Joby began flying its first FAA-conforming aircraft for type inspection authorization. This testing phase is a required step as the company works toward achieving full FAA type certification for the S4 Series.
With the joint venture now legally established, the two companies will begin integrating their engineering and manufacturing teams across the California and Japan facilities to prepare for high-volume aircraft production.
AirPro News analysis
We view the formalization of the Joby Toyota Aero Manufacturing Preparation Company as a critical de-risking event for Joby’s production ambitions. While designing and certifying an eVTOL aircraft presents significant regulatory hurdles, manufacturing these vehicles at scale with automotive-style efficiency is an entirely different challenge that has historically troubled aerospace Startups. By securing a majority-stake commitment from Toyota, Joby gains direct access to one of the world’s most proven manufacturing systems. Furthermore, the intellectual property arrangement, where Toyota retains royalty-bearing rights on its manufacturing processes, suggests the automaker sees long-term revenue potential in aerospace production beyond its initial capital Investments.
Photo Credit: Joby Aviation
Sustainable Aviation
KBR Selected for Asia’s First Ethanol-to-Jet SAF Plant in Singapore
KBR will provide PureSAF technology licensing and FEED services for a 100,000-ton/year SAF facility on Jurong Island, Singapore.

On June 29, 2026, KBR announced its selection by Keppel Ltd. and Aster Chemicals and Energy to provide technology licensing and Front-End Engineering Design (FEED) services for a proposed 100,000-ton-per-year SAF (SAF) facility on Jurong Island, Singapore.
The planned facility is envisioned as Asia’s first commercial-scale ethanol-to-jet (EtJ) SAF plant. According to the KBR press release, the project will utilize the company’s PureSAF technology to produce a 100% drop-in jet fuel, supporting Singapore’s national mandate to increase sustainability usage across the aviation sector.
PureSAF technology and project scope
The Jurong Island facility will leverage PureSAF, a technology originally developed by Swedish Biofuels AB and engineered for commercial-scale production by KBR, which holds the exclusive global license. The process is designed to convert ethanol into aviation fuel that requires no blending with conventional Jet A or Jet A-1 before use.
In a statement accompanying the announcement, KBR President and CEO Stuart Bradie highlighted the system’s flexibility.
“KBR’s PureSAF is a feedstock-flexible, bankable technology that is designed to deliver a 100% drop in jet fuel, ready to power aircraft without blending. We are constantly innovating our SAF solution to make it compatible with feedstock availability in different regions and to enable the aviation industry to transition to low-carbon jet fuel with a cost-optimized approach.”
The FEED study will determine the technical configuration and project capital expenditure required for the facility. The development remains subject to regulatory approvals and a final investment decision (FID) by the project partners.
Aligning with Singapore’s aviation mandates
The selection of KBR follows a January 28, 2026, agreement between Keppel’s Infrastructure Division and Aster to jointly assess the development of the Jurong Island site. Aster operates as a joint venture between Indonesian petrochemical company Chandra Asri and Swiss commodities trader Glencore.
The proposed 100,000-ton annual production capacity aligns directly with targets set by the Civil Aviation Authority of Singapore (CAAS). Starting in 2026, the CAAS mandates a 1% SAF uplift for all departing flights from the country, with a stated goal of increasing that requirement to between 3% and 5% by 2030.
Alongside the SAF plant contract, KBR and Keppel signed a Memorandum of Intent to collaborate on broader energy transition initiatives. The companies plan to explore technologies related to waste-to-energy, plastic recycling, biofuels, and artificial intelligence-driven digitalization.
AirPro News analysis
We view the progression of the Jurong Island project to the FEED stage as a critical indicator of the Asia-Pacific region’s readiness to scale SAF production. While North America and Europe have led early SAF capacity investments, Singapore’s firm regulatory mandate provides the demand certainty required to underwrite commercial-scale facilities in Southeast Asia. The choice of an ethanol-to-jet pathway is particularly notable, as it allows operators to bypass the constrained supply of fats, oils, and greases that limit hydroprocessed esters and fatty acids (HEFA) production volumes. The project’s ultimate realization hinges on the upcoming final investment decision, which will test the commercial viability of the EtJ process in the current economic environment.
Sources: KBR
Photo Credit: KBR
Technology & Innovation
Mako Aerospace Indicates $28M Series A for Electric Jet Engine
Scottish startup Mako Aerospace indicates a $28M Series A to advance its superconductor-based all-electric jet engine prototype.

Mako Aerospace, a Scottish aerospace startups developing all-electric jet engine technology, has indicated the closure of a $28 million Series A funding round to advance its propulsion systems.
A URL published on the company’s domain outlines the capital injection for the Dunfermline-based manufacturers. Mako Aerospace is currently developing “The Forerunner,” an all-electric jet engine prototype utilizing superconductor technology designed to extend the range of electric aircraft.
Advancing all-electric propulsion
Led by Chief Executive Officer Kieran Duncan and Chief Operations Officer Pia Saelen, Mako Aerospace is focused on reducing operating expenses for aircraft operators. The company targets a 70% reduction in fuel costs compared to traditional turboprop engines using its proprietary technology.
In September 2022, Mako Aerospace announced a partnerships with the National Manufacturing Institute Scotland (NMIS) to manufacture the prototype of its electric jet engine. The reported $28 million Series A would provide the capital required to scale this development and pursue experimental certification for the propulsion system.
Funding verification and industry context
The $28 million funding figure originates from a dedicated URL on the Mako Aerospace website. The primary press release is not currently accessible through public web searches, and the funding round has not yet been confirmed by regulatory filings or secondary financial press.
If completed, a $28 million Series A represents a substantial investments in the electric aviation sector. Startups developing novel propulsion systems require significant early-stage capital to transition from conceptual design to physical prototyping and testing.
AirPro News analysis
We note that while the $28 million figure is substantial for a regional aerospace startup at this stage, the lack of accessible public filings or widespread syndication of the press release warrants caution. Developing an all-electric jet engine using superconductors is a highly capital-intensive process. If the funding is fully realized, it will likely bridge the gap between the NMIS-supported prototype phase and initial ground testing. Certification by aviation authorities remains a distant and expensive hurdle for any novel propulsion technology.
Sources: Mako Aerospace
Photo Credit: Mako
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