Northrop T-38 Talon

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T-38 Talon
A T-38A from Edwards Air Force Base
Role Advanced trainer
National origin United States
Manufacturer Northrop Corporation
First flight 10 April 1959
Introduction 17 March 1961
Status Operational
Primary users United States Air Force
United States Navy
NASA
Turkish Air Force
Produced 1961–1972
Number built 1,189
Developed from Northrop N-156
Variants Northrop F-5

The Northrop T-38 Talon is a two-seat, twinjet supersonic jet trainer designed and produced by the American aircraft manufacturer Northrop Corporation. It was the world's first supersonic trainer as well as the most produced.

The T-38 can be traced back to 1952 and Northrop's N-102 Fang and N-156 fighter aircraft projects. During the mid-1950s, Northrop officials decided to adapt the N-156 to suit a recently issued general operating requirement by the United States Air Force (USAF) for a supersonic trainer to replace the Lockheed T-33. The bid was successful, in no small part on its lower lifecycle cost comparisons to competing aircraft, and the company received an initial order to build three prototypes. The first of these, designated YT-38, made its maiden flight on 10 April 1959. The T-38 was introduced to USAF service on 17 March 1961.

The USAF is the largest operator of the T-38. Additional operators of the T-38 include NASA and the United States Navy. U.S. Naval Test Pilot School in Patuxent River, Maryland, is the principal US Navy operator. Other T-38s were previously used by the US Navy for dissimilar air combat training until replaced by the similar Northrop F-5 Tiger II. Pilots of other NATO nations have commonly flown the T-38 during joint training programs with American pilots.[1] The T-38 remains in service as of 2023 with several air forces. As of 2023, the T-38 has been in service for over 60 years with the USAF, its original operator. In September 2018, USAF announced the replacement of the Talon by the Boeing–Saab T-7 Red Hawk with phaseout to begin in 2023.[2]

Development[edit]

A T-38C assigned to the 416th Flight Test Squadron, 412th Test Wing, Air Force Test Center, flies over the Mojave desert near Edwards AFB, California
Air-to-air right side view of a USAF T-38 Talon aircraft from 560th Flying Training Squadron, Randolph AFB, Texas as his lead performs a left pitchout
A T-38C cockpit
Two T-38 chase planes follow Space Shuttle Columbia as it lands at Northrop Strip in White Sands, New Mexico, ending its mission STS-3.
NASA Dryden's T-38 in flight over Cuddeback Dry Lake in Southern California
Picture of the formation leader, taken from the backseat of a T38C, of the 479th Fighter Training Group, Moody AFB, Georgia, 2006
A T-38 in Portuguese Air Force colours at Air Base No. 11 (BA11 – Beja)
U.S. Air Force 25th Flying Training Squadron instructor pilot and his student walk to a T-38A to begin flight training at Vance Air Force Base, Oklahoma, November 1997.
An X-15 in flight attached to a B-52 mother ship, with a T-38 chase plane, 1961
A T-38 takes off from Edwards Air Force Base with only one engine during single-engine takeoff testing, to evaluate recommended speeds for takeoff if an engine fails.

In 1952, Northrop began work on a fighter project, the N-102 Fang, with shoulder-mounted delta wing and a single engine.[3] The proposed General Electric J79 engine, weighing nearly two tons, meant the resulting aircraft would be large and expensive.[4][5] During 1953, representatives from General Electric Aviation's newly created Small Aircraft Engine Department showed Northrop a relatively compact engine, around 400 lb installed weight, capable of 2,500 lb of thrust. Upon seeing the engine, Northrop VP-Engineering Edgar Schmued saw the possibility of reversing the trend toward the large fighters.[5]

Schmued and chief engineer Welko Gasich decided on a small, twin-engined "hot-rod" fighter, the N-156. Northrop launched its N-156 project in 1954, aiming for a small, supersonic fighter jet capable of operating from the US Navy's escort carriers.[5] When the Navy chose not to pursue equipping its fleets in such a fashion, favoring large fleet carriers instead, Northrop opted to continue work on the N-156 using in-house funding. It was instead recast as a lightweight fighter, referred to as the N-156F, that was primarily aimed at the export market.[5]

In the mid-1950s, the USAF issued a general operating requirement for a supersonic trainer, seeking to retire its 1940s-era Lockheed T-33s for an aircraft better suited to training pilots to fly its high speed fighter aircraft.[5] Northrop officials decided to adapt the N-156 to this competition. The only other candidate was the two-seat version of the North American F-100 Super Sabre. Although the F-100 was not considered the ideal candidate for a training aircraft (it is not capable of recovering from a spin),[6] NAA was still considered the favorite in the competition due to that company's favored-contractor status with the USAF, but Northrop officials presented lifecycle cost comparisons that proved to be highly persuasive amongst USAF officials.[7] Accordingly, Northrop was awarded an initial contract in June 1956 to produce three prototypes, designated YT-38.[7]

On 10 April 1959, the first YT-38 performed its maiden flight at the hands of test pilot Lew Nelson.[7][8]

The type was quickly adopted. The first production examples were delivered in 1961, entering service on 17 March 1961, complementing the Cessna T-37 Tweet primary jet trainer. When production ended in 1972, 1,187 T-38s had been built, plus two N-156T prototypes. Since its introduction, an estimated 50,000 military pilots have trained on this aircraft. The USAF remains one of the few armed flying forces using dedicated supersonic final trainers, as most, such as the US Navy, use high-subsonic trainers.[9]

During 1962, the T-38 set absolute time-to-climb records for 3,000, 6,000, 9,000, and 12,000 meters, beating the records for those altitudes set by the F-104 in December 1958. The F-4 Phantom beat the T-38's records less than a month later.

The majority of T-38s built were of the T-38A variant. The USAF had a small number of aircraft converted for weapons training, designated AT-38B, which were fitted with a gunsight and could carry a gun pod, rockets, or bombs on a centerline pylon. By the end of September 2017, 503 T-38s were still operational with the USAF,[10] while many more remained in operation around the world.

Most of the USAF's aircraft, T-38A and AT-38B, have been converted to the T-38C through an avionics upgrade program. Improvements include the addition of a head-up display, global satellite positioning, inertial navigation system, and traffic collision avoidance system. Most aircraft have received a propulsion modification to improve low-altitude engine thrust. Around a third of the fleet, those that experience more severe usage, are currently undergoing structural replacements and upgrades, as well as receiving new wings, to extend their service life to 2029.[11]

The fighter version of the N-156 was selected for the US Military Assistance Program and produced as the F-5 Freedom Fighter. Many of these have since reverted to a weapons-training role, as various air forces have introduced newer types into service. The F-5G was an advanced single-engined variant later renamed the F-20 Tigershark. In 2018, the Iranian Air Force announced that an outwardly similar aircraft, named the Kowsar, had been constructed within Iran.[12][13][14]

Design[edit]

The Northrop T-38 Talon is of a conventional configuration, with a small, low-mounted, long-chord wing, a single vertical stabilizer, and tricycle undercarriage. The cockpit accommodates a student pilot and instructor in a tandem seating arrangement. The flight controls were hydraulically-powered and lacked manual reversion, and thus the aircraft would be unflyable in the event of both engines failing mid-flight.[7]

Its handling was relatively conventional and viceless. While it was originally considered to be too easy to fly compared with frontline fighters of the 1960s, by the twenty-first century, it had become regarded as the most challenging aircraft in the USAF's inventory.[15] The aircraft's nimble performance earned it the nickname "white rocket". It had been considered by trainee pilots to be a somewhat unforgiving aircraft from an aerodynamic standpoint.[16]

The T-38 can be visually distinguished from both the F-5B and F-5F, which are also derived from the N-156, by the wings. The wing of the T-38 meets the fuselage straight and ends square, while the F-5 has leading edge extensions near the wing roots and wingtip launch rails for air-to-air missiles. The wings of both the T-38 and the F-5 family use conventional skin over spar-rib structure.[17] The T-38's wings were originally designed to withstand 7.33-G loads and for a fatigue life of 4,000 flight hours. This proved sufficient for the majority of the training syllabus, but was a major limiting factor when the aircraft was used for aggressive dogfighting-style maneuvering. Incidents of wing tips separating mid-flight were reported. Northrop resolved this via the installation of new wings with thickened skins.[11]

Throughout the development process, a strict weight control regime was exercised by the design team.[7] This was one reason for the T-38's relative simplicity; only basic systems for navigation and communication were provided. No fuel was housed within the wings while no provision for external stores was made.[7] The aircraft's twin General Electric J85-5A turbojet engines were accommodated within the fuselage to exert less drag and produce fewer aerodynamic disturbances. The J85-5A engine, despite generating up to 3,850 lb of static thrust, was relatively compact and lightweight for the era, weighing less than 600 pounds.[5] Air was supplied to the engines via intakes at the wing roots. A twin-engine arrangement had been pursued to provide a greater margin of safety.[7]

Various design decisions were taken and features were incorporated to simplify the T-38 and make it as easy to maintain as possible.[7] To avoid removing the vertical fin while changing an engine, the fin was attached directly to the keel structure between the engines, and instead detaching the horizontal stabilizer along with the entire aft shell of the fuselage that surrounds the engines, which could be removed relatively easily via undoing several fasteners that hold the fuselage shell together and disconnecting two push rods that connect the pilot's control stick to the horizontal stabilizer's hydraulic actuators.[7]

To avoid having to break and reconnect multiple hydraulic lines during an engine swap, designers mounted the hydraulic pump and other accessory drives on the fuselage which joined to the engine by a short driveshaft. Several internal check valves prevented a loss of hydraulic fluid.[7] The engines hung from rails on either side of the central keel. This design enabled ground crews to remove and replace an engine in roughly one hour.[7]

Operational history[edit]

Military[edit]

The USAF Strategic Air Command (SAC) had T-38s in service from 1978 until SAC's 1991 inactivation. These aircraft were used to enhance the career development of bomber and tanker copilots through the Accelerated Copilot Enrichment Program. They were later used as proficiency aircraft for all B-52, B-1, Lockheed SR-71, U-2, Boeing KC-135, and KC-10 pilots. SAC's successors, the Air Combat Command (ACC) and the Air Force Global Strike Command (AFGSC) retain T-38s as proficiency aircraft for U-2 pilots and B-2 pilots, respectively.[9]

The Air Training Command's successor, the Air Education and Training Command (AETC), uses the T-38C to prepare pilots for the F-15C Eagle and F-15E Strike Eagle, the F-16 Fighting Falcon, B-52 Stratofortress, B-1B Lancer, B-2 Spirit, A-10 Thunderbolt, F-22 Raptor, and F-35 Lightning II. The AETC received T-38Cs in 2001 as part of the Avionics Upgrade Program. The T-38Cs owned by the AETC have undergone propulsion modernization, which replaces major engine components to enhance reliability and maintainability, and an engine inlet/injector modification to increase available takeoff thrust.[9] These upgrades and modifications, with the Pacer Classic program, were to extend the service life of T-38s past 2020. The T-38 has an availability goal of 75%, which it maintained in 2011. In 2015, its availability was 60%.[18]

After graduating from basic flying on the Cessna T-37 Tweet, pilots were trained on more advanced aspects, including supersonic flight, blind flying, formation flight, handling stalls, single-engine flight procedures, low speed flight, and landing techniques.[16] Prior to the USAF ceasing the practice of trainees flying within icy conditions, the T-38's engines were prone to being damaged by ingesting ice. The relatively small engine intakes are also known to be problematic when flown at low speeds under 'hot and high' conditions.[19]

The landing gear's brakes have been criticised for being relatively weak, one of several factors that necessitates care while landing. Several incidents, including fatalities, have occurred due to imprecise management of the throttles and air speed during landing attempts.[19] Despite these factors, the T-38 has been regarded as a relatively safe trainer aircraft even into the twenty-first century. Between 1961 and 2005, the fleet has cumulatively flown 25 million hours, during which 150 of the 1,187 T-38s built between 1961 and 1972 were recorded as lost, resulting in 45 deaths.[11]

Besides the USAF and the USN, other military operators of the T-38 have included the German Air Force, the Portuguese Air Force, the Republic of China Air Force, and the Turkish Air Force.[9]

During late 2010, the USAF launched the T-X program to procure a replacement for its T-38s.[20] Bidders included a joint venture of BAE Systems and Rolls-Royce, offering the Hawk trainer, equipped with Rolls' Adour Mk951 engine with FADEC. Lockheed Martin and Korea Aerospace Industries, offered the T-50. Raytheon and Alenia Aermacchi offered the T-100, an aircraft whose design originated with the M-346.[21]

Boeing and Saab offered a new-technology design powered by the General Electric F404 turbofan engine. The Boeing/Saab bid first flew in December 2016. It was declared the winner of the T-X competition in September 2018.[22]

NASA[edit]

NASA operates a fleet of 32 T-38 trainers.[23] The fleet is typically used to train its astronauts and as a chase plane. NASA's fleet is housed primarily at Ellington Field in Houston, Texas. NASA's internal projections showed the number of operational jet trainers falling to 16 by 2015. The agency spends $25–30 million annually to fly and maintain the T-38s.[24]

During the Space Shuttle era, an established NASA tradition was for astronauts to arrive at the Kennedy Space Center in T-38 Talons.[25]

Civil[edit]

Seven privately owned T-38s are in the U.S.[23] Boeing owns two T-38s, which are used as chase planes.[23] Thornton Corporation owns two T-38s, and the National Test Pilot School owns one T-38.[23] Two others are in private ownership.[23]

Variants[edit]

US Navy DT-38A at United States Navy Fighter Weapons School "Top Gun", 1974
  • N-156T: Northrop company designation.
  • YT-38: Prototypes, two built with YJ85-GE-1 engines, later designated YT-38A and four pre-production aircraft with YJ-85-GE-5 engines, later designated T-38A.[26]
  • T-38A: Two-seat advanced training aircraft, production model, 1,139 built.[26]
  • T-38A(N): Two-seat astronaut training version for NASA. See T-38N below.
  • AT-38A: A small number of T-38As were converted into weapons training aircraft.
  • DT-38A: A number of US Navy T-38As were converted into drone directors.
  • GT-38A: Permanently grounded aircraft, often due to flight or ground mishap, converted into ground procedural trainers or aircraft maintenance trainers.
  • NT-38A: A small number of T-38As were converted into research and test aircraft.
  • QT-38A: Unmanned target drone aircraft.
  • AT-38B: Two-seat weapons training aircraft.
  • T-38C: A T-38A with structural and avionics upgrades.[9]
  • T-38M: Modernized Turkish Air Force T-38As with full glass cockpit and avionics, upgraded by Turkish Aerospace Industries under the project codename "ARI" (Turkish: Arı, for Bee).[27]
  • T-38N: Former USAF T-38As bailed to NASA and T-38As directly assigned to NASA that received an Avionics Upgrade Program (AUP), modernizing communications and navigation systems, replacing outdated avionics, and adding a weather radar, flight management system, altitude alert systems, and modern controls and displays.[28]
  • ST-38 or N-205: A proposal to be fitted with 3 rocket engines in the 10,000lb thrust range burning hydrogen peroxide and JP-5, capable of Mach 3.2 and a maximum altitude of 200,000 feet (61,000 m) and only requiring modification to 25% of the airframe. It was to be used for training astronauts as part of the ARPS (Aerospace Research Flight School). It was first proposed in May 1958 and then again in 1963, however the Air Force showed no interest and instead selected the NF-104A .[29][30]
  • T-38 VTOL Proposed vertical takeoff variant with four lift nozzles behind the pilot.[31]

Operators[edit]

A T-38 Talon in Thunderbirds livery at the Alliance Air Show, 2014
A T-38 Talon at the Fort Worth Alliance Air Show, 2019

Current[edit]

 Germany
  • German Air Force – 46 T-38A in 1968, now upgraded to T-38C. All aircraft are stationed at Sheppard AFB, Texas and are painted in US markings.[32]
 Turkey
 United States

Former[edit]

 Portugal
 Republic of Korea
 Taiwan (Republic of China)

Accidents and incidents[edit]

More than 210 aircraft losses and ejections have been documented over the lifetime of the T-38.[39] The USAF has recorded 149 fatalities since operations began in 1960.[40]

  • February 1962 – The first crash of a T-38 occurred, near Webb AFB, Texas. One pilot was killed.[citation needed]
  • 31 October 1964 – Astronaut Theodore Freeman was killed as a result of a bird strike on a NASA operated T-38.[41][42]
  • 28 February 1966 (1966 NASA T-38 crash) – Astronauts Elliot See and Charles Bassett were killed when they struck a building in fog.[43][44]
  • 5 October 1967 – Astronaut Clifton "C.C." Williams was killed in a crash of a NASA operated T-38 due to an aileron jam.[45][46]
  • 18 January 1982 – Diamond Crash – Four T-38As of the U.S. Air Force Thunderbirds crashed while practicing for an airshow. After this crash, the T-38 was replaced in this role by the front line F-16A Fighting Falcon.
  • 21 May 2009 – One pilot was killed and the other ejected with serious injuries after a rudder malfunction caused the crash of a USAF T38A.[47]
  • 19 July 2013 – The plane went down south of Sheppard Air Force Base at approximately 6:48 a.m., near Pecanway Drive and Horton Lane in Wichita County and the pilots ejected safely with minor injuries.
  • 21 November 2019 – Two pilots killed during a collision while landing.[48]
  • 19 February 2021 – The two-person USAF crew of a T-38 was killed in a landing crash near Montgomery Regional Airport in Alabama. The aircraft was assigned to the USAF 14th Flying Training Wing at Columbus AFB, Mississippi. The crash was later attributed to pilot error.[49]
  • 19 November 2021 – Two aircraft collided on approach to Laughlin Air Force base, resulting in the death of one student.[50]
  • 7 November 2022 – A T-38C crashed near Columbus AFB, Mississippi, with one pilot safely ejecting.[51]

Aircraft on display[edit]

A T-38 Talon on display at the Frontiers of Flight Museum
A T-38 Talon on display at the Kennedy Space Center Visitor Complex
T-38 Serial Numbers 60–0573, 60–0589, and 61–0828 at Owatonna Degner Regional Airport, Minnesota
YT-38A
T-38A
GT-38A
AT-38B
T-38N

Specifications (T-38A)[edit]

Data from USAF factsheet[9]

General characteristics

  • Crew: 2
  • Length: 46 ft 4.5 in (14.135 m)
  • Wingspan: 25 ft 3 in (7.70 m)
  • Height: 12 ft 10.5 in (3.924 m)
  • Wing area: 170 sq ft (16 m2)
  • Empty weight: 7,200 lb (3,266 kg)
  • Gross weight: 11,820 lb (5,361 kg)
  • Max takeoff weight: 12,093 lb (5,485 kg)
  • Powerplant: 2 × General Electric J85-5A afterburning turbojet engines, 2,050 lbf (9.1 kN) thrust each dry, 2,900 lbf (13 kN) with afterburner
  • J85-5A upgraded with PMP modification to J85-5R: 2,200 lbf (9.8 kN)dry / 3,300 lbf (15 kN) afterburner[84]

Performance

  • Maximum speed: 746 kn (858 mph, 1,382 km/h)
  • Maximum speed: Mach 1.3
  • Range: 991 nmi (1,140 mi, 1,835 km)
  • Service ceiling: 50,000 ft (15,000 m)
  • Rate of climb: 33,600 ft/min (171 m/s) [85]
  • Wing loading: 69.53 lb/sq ft (339.5 kg/m2)
  • Thrust/weight: 0.65

See also[edit]

Related development

Related lists

References[edit]

Citations[edit]

  1. ^ "ENJJPT, 40 years of training NATO's future military pilots". blogbeforeflight.net. 27 April 2022.
  2. ^ United States, Air Force (27 September 2018). "Air Force awards next-generation fighter and bomber trainer". af.mil. Secretary of the Air Force Public Affairs. Retrieved 1 November 2022.
  3. ^ Johnsen 2006, pp. 5–6.
  4. ^ Eden 2004, p. 344.
  5. ^ a b c d e f Garrison August/September 2005, p. 60.
  6. ^ Due to its elongated fuselage – the pilot's operating handbook for the two-seat version contains an instruction to avoid spins.
  7. ^ a b c d e f g h i j k Garrison August/September 2005, p. 61.
  8. ^ "Northrop marks the 50th anniversary of T-38 Talon first flight". defencetalk.com. 14 April 2009. Archived from the original on 6 April 2012. Retrieved 21 August 2011.
  9. ^ a b c d e f "T-38 TALON Fact Sheet". U.S. Air Force. 2 May 2008. Archived from the original on 2 June 2013.
  10. ^ "USAF Almanac 2018" (PDF). Archived (PDF) from the original on 7 May 2019. Retrieved 28 November 2018.
  11. ^ a b c Garrison August/September 2005, p. 64.
  12. ^ "New Fighter Jet Unveiled By Iranian Military". Forces Network. British Forces Broadcasting Service. 21 August 2018. Retrieved 29 September 2019.
  13. ^ "Iran unveils new domestically-produced fighter jet". BBC News. 21 August 2018. Retrieved 29 September 2018.
  14. ^ "Eyeing U.S., Iran unveils new fighter jet". Reuters. 22 August 2018. Retrieved 29 September 2019.
  15. ^ Garrison August/September 2005, p. 62.
  16. ^ a b Garrison August/September 2005, p. 59.
  17. ^ TO 1T-38A-4, USAF T-38 Tech Order.
  18. ^ Butler, Amy (6 April 2015). "T-X Competition Fierce Despite GD, Alenia Split". Aviation Week & Space Technology. Archived from the original on 7 April 2015. Retrieved 7 April 2015.
  19. ^ a b Garrison August/September 2005, p. 63.
  20. ^ "USAF Braces For Fiscal Bombardment". AW & ST. 20 September 2010.
  21. ^ Power play, The World column, AW & ST, 16 September 2013, p. 12.
  22. ^ Reim, Garrett (27 September 2018). "Boeing wins $9.2b T-X trainer contract with USAF". FlightGlobal.com. Los Angeles: Flight International. Archived from the original on 28 September 2018. Retrieved 28 September 2018.
  23. ^ a b c d e "Aircraft – Make / Model Results: Northrop T-38". Federal Aviation Administration. Archived from the original on 12 January 2012. Retrieved 21 August 2011.
  24. ^ Creech, Gray. "T-38 Supersonic Trainer Jet Gets New Home". NASA. Archived from the original on 2 August 2011. Retrieved 21 August 2011.
  25. ^ "Discovery's final crew arrives at NASA's Kennedy Space Center". 20 February 2011. Archived from the original on 12 March 2017. Retrieved 9 March 2017.
  26. ^ a b Andrade 1979, p. 167.
  27. ^ "Modifications & Modernization T-38 Avionics Modernization Program". Turkish International Cooperation and Export Activities. Archived from the original on 15 August 2011. Retrieved 21 August 2011.
  28. ^ "NASA T-38N Hangar, Ellington Field". airliners.net. Archived from the original on 19 December 2014.
  29. ^ "Northrop Space Trainer". The Aeroplane, 3 April 1959, p. 393.
  30. ^ Landis, Tony (24 November 2021). "Flashback: Lockheed NF-104A Aerospace Trainer". United States Air Force Material Command.
  31. ^ "Conceptual Design Study Report NOR 67-6R" (PDF). ntrs.nasa.gov. 1967. Archived from the original (PDF) on 24 May 2010.
  32. ^ "Luftwaffe History". Geschichte der Luftwaffe. Retrieved 26 September 2019.
  33. ^ "Aircraft Inventory". Turkish Air Force Command. Archived from the original on 12 May 2016. Retrieved 12 June 2016.
  34. ^ a b Embraer, In association with. "2023 World Air Forces directory". Flight Global. Retrieved 12 December 2022.
  35. ^ "T-38 Talon | NAVAIR". www.navair.navy.mil. Retrieved 27 April 2022.
  36. ^ Sanzani, Matteo (January 17, 2018). "Portugal Retires Alpha Jet". blogbeforeflight.net. Archived from the original on 10 July 2018. Retrieved 26 September 2019.
  37. ^ "T-38s Reborn". Air Forces Monthly. Key Publishing Limited. 19 January 2011. Archived from the original on 30 August 2018. Retrieved 30 August 2018.
  38. ^ "Taiwan Air Power". TaiwanAirPower.org. April 13, 2008. Archived from the original on November 21, 2009. Retrieved August 30, 2018.
  39. ^ "Northrop T-38 Losses and Ejections". Archived from the original on November 21, 2014. Retrieved September 29, 2019.
  40. ^ "USAF T38 Flight Statistics EOY" (PDF). USAF. Retrieved 27 October 2022.
  41. ^ "Crash Kills Astronaut." Richland, WA – Tri City Herald, 1 November 1964[dead link]
  42. ^ "Goose Hit Jet, Killing Astronaut." The Miami News, 17 November 1964[dead link]
  43. ^ "2 Astronauts Die In Plane Crash." The Tuscaloosa News, 28 February 1966
  44. ^ "See – Bassett Backup Crew Gets Gemini." Daytona Beach, FL – Morning Journal newspaper, 1 March 1966
  45. ^ "Williams Wanted To Be First On The Moon." St. Petersburg, FL -Evening Independent newspaper, 6 October 1967
  46. ^ "Board Pinpoints Astronaut's Death." Sarasota, FL – Herald-Tribune newspaper, 7 June 1968
  47. ^ "Air Force Releases Results of T-38 Accident Investigation". Edwards Air Force Base. 13 October 2009. Retrieved 9 November 2022.
  48. ^ "United States Air Force Aircraft Investigation Board Report" (PDF). USAF Accident Board. 1 (1). 21 November 2019.
  49. ^ Cohen, Rachel (10 October 2021). "Pilots' errors upon descent led to fatal T-38 crash in February, Air Force says". Air Force Times. Retrieved 28 December 2022.
  50. ^ Novelly, Thomas (2022-05-27). "T-38 Crash That Killed Student Pilot in Texas Caused by Miscommunication, Leading to Change in Formation Landing Rules". Military.com. Retrieved 2022-10-27.
  51. ^ "T-38 crashes near Air Force training base in Mississippi". Air Force Times. Associated Press. 7 November 2022. Retrieved 9 November 2022.
  52. ^ "T-38 Talon/58-1192." Archived 2017-08-06 at the Wayback Machine South Dakota Air and Space Museum. Retrieved 12 April 2013
  53. ^ "Northrop T-38 Talon". California Science Center. Archived from the original on June 23, 2015.
  54. ^ "Northrop T-38A Talon USAF 82FTW". stanakshot. Archived from the original on June 23, 2015.
  55. ^ "Maxwell AFB Display Aircraft". Warbird Information Exchange. Archived from the original on 2014-09-14. Retrieved September 26, 2019.
  56. ^ "USNTPS T-38 at Wikipedia Commons". Naval Aviation Museum, Pensacola, Florida. Archived from the original on March 2, 2015.
  57. ^ "Lackland Air Force Base USAF History and Traditions Museum". aero-web. Aviation Enthusiast Corner. Archived from the original on August 31, 1999.
  58. ^ "T-38 Talon/60-0549." Archived 2013-10-16 at the Wayback Machine Prairie Aviation Museum. Retrieved 12 April 2013
  59. ^ "Going Subsonic: Moving the T-38 Talon". National Air and Space Museum. 2019-03-27. Retrieved 2020-03-11.
  60. ^ "GT-38A Talon 60-0558 in Edinburgh." Archived 2014-12-19 at the Wayback Machine Talon in Edinburgh
  61. ^ "Edward F. Beale Museum". aero-web. Aviation Enthusiast Corner. Archived from the original on November 21, 2014.
  62. ^ "Laughlin AFB". aero-web. Archived from the original on September 17, 2014. Retrieved September 14, 2014.
  63. ^ "T-38 Talon/61-0817." Archived 2012-10-03 at the Wayback Machine Warbird Registry. Retrieved 12 April 2013
  64. ^ "Randolph AFB Aircraft Display". Warbird Information Exchange. Archived from the original on September 14, 2014.
  65. ^ "T-38 Talon/61-0854". Pima Air & Space Museum. Archived from the original on 2013-10-30. Retrieved April 12, 2013.
  66. ^ a b "Sheppard AFB Air Park". Archived from the original on September 17, 2014. Retrieved September 14, 2014.
  67. ^ "T-38 Talon/61-0902." Archived 2012-09-30 at the Wayback Machine Warbird Registry. Retrieved 12 April 2013
  68. ^ "Salina, Oklahoma, Local Attractions". Retrieved October 1, 2019.
  69. ^ "T-38 Talon/63-8224." Archived 2013-05-01 at the Wayback Machine Evergreen Aviation & Space Museum. Retrieved 12 April 2013
  70. ^ "Aircraft Data 64-13198, 1964 Northrop T-38A Talon C/N N.5627". www.airport-data.com. Retrieved 2020-11-12.
  71. ^ "Northrop T-38A Talon – USA – Air Force". airliners.net. Archived from the original on September 14, 2014.
  72. ^ "Northrop T-38A Talon SN: 65-10405". aero-web. Archived from the original on March 4, 2016. Retrieved September 13, 2014.
  73. ^ "Northrop T-38A Talon SN: 65-10426". aero-web. Archived from the original on October 11, 2011. Retrieved September 14, 2014.
  74. ^ "NASA T-38 Talon". Aviation Heritage Park. Archived from the original on October 29, 2014.
  75. ^ Wilson, Laurel (March 23, 2014). "NASA T-38 Talon plane arrives in BG". Bowling Green Daily News. Retrieved October 1, 2019.
  76. ^ "Dyess Linear Air Park". aero-web. Archived from the original on August 31, 1999.
  77. ^ "T-38 Talon/60-0593." Archived 2012-01-08 at the Wayback Machine March Field Air Museum. Retrieved 12 April 2013
  78. ^ "T-38 Talon/61-0824." Archived 2013-04-23 at the Wayback Machine Hill Aerospace Museum. Retrieved 12 April 2013
  79. ^ "T-38 Talon/60-0576." Archived 2012-09-26 at the Wayback Machine Warbird Registry. Retrieved 12 April 2013
  80. ^ "T-38 Talon/65-10441." Archived 2013-04-04 at the Wayback Machine National Museum of the USAF. Retrieved 12 April 2013
  81. ^ "NASA Space Center Museum". tinfeathers.com. Archived from the original on April 12, 2013.
  82. ^ "Northrop T-38N Talon Hoisted to Flight Deck" Archived 2018-06-12 at the Wayback Machine Intrepid Museum. Retrieved 11 July 2018.
  83. ^ "T-38N N968NA". stanakshot.free.fr. 2014-11-02.
  84. ^ "T-38 Talon". af.mil.
  85. ^ Even though this value has been printed in USAF outlets for many years, it is probably incorrect. The T-38 time-to-climb record, set in 1962, was three minutes to 30,000 feet. According to Northrop's Roy Martin (quoted on p. 64 of Air & Space/Smithsonian, Vol. 20, No. 3 (August/September 2005)), a normal climb at military power – that is, maximum power without afterburner – is around 6,000 feet/minute.

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