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Boeing MQ-25 Stingray
Boeing MQ-25 Stingray
Boeing MQ-25 Stingray
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MQ-25 Stingray
MQ-25 Stingray during testing
Role Unmanned combat aerial vehicle for aerial refueling
National origin United States
Manufacturer Boeing
First flight 19 September 2019
Status In development
Primary user United States Navy

The Boeing MQ-25 Stingray is an aerial refueling drone that resulted from the Carrier-Based Aerial-Refueling System (CBARS) program, which grew out of the earlier Unmanned Carrier-Launched Airborne Surveillance and Strike (UCLASS) program. The MQ-25 first flew on 19 September 2019.

Development

[edit]

Background

[edit]
Main article: Unmanned Carrier-Launched Airborne Surveillance and Strike

The United States Navy began its efforts to develop an aircraft carrier-based UAV in 2006. The original UCLASS concept was for a stealthy strike platform capable of penetrating enemy air defenses. In 2012, lethality and strike requirements were diluted in order to create an intelligence, surveillance and reconnaissance (ISR)-oriented aircraft that could be developed quickly to conduct low-intensity counter-terrorism missions.[1]

On 1 February 2016, after delays over whether the UCLASS would specialize in strike or ISR roles, it was reported that significant priority would be given to producing a Super Hornet-sized carrier-based aerial refueling tanker as the Carrier-Based Aerial-Refueling System (CBARS), with "a little ISR" and some capabilities for communications relay, and strike capabilities put off to a future variant.[2] The Pentagon apparently made this program change to address the Navy's expected fighter shortfall by directing funds to buy more F/A-18E/F Super Hornets and accelerate purchases of the F-35C. Having the CBARS as the first carrier-based UAV provides a less complex bridge to the future F/A-XX, should it be an unmanned strike platform. It also addresses the carriers' need for an organic refueling aircraft, proposed for the UCLASS since 2014, freeing up the 20–30 percent of Super Hornets performing the mission in a more capable and cost effective manner than modifying the F-35, V-22 Osprey, and E-2D Hawkeye, or returning the retired S-3 Viking to service.[2][3][4]

Four development contracts were issued in 2016, with a formal RFP expected in 2017, with operational status in the early to mid-2020s.[5][6] In July 2016, it was officially named "MQ-25A Stingray" after being named RAQ-25A previously.[7]

Rear Adm. Michael Manazir has suggested that three of these UCAVs could fly with an F-35 for refueling and sensor operation.[8] Vice Adm. Mike Shoemaker said that the MQ-25 can extend the Super Hornet's 450 nmi (520 mi; 830 km) unrefueled combat radius to beyond 700 nmi (810 mi; 1,300 km). The Navy's goal for the aircraft is to be able to deliver 15,000 lb (6,800 kg) of fuel total to 4 to 6 airplanes at a range of 500 nmi (580 mi; 930 km).[9] The Navy released the final MQ-25 Stingray request for proposals in October 2017 to Lockheed Martin, Boeing, Northrop Grumman, and General Atomics.[10]

Selection

[edit]

Boeing secretly finished building its wing-body-tail in 2014 when the UCLASS program was paused, and revived it for the CBARS mission.[11] On 19 December 2017, Boeing unveiled its prototype aircraft entrant that incorporated lessons learned from the Boeing Phantom Ray flying wing and its other unmanned aerial systems.[12] Boeing's MQ-25 design is not new for the tanking mission, but Boeing says that was considered when designing it.[11]

General Atomics proposed their Sea Avenger concept which was enlarged from its Predator-C/Avenger for refueling,[13] while Lockheed Martin proposed their Sea Ghost concept based on the RQ-170 Sentinel.[14]

Northrop Grumman announced on 25 October 2017 that it was withdrawing its X-47B from the MQ-25 competition, saying the company would have been unable to execute the program under the terms of the service's request for proposals.[15] The company's departure signaled to some analysts that the Navy's requirements could favor wing-body-tail designs, not the flying wings thought to be proposed by Northrop Grumman and Lockheed Martin.[12]

MQ-25 deck handling demonstration, 2018

On 30 August 2018, the U.S. Navy announced Boeing as the winner of the competition and awarded an $805 million development contract for four MQ-25A aircraft to be completed by August 2024.[1] An additional three test MQ-25As were ordered on 2 April 2020 for a current total order of seven.[16] The program may expand to $13 billion overall and consist of 72 aircraft.[17]

Flight testing

[edit]
MQ-25 T1 Stingray test aircraft refuels F-35C, 2021

In late April 2019, the first MQ-25 test aircraft (T-1 or "Tail 1") was taken by road from Boeing's technical plant at St. Louis's Lambert International Airport across the Mississippi River to MidAmerica St. Louis Airport, which is conjoined to Scott Air Force Base.[18] Following taxi tests, the Federal Aviation Administration certified the aircraft and granted airspace for flight testing. The MQ-25 took its first flight on 19 September 2019.[19]

In December 2020, Boeing released video showing the first flight of the MQ-25 with a Cobham aerial refueling store externally mounted.[20]

MQ-25 T1 Stingray test aircraft takes off, 2021
MQ-25 T1 on aboard USS George H.W. Bush 2021

On 4 June 2021, the first refueling test was conducted, with the MQ-25 providing fuel to an F/A-18F Super Hornet. The MQ-25 originated at MidAmerica Airport in Mascoutah, Illinois, with support by Air Test and Evaluation Squadron VX-23. The mission lasted about 4.5 hours with the two aircraft performing numerous dry or wet connects for more than 10 minutes and 325 pounds of fuel transferred in total.[21] Further refueling tests were performed with E-2 and F-35C.[22]

Design

[edit]

Boeing's MQ-25 design is powered by one Rolls-Royce AE 3007N turbofan engine delivering 10,000 lbf (44 kN) of thrust; this is a variant of the engine used to power the Navy's MQ-4C Triton.[23][24] Although the aircraft is less stealthy than flying wing UAVs, it does feature a stealthy fuselage shaping, flush inlet to shield engine blades from radar, and a V-tail.

Images of an MQ-25 model released in April 2024 showed AGM-158C LRASM anti-ship missiles on the underwing hardpoints. The model also showed an electro-optical sensor ball under the nose in front of the forward landing gear.[25]

Operational history

[edit]

In 2020, the U.S. Navy planned to establish Unmanned Carrier Launched Multi-Role Squadron 10 (VUQ-10) in October 2021 with four aircraft at Naval Base Ventura County, which includes Naval Air Station Point Mugu.[26][27][28] The Navy established VUQ-10 at Naval Air Station Patuxent River, Maryland, as the Fleet Replacement Squadron (FRS) for the MQ-25 on 1 October 2022. The unit is working on testing and development of maintenance and operations procedures for the MQ-25. The unit is to eventually move to Naval Air Station Point Mugu at Naval Base Ventura County.[29]

Operators

[edit]

United States United States

  • United States Navy- 76 aircraft planned, the first Fleet Replacement Squadron, VUQ-10, stood up at Naval Air Station Patuxent River on 1 October 2021. Two operational units, VUQ-11 and VUQ-12 are planned to stand up on later dates.[30]
    • Pacific Fleet Squadrons
      • VUQ-10 (Fleet Replacement Squadron)
    • Planned Squadrons
      • VUQ-11
      • VUQ-12

Specifications (MQ-25A)

[edit]

Data from NAVAIR[31] and USN MQ-25A Basing Draft Environmental Assessment[32]

General characteristics

  • Length: 51.0 ft (15.5 m)
  • Wingspan: 75.0 ft (22.9 m) wings extended, 31.3 ft (9.54 m) folded
  • Height: 9.8 ft (3.0 m) wings extended, 15.7 ft (4.79 m) folded
  • Powerplant: 1 × Rolls-Royce AE 3007N[33] turbofan, >10,000 lbf (>44 kN) thrust

Performance

  • Range: 500 nmi (580 mi, 930 km) when delivering ≥16,000 lb (7,250 kg) of fuel[34]

Armament

See also

[edit]

Aircraft of comparable role, configuration, and era

Related lists

References

[edit]
[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Boeing MQ-25 Stingray

View on Grokipedia
from Grokipedia
The Boeing MQ-25 Stingray is an unmanned aerial vehicle developed by Boeing for the United States Navy, serving as the first operational carrier-based unmanned aircraft designed primarily for aerial refueling to extend the range and endurance of carrier air wing assets. Selected by the Navy on August 30, 2018, under a fixed-price contract worth $805 million for the engineering and manufacturing development phase, the MQ-25 program originated from the Unmanned Carrier-Launched Airborne Surveillance and Strike (UCLASS) initiative but evolved to prioritize refueling capabilities while retaining potential for intelligence, surveillance, and reconnaissance (ISR) missions. The aircraft features a V-tail design with a 51-foot length, a wingspan of approximately 75 feet when extended, and is powered by a single Rolls-Royce AE 3007N turbofan engine producing over 10,000 pounds of thrust, enabling it to deliver at least 15,000 pounds of fuel at ranges up to 500 nautical miles from the carrier. Key development milestones include the first flight of the MQ-25 T1 test asset on September 19, 2019, from Boeing's facility in St. Louis, Missouri, followed by the historic first unmanned-to-manned aerial refueling demonstration on June 7, 2021, when it successfully transferred fuel to an F/A-18F Super Hornet. Subsequent tests in 2021 validated refueling with the F-35C Lightning II in September and the E-2D Advanced Hawkeye in August, showcasing compatibility with diverse carrier-based aircraft. As of August 2025, the program has faced delays, with ground testing of a static test aircraft underway since July 2025 and the first flight of an engineering and manufacturing development aircraft planned for later in 2025, followed by carrier integration in 2026. Congress appropriated $524.6 million for FY2025 (partially funding the $898 million request), with low-rate initial production procurement of the first three aircraft beginning in FY2026 using $1.04 billion in requested funding. Initial operational capability is now targeted for the end of FY2027, with the program aiming for 76 total aircraft (67 operational across four squadrons) to relieve manned tankers like the F/A-18 and enhance the Navy's carrier strike group flexibility.

Development

Background

The U.S. Navy has traditionally relied on "buddy tanking" with F/A-18E/F Super Hornets for carrier-based aerial refueling, a method that diverts fighter aircraft from strike roles, reduces overall combat air wing effectiveness, and burdens pilots with additional workload. This approach limits the range and sortie generation of carrier strike groups, particularly in high-threat environments. To address these shortcomings, the Navy initiated the MQ-25 program to transition to unmanned aerial refueling systems, enabling extended operational ranges for manned aircraft while preserving pilot resources for combat missions. The MQ-25 Stingray originated from the Carrier-Based Aerial Refueling System (CBARS) program, launched in 2014 as a restructuring of the earlier Unmanned Carrier-Launched Airborne Surveillance and Strike (UCLASS) effort, which had faced scope and cost challenges. CBARS was driven by strategic imperatives in the Pacific theater, where China's advancing anti-access/area-denial (A2/AD) capabilities— including long-range missiles and integrated air defenses—threaten to constrain U.S. carrier operations and compress the strike range of naval aviation. By offloading refueling duties to unmanned platforms, the program seeks to enhance the Navy's ability to project power against such peer competitors. Core requirements for the MQ-25 emphasize operational robustness, including the capacity to offload at least 15,000 pounds of fuel at a radius of 500 nautical miles from the carrier while returning safely. The system must integrate seamlessly with existing carrier launch and recovery equipment, such as catapults and arrestor wires, to operate from nuclear-powered aircraft carriers. Additionally, it incorporates multi-role potential for intelligence, surveillance, and reconnaissance (ISR) missions to maximize utility beyond refueling. Early concept development involved studies and demonstrations by major contractors in 2016, as the Navy refined requirements during preliminary design reviews. Boeing showcased a full-scale prototype derived from its prior UCLASS work, emphasizing carrier deck handling and autonomy. Northrop Grumman, Lockheed Martin, and General Atomics presented designs focused on fuel efficiency, ISR integration, and unmanned operations, informing the program's shift toward a "sweet spot" balancing tanker primacy with future growth potential.

Selection

The U.S. Navy's Carrier-Based Aerial-Refueling System (CBARS) program advanced through a competitive demonstration phase in 2016, where four companies—Boeing, General Atomics Aeronautical Systems, Lockheed Martin, and Northrop Grumman—received contracts totaling approximately $164 million to develop and test carrier-compatible unmanned aerial system concepts for aerial refueling. These efforts focused on demonstrating key technologies for unmanned operations from aircraft carriers, building on prior requirements for carrier-based unmanned aviation. Proposals were evaluated against Navy criteria emphasizing refueling capacity to extend carrier air wing range, operational autonomy for unmanned missions, seamless integration with carrier deck operations, and overall program cost-effectiveness. Boeing's submission stood out by leveraging mature technologies from prior demonstrators, such as the Phantom Ray, to minimize development risks while meeting performance thresholds. On August 30, 2018, the Navy awarded Boeing an $805.3 million fixed-price-incentive-firm contract for the Engineering and Manufacturing Development phase, selecting the company to design, build, test, and deliver four full-scale MQ-25A Stingray aircraft. The selection highlighted Boeing's design advantages, including the ability to offload up to 15,000 pounds of fuel at 500 nautical miles from the carrier—effectively doubling strike range for manned aircraft—and its low-risk approach using proven commercial and military aviation components for rapid integration. Following the award, the Navy issued subsequent contract modifications to support early development, including a 2019 agreement valued at approximately $54 million to modify the Boeing-owned Stingray prototype (T1 test asset) for additional ground and flight testing aligned with EMD requirements.

Flight testing

The Boeing MQ-25 Stingray prototype, designated T1, completed its maiden flight on September 19, 2019, at MidAmerica St. Louis Airport near Boeing's facilities in St. Louis, Missouri. The unmanned test asset, controlled by Boeing pilots from the ground, executed a pre-programmed autonomous route lasting approximately two hours, validating basic flight characteristics, stability, and systems integration without incident. In 2021, the program advanced to carrier compatibility demonstrations, with the T1 conducting deck-handling trials aboard the USS George H.W. Bush (CVN-77) in December, simulating operations in the carrier environment at sea. These tests confirmed the aircraft's integration with carrier deck procedures, including evaluations of electromagnetic aircraft launch system (EMALS) compatibility and arrested recovery simulations to ensure seamless interaction with catapult launches and wire arrests. Concurrently, on June 4, the T1 achieved a historic milestone by performing the first unmanned-to-manned aerial refueling, transferring fuel via probe-and-drogue to an F/A-18F Super Hornet over MidAmerica Airport, demonstrating stable formation flying and refueling store functionality. Later that year, additional refueling tests extended to the E-2D Advanced Hawkeye in August and the F-35C Lightning II in September, further proving the Stingray's versatility across carrier air wing assets. From 2022 to 2024, testing emphasized autonomous operations and multi-mission capabilities, with the T1 accumulating over 125 flight hours to refine software algorithms for independent mission execution. In September 2022, Boeing demonstrated an open autonomy architecture allowing the MQ-25 to receive tasking from manned platforms like the P-8A Poseidon and E-2D for intelligence, surveillance, and reconnaissance (ISR) missions, including simulated pod integration for sensor data collection without direct ground control intervention. Refueling demonstrations expanded to multiple sequential operations, with the T1 successfully transferring fuel to combinations of carrier-based aircraft in probe-and-drogue configurations, validating endurance and reliability in contested scenarios. These efforts addressed key challenges in software autonomy, where iterative refinements improved decision-making algorithms to handle dynamic flight paths and reduce pilot workload during complex carrier-integrated missions. Electromagnetic interference mitigation was a focal point during carrier trials, with early design modifications strengthening the airframe's shielding to ensure compatibility with EMALS and other shipboard systems, preventing disruptions to autonomous controls and communications. By 2024, these advancements enabled simulated autonomous landings using the F-35's Joint Precision Approach and Landing System, paving the way for full deck-cycle operations. In 2025, ground testing of the first production-representative MQ-25 aircraft commenced in July at Boeing's MidAmerica Airport facility near St. Louis, Missouri, focusing on initial carrier compatibility validations including taxi, weight-and-balance, and systems integration ahead of flight. The initial flight of the production-representative airframe is scheduled for late 2025, marking the transition from prototype validation to operational certification.

Production and procurement

The U.S. Navy awarded Boeing an initial low-rate initial production (LRIP) contract in September 2022 valued at $47 million to prepare for building and delivering the first MQ-25 Stingray aircraft, following engineering and manufacturing development efforts. This contract supported additional test units, with full-rate production decisions anticipated after Milestone C approval, now projected for 2026 pending successful testing outcomes. The MQ-25 program has experienced significant delays, shifting initial operational capability (IOC) from 2024 to 2027 due to challenges in software integration, supply chain disruptions, and required air vehicle redesigns. A 2023 Department of Defense Inspector General audit highlighted risks associated with advancing to production without sufficient testing and evaluation, potentially affecting program reliability and costs. These issues also postponed the LRIP start from September 2023 to June 2025 and the first carrier flight from June 2025 to March 2026. For fiscal year 2025, the Navy requested $898 million, including $553 million in procurement for three LRIP aircraft, $215 million for research, development, test, and evaluation (RDT&E), and $130 million for unmanned mission control system (UMCS) development. The fiscal year 2026 budget proposal seeks $1.04 billion to procure three additional aircraft, marking the first operational buys and initiating broader fleet expansion. The Navy plans to acquire a total of 76 MQ-25 aircraft, comprising 67 operational units and 9 for testing and development, with the first delivery to the Navy scheduled for 2025 and shipboard integration beginning in 2026. Manufacturing occurs at Boeing's facility in St. Louis, Missouri, with key subcontractors including Rolls-Royce for the AE 3007N turbofan engines and additional partners for avionics systems.

Design

Airframe

The Boeing MQ-25 Stingray employs a V-tail stabilizer configuration in lieu of a traditional vertical tail, enhancing aerodynamic stability while contributing to a reduced radar signature. This design choice, combined with a flush engine inlet, supports the aircraft's low-observability features tailored for carrier-based operations. The airframe measures 51 feet (15.5 meters) in length, with a wingspan of 75 feet (22.9 meters) when extended and 31.3 feet (9.5 meters) when folded for carrier storage. Its height stands at 9.8 feet (3.0 meters) with wings spread, facilitating compact stowage on aircraft carriers. These dimensions enable efficient integration into naval air wings while maintaining operational range. Construction emphasizes composite materials for the skins, providing lightweight strength, resilience, and tailored performance to minimize weight and enhance stealth properties. Internal structure incorporates dedicated fuel tanks to maximize refueling capacity, alongside provisions for ISR payloads in mission-configurable bays. Carrier-specific adaptations include folding wings to optimize deck space and reinforced landing gear capable of withstanding catapult launches and arrested recoveries. These elements ensure reliable performance in the demanding maritime environment of aircraft carrier operations.

Propulsion

The Boeing MQ-25 Stingray is powered by a single Rolls-Royce AE 3007N high-bypass turbofan engine mounted in the rear fuselage, providing 10,000 lbf (44 kN) of thrust for carrier takeoffs and efficient cruising. This engine, a derivative of the AE 3007 series used in the MQ-4C Triton, emphasizes fuel efficiency during extended loiter periods and transit to refueling zones, enabling the aircraft's primary mission profile without afterburners. The Stingray's internal fuel tanks, integrated into the airframe's wing and fuselage structure, support a mission capability to offload up to 15,000 lb (6,800 kg) of fuel at a range of 500 nautical miles (930 km) from the carrier, with reserves for return flight. This capacity prioritizes operational endurance in contested environments, allowing the unmanned tanker to extend the reach of carrier air wing assets like the F/A-18E/F Super Hornet and F-35C Lightning II. The refueling system employs a podded probe-and-drogue configuration, using a fly-by-wire controlled hose-and-drogue assembly from an aerial refueling store (ARS) mounted under the fuselage. This setup enables automated connections and fuel transfer to Navy receiver aircraft, with demonstrated rates supporting practical mission tempos, such as 220 gallons per minute (approximately 1,500 lb per minute) in early tests. The high-bypass engine's efficiency features, including optimized fan and compressor staging, minimize fuel burn across transit, station-keeping, and recovery phases, enhancing overall mission flexibility.

Avionics and mission systems

The Boeing MQ-25 Stingray's avionics are centered around an advanced autonomy framework that enables seamless integration into carrier-based operations. The core of this system is the Unmanned Carrier Aviation Mission Control System (UMCS), also designated as MD-5, which serves as the ground-based command and control station. This system allows operators to manage the aircraft from aircraft carriers or remote land-based facilities, supporting a spectrum of autonomy levels from direct remote piloting to fully independent mission execution. The UMCS facilitates manned-unmanned teaming, where manned aircraft can task the MQ-25 for missions such as intelligence, surveillance, and reconnaissance (ISR) by specifying parameters like search areas and no-fly zones, leveraging an open architecture for interoperability. Key sensors enhance the MQ-25's situational awareness and navigation capabilities. The aircraft incorporates an electro-optical/infrared (EO/IR) sensor turret for visual and thermal imaging, enabling target detection, navigation, and basic ISR functions even in low-visibility conditions. Complementing these are secure datalinks that provide real-time transmission of video feeds and ISR data to operators or other platforms, supporting collaborative operations in dynamic environments. The mission systems emphasize flexibility beyond the primary aerial refueling role, with a modular payload bay designed for rapid integration of interchangeable pods. This architecture allows the MQ-25 to adapt for ISR missions using enhanced sensor packages or, in future upgrades, electronic attack and strike capabilities through specialized payloads. To ensure operational reliability, the avionics feature redundant architectures in flight controls and communications, providing fault tolerance and resistance to disruptions in contested airspace.

Specifications

General characteristics

The Boeing MQ-25A Stingray is an unmanned aerial vehicle (UAV), operating without an onboard crew and capable of autonomous flight or optional remote control from mission control stations. The aircraft's dimensions are tailored for carrier compatibility, with a length of 51.0 ft (15.5 m), a wingspan of 75.0 ft (22.9 m) when extended for flight and 31.3 ft (9.5 m) when folded for storage, and a height of 9.8 ft (3.0 m); the folding wing mechanism facilitates compact stowage on aircraft carrier decks. It features an empty weight of approximately 14,000 lb (6,400 kg) and a maximum takeoff weight of 44,500 lb (20,200 kg), providing capacity for significant fuel and mission loads while adhering to carrier launch and recovery constraints. The MQ-25A is powered by a single Rolls-Royce AE 3007N turbofan engine, >10,000 lbf (44 kN) thrust, delivering efficient thrust for carrier-based operations. In its primary aerial refueling role, the aircraft can offload up to 15,000 lb (6,800 kg) of fuel to supported aircraft; for secondary missions, it accommodates payloads in modular pods for intelligence, surveillance, reconnaissance (ISR), or electronic warfare. The standard MQ-25A configuration carries no armament, though the design includes provisions for potential future integration of modular weapons systems.
CharacteristicSpecification
CrewUnmanned (optionally remote-controlled)
Length51.0 ft (15.5 m)
Wingspan75.0 ft (22.9 m) extended; 31.3 ft (9.5 m) folded
Height9.8 ft (3.0 m)
Empty weight~14,000 lb (6,400 kg)
Maximum takeoff weight44,500 lb (20,200 kg)
Powerplant1 × Rolls-Royce AE 3007N turbofan, >10,000 lbf (44 kN) thrust
Fuel offload capacityUp to 15,000 lb (6,800 kg)
ISR/EW pod capacityModular payloads
ArmamentNone (provisions for modular weapons)

Performance

The Boeing MQ-25A Stingray operates within an envelope optimized for carrier-based unmanned aerial refueling, enabling it to support extended mission profiles for the U.S. Navy's carrier air wing. The aircraft's range with a full refueling payload extends 500 nautical miles (926 km) from the carrier, during which it can transfer up to 15,000 lb of fuel to compatible platforms including the F/A-18 Super Hornet, F-35C Lightning II, and E-2D Advanced Hawkeye. The performance parameters, enabled in part by its Rolls-Royce AE 3007-based propulsion system, allow the MQ-25A to integrate seamlessly into high-tempo carrier strike group missions, extending the operational reach of manned aircraft without risking pilots in routine tanker roles. It has a service ceiling of 39,000 ft (11,887 m).

Service

Operational history

The Boeing MQ-25 Stingray was planned to enter the initial phase of operational evaluation with the U.S. Navy in 2025, marked by flight tests for the engineering and manufacturing development aircraft at Naval Air Station Patuxent River, but these flight tests have been delayed to early 2026. These tests represent the transition from developmental to operational assessment, with the first production deliveries anticipated in fiscal year 2026 to support further integration. Initial operating capability is targeted for fiscal year 2027, following low-rate initial production and verification of system performance. Early service activities have centered on assignment to Air Test and Evaluation Squadron (VX) 23 at NAS Patuxent River, where the MQ-25 undergoes operational testing to validate refueling operations with carrier air wing assets, including the F-35C Lightning II and F/A-18E/F Super Hornet. Shipboard integration is scheduled to begin in 2026 aboard the USS George H.W. Bush (CVN-77), building on the prior installation of the Unmanned Mission Control System in 2024 to enable carrier-based control of the aircraft. This phase will evaluate the Stingray's performance in a fleet environment, prioritizing autonomous operations to reduce pilot workload during refueling sorties. In service, the MQ-25 is planned to serve primarily as an unmanned aerial tanker, extending the combat range of strike aircraft in contested areas by delivering up to 15,000 pounds of fuel while operating beyond the carrier's defended perimeter. Its modular design also positions it for secondary intelligence, surveillance, and reconnaissance roles during multinational exercises such as Rim of the Pacific (RIMPAC). Challenges persist in achieving full operational autonomy, necessitating continued software maturation and addressing program delays attributed to integration complexities. As of November 2025, no MQ-25 units have achieved combat deployment status. Looking ahead, the MQ-25 is expected to expand into collaborative unmanned teaming with emerging collaborative combat aircraft programs, enhancing networked operations for the carrier strike group.

Operators

The primary operator of the Boeing MQ-25 Stingray is the United States Navy (USN), which is developing and fielding the unmanned aerial refueling system as its first carrier-based unmanned aircraft. Initial operational units are assigned to Air Test and Evaluation Squadron 23 (VX-23) at Naval Air Station Patuxent River, Maryland, for testing and evaluation, including flight demonstrations and integration trials. Following initial operational capability (IOC), expected in 2027, the MQ-25 will transition to dedicated Unmanned Carrier-Launched Multi-Role Squadrons, such as the Fleet Replacement Squadron VUQ-10, also based at NAS Patuxent River, to handle training, maintenance, and deployment operations. The USN's program of record calls for a total of 76 MQ-25 aircraft, comprising 67 operational units and nine for testing and development, to be integrated across the Navy's carrier air wings for enhanced refueling and intelligence, surveillance, and reconnaissance capabilities. These aircraft will support operations from Nimitz-class and Ford-class carriers, enabling forward deployment with carrier strike groups. Operator training for the MQ-25 is conducted using the Unmanned Carrier Aviation Mission Control System (UMCS), a system-of-systems for command and control, with simulators and facilities located at NAS Patuxent River to prepare Navy Air Vehicle Pilots and maintenance personnel. As of November 2025, there are no international operators for the MQ-25 Stingray, with the platform remaining exclusive to the USN due to its integration with sensitive naval unmanned systems.

References

  1. https://www.boeing.com/defense/mq25
  2. https://www.navy.mil/Resources/Fact-Files/Display-FactFiles/Article/2160662/mq-25a-stingray/
  3. https://www.congress.gov/crs-product/IF12972
  4. https://www.navair.navy.mil/product/Unmanned-Carrier-Aviation
  5. https://www.rolls-royce.com/products-and-services/defence/advanced-technology-defence/mq-25.aspx
  6. https://boeing.mediaroom.com/2019-09-19-Boeing-MQ-25-Completes-First-Flight
  7. https://investors.boeing.com/investors/news/press-release-details/2021/Navy-Boeing-Make-Aviation-History-with-MQ-25-Becoming-the-First-Unmanned-Aircraft-to-Refuel-Another-Aircraft/default.aspx
  8. https://www.navy.mil/Press-Office/News-Stories/Article/2773685/mq-25-conducts-first-air-to-air-refueling-with-f-35c/
  9. https://www.navy.mil/Press-Office/Press-Releases/display-pressreleases/Article/2738228/mq-25-achieves-another-first-conducts-air-to-air-refueling-with-e-2d/
  10. https://www.usni.org/magazines/proceedings/2022/september/return-range-how-navy-got-mq-25-right
  11. https://news.usni.org/2016/02/01/pentagon-to-navy-convert-uclass-program-into-unmanned-aerial-tanker-accelerate-f-35-development-buy-more-super-hornets
  12. https://www.aerosociety.com/news/mq-25-the-future-of-carrier-aviation/
  13. https://theaviationist.com/2025/01/29/us-navy-will-fly-mq-25-2025-carriers-2026/
  14. https://news.usni.org/2016/08/18/navy-industry-design-sweet-mq-25a-stingray-missions
  15. https://www.nationaldefensemagazine.org/articles/2016/11/18/navy-puts-procurement-of-carrier-drone-on-fast-track-updated
  16. https://news.usni.org/2016/02/11/unmanned-cbars-tanker-air-segment-draft-rfp-expected-later-this-year
  17. https://news.usni.org/2018/08/30/navy-picks-boeing-build-mq-25a-stingray-carrier-based-drone
  18. https://www.navair.navy.mil/news/navy-awards-boeing-8053-million-contract-design-build-mq-25a-stingray/wed-11142018-2130
  19. https://boeing.mediaroom.com/2019-09-19-Boeing-MQ-25-Unmanned-Aerial-Refueler-Completes-First-Test-Flight
  20. https://news.usni.org/2019/09/20/boring-first-flight-of-mq-25a-prototype-was-the-result-boeing-and-navy-wanted
  21. https://www.navalnews.com/naval-news/2019/09/boeing-mq-25-unmanned-aerial-refueler-completes-first-test-flight/
  22. https://www.navy.mil/Press-Office/News-Stories/Article/2879506/navy-completes-initial-carrier-demo-for-mq-25-program/
  23. https://www.twz.com/43361/navys-mq-25-stingray-tanker-drone-goes-aboard-a-carrier-for-the-first-time
  24. https://www.navy.mil/Press-Office/News-Stories/Article/2647709/fueling-the-future-mq-25-first-to-conduct-unmanned-aerial-tanking/
  25. https://boeing.mediaroom.com/2021-06-07-Navy%2C-Boeing-Make-Aviation-History-with-MQ-25-Becoming-the-First-Unmanned-Aircraft-to-Refuel-Another-Aircraft
  26. https://breakingdefense.com/2022/09/boeing-successfully-demos-mq-25-control-through-p-8-autonomy-software/
  27. https://www.key.aero/article/boeing-advances-manned-unmanned-teaming-mq-25-stingray
  28. https://www.defence21.com/en/license-drive-mq-25-stingray
  29. https://www.flightglobal.com/military-uavs/boeing-and-us-navy-simulate-mq-25-carrier-recovery-using-f-35-automated-landing-system/160592.article
  30. https://www.twz.com/air/mq-25-stingray-carrier-based-uncrewed-tanker-ground-testing-now-underway
  31. https://www.defensedaily.com/boeing-wins-47-million-contract-to-start-first-mq-25-lrip/navy-usmc/
  32. https://www.esd.whs.mil/Portals/54/Documents/FOID/Reading%2520Room/Selected_Acquisition_Reports/FY_2023_SARS/MQ-25%2520MSAR%2520Dec%25202023.pdf
  33. https://www.defenseone.com/technology/2025/07/navys-drone-refueler-delayed-again/407148/
  34. https://news.usni.org/2025/08/12/report-to-congress-on-mq-25-stingray
  35. https://aerospaceamerica.aiaa.org/features/grading-the-mq-25/
  36. https://www.usni.org/magazines/proceedings/2023/july/mq-25-stingray-enabling-marine-corps-conops-indo-pacific
  37. https://nationalsecurityjournal.org/forget-the-f-35-the-mq-25-stingray-might-be-the-navys-best-weapon-against-china/
  38. https://www.boeing.com/features/2023/06/boeing-and-aurora-flight-sciences-partner
  39. https://www.naval-technology.com/projects/mq-25-stingray-unmanned-aerial-refuelling-aircraft/
  40. https://www.globalsecurity.org/military/systems/aircraft/mq-25.htm
  41. https://www.navy.mil/DesktopModules/ArticleCS/Print.aspx?PortalId=1&ModuleId=523&Article=2647709
  42. https://seapowermagazine.org/mq-25-uav-makes-history-with-first-unmanned-aerial-refueling/
  43. https://www.aurora.aero/2022/09/06/boeing-team-demonstrates-open-autonomy-architecture-for-manned-unmanned-teaming-with-mq-25/
  44. https://www.twz.com/30145/u-s-intelligence-agency-eyes-the-navys-mq-25-drone-for-maritime-surveillance-missions
  45. https://www.aviationtoday.com/2022/09/09/boeing-simulates-virtual-mq-25-open-architecture-manned-unmannned-teaming/
  46. https://www.globalsecurity.org/military/systems/aircraft/mq-25-specs.htm
  47. https://news.usni.org/2025/01/29/mq-25a-stingray-2026-debut-will-unlock-unmanned-aviation-for-carrier-strike-group-say-officials
  48. https://www.shephardmedia.com/news/naval-warfare/us-navy-confirms-mq-25-stingray-first-flight-tests-for-this-year/
  49. https://www.aviationtoday.com/2025/12/18/first-mq-25-flight-test-pushed-to-early-2026/
  50. https://www.flightglobal.com/military-uavs/us-navy-to-fly-mq-25-from-aircraft-carrier-in-2026/164268.article
  51. https://www.navair.navy.mil/news/Navy-completes-install-first-MQ-25-Unmanned-Air-Warfare-Center-aboard-USS-George-HW-Bush-CVN
  52. https://www.boeing.com/features/2025/06/advancing-into-the-future
  53. https://www.airpac.navy.mil/Organization/Unmanned-Carrier-Launched-Multi-Role-Squadron-10/About-Us/
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