NTSB CAROL · Event
Event ERA14LA208
Registry · N6364V
FAA Aircraft Registry record.
Make / Model
ALON A2
Year of manufacture
1965 · 49 years old at event
Engine
CONT MOTOR C90 SERIES (95 hp)
Seats / Engines
2 seats · 1 engine
Last airworthiness date
19650730
ADS-B equipped
Yes — Mode-S A856FE
Registrant of record
GREGORY VERNON L
Source: FAA Aircraft Registry (releasable master file).
Aircraft involved
Probable cause & findings
A total loss of engine power during initial climb for reasons that could not be determined during postaccident examination and testing.
Factual narrative
HISTORY OF FLIGHTOn April 27, 2014, about 1700 eastern daylight time, an Alon A2, N6364V, experienced a total loss of engine power shortly after takeoff from Deck Airpark (NC11), Apex, North Carolina. The pilot subsequently made an off-airport forced landing into a forest. The private pilot sustained minor injuries, and the passenger was not injured. Visual meteorological conditions prevailed and no flight plan was filed for the local flight. The airplane was registered to and operated by a private individual under the provisions of Title 14 Code of Federal Regulations Part 91 as a personal flight. The pilot reported that the taxi and initial takeoff were "normal;" however, when the airplane was about 100 feet above the trees that bordered the airport, the engine experienced a total loss of power. The pilot retarded the throttle and immediately reapplied full throttle. The engine subsequently restarted, but immediately lost power again. He then performed a forced landing into the trees, about 500 feet past the departure end of the runway. The pilot reported that he had about 15 gallons of autogas in the fuel tanks prior to departure. PERSONNEL INFORMATIONAccording to pilot provided information and Federal Aviation Administration (FAA) records, the pilot held a private pilot certificate with a rating for airplane single-engine land. He held a third-class medical certificate, which was issued on August 20, 2013. The pilot reported 1471.6 total flight hours, with 38.3 of those hours in the accident airplane make and model. AIRCRAFT INFORMATIONThe accident airplane, an Alon A2 (serial number A-40), was manufactured in 1965. It was registered with the FAA on a standard airworthiness certificate for normal operations. The airplane had a total time of 1,872.36 hours as of the last annual inspection, which was completed on January 4, 2014. The airplane was powered by a Continental C90 series engine. As of the last annual inspection, the engine had accumulated a total of 1,661 hours, with 287 hours since last major overhaul. METEOROLOGICAL INFORMATIONThe 1651 recorded weather observation at Raleigh-Durham International Airport (RDU), Raleigh, North Carolina, located approximately 10 miles to the northeast of the accident location, included wind from 210 degrees at 6 knots, 10 miles visibility, scattered clouds 25,000 feet above ground level, temperature 28.3 degrees C, dew point 8.9 degrees C; altimeter setting 29.92 inches of mercury AIRPORT INFORMATIONThe accident airplane, an Alon A2 (serial number A-40), was manufactured in 1965. It was registered with the FAA on a standard airworthiness certificate for normal operations. The airplane had a total time of 1,872.36 hours as of the last annual inspection, which was completed on January 4, 2014. The airplane was powered by a Continental C90 series engine. As of the last annual inspection, the engine had accumulated a total of 1,661 hours, with 287 hours since last major overhaul. WRECKAGE AND IMPACT INFORMATIONInitial examination of the aircraft by an FAA inspector revealed that the airplane impacted several trees and came to rest inverted between two trees, resulting in substantial damage to the wings and fuselage. Local authorities reported to the inspector that there was a strong fuel smell at the accident scene; however, the fuel tank selected at takeoff was not noted or provided to the NTSB. ADDITIONAL INFORMATIONA subsequent examination, of the engine at a storage facility, under NTSB oversight, revealed minimal external damage. The throttle, mixture, and carburetor heat controls remained attached to the engine and operated without anomalies. The engine remained attached to the airframe and was fitted with a 5 gallon fuel container, between the wing root and the carburetor, to facilitate an engine run. The wings were removed at the wing root to facilitate transport, and continuity was not confirmed from fuel tank to the separation point. The engine started and operated through various power settings with no abnormalities noted. No anomalies were noted from the 5 gallon fuel container through the fuel system. FAA Guidance According to an NTSB accident report (ERA12LA131), testing conducted at the FAA Technical Center revealed that vapor pressure of autogas can vary widely as formulations are changed seasonally, and according to local requirements. High vapor pressure can promote vapor lock in aircraft fuel systems causing engine power to be reduced or the engine to completely fail and testing by the FAA William J. Hughes Technical Center concluded that autogas with high vapor pressure can accelerate the formation of carburetor ice. The Pilot's Handbook of Aeronautical Knowledge (FAA-H-8083-25A) defines vapor lock as "A problem that mostly affects gasoline-fuelled internal combustion engines. It occurs when liquid fuel changes state from liquid to gas while still in the fuel delivery system. This disrupts the operation of the fuel pump, causing loss of feed pressure to the carburetor or fuel injection system, resulting in transient loss of power or complete stalling. Restarting the engine from this state may be difficult. The fuel can vaporize due to being heated by the engine, by the local climate, or due to a lower boiling point at high altitude." DOT/FAA/CT-87/05 "Autogas in General Aviation Aircraft," states in part "The conditions which define the worst case for vapor lock testing (i.e., most likely to result in vapor lock) are as follows. 1. Takeoff fuel flow 2. Initial fuel temperature between 38 and 43 degrees Celsius (100 to 110 degrees Fahrenheit) 3. Ambient air temperature of 29 degrees Celsius or higher (85 degrees Fahrenheit). 4. Engine at operating temperatures typically found after a prolonged idling or a hot soak. 5. ASTM class E (winter grade) fuel if the testing is for autogas" An FAA chart, titled "Conditions Favoring Carb Ice Formation," indicated that with the ambient temperature and dew point, "Icing at glide and cruise power" was probable. The pilot stated that, before the accident flight, the airplane had about 15 gallons of automotive gasoline in the fuel tanks. The taxi and initial takeoff were "normal"; however, when the airplane was about 100 ft above the trees that bordered the airport, the engine experienced a sudden total loss of power. The pilot then reduced the throttle and reapplied full throttle. Although the engine momentarily restarted, it then immediately lost power. The airplane subsequently impacted trees and came to rest inverted. Local authorities reported a strong fuel smell at the accident location, but the exact amount of spilled fuel could not be determined. Examination of the airframe and a subsequent test run of the engine revealed no mechanical anomalies that would have precluded normal operation. Federal Aviation Administration guidance indicates that vapor lock is a problem that mostly affects gasoline-fueled internal combustion engines and can result in a transient or complete loss of power. The guidance further states that restarting the engine from this state may be difficult because fuel can be vaporized by engine heat. Given that the ambient air temperature, the fuel flow condition (takeoff), and the likely engine temperature were conducive to the occurrence of vapor lock, it is possible that the loss of engine power was due to vapor lock; however, insufficient evidence existed to determine whether vapor lock occurred during the accident flight. The weather conditions about the time of the accident were conducive to the accumulation of carburetor icing at cruise and glide power; however, given the pilot's statement that the engine operated "normally" until the sudden loss of power and that the airplane was climbing at a high power setting, it is not likely that the carburetor accumulated ice. Source: NTSB Aviation Accident Database Retrieved: 2026-02-12
NTSB Findings
Hierarchical cause / factor breakdown from the FAA bulk avdata database. Each finding tagged C (Cause) or F (Factor).
- C Not determined-Not determined-(general)-(general)-Unknown/Not determined - C
- — Environmental issues-Physical environment-Object/animal/substance-Tree(s)-Contributed to outcome
Verbatim from NTSB's published report. Source file
NTSB_2014_ERA14LA208.txt.
Findings + structured fields enriched from FAA avall.mdb.
Full investigation docket on
data.ntsb.gov ↗.
Beyond the agency record
Search this event elsewhere.
Pre-filled searches into the sources where news + community discussion of aviation events lives. External sources are reported, not agency. Treat them as signal that something happened, not as fact about what happened.
Entity-clustered aviation events in the press — last 24 hr + 30-day archive.
Official agency record + docket.
Investigative docket: factual reports, photos, transcripts.
Long-running aviation incident database (Flight Safety Foundation).
Community NTSB synthesis blog — often has photos and witness reports.
Gold-standard aviation incident blog.
Aviation industry news search.
GA pilot forum — informed but rumor-prone.
GA pilot subreddit search.
Tail-number page — flight history (free tier limited).
AOPA Air Safety Institute search.
Mainstream press coverage. Recent events only.
Privacy-preserving news search.
External links open in a new tab. We don't ingest their content; we deep-link search queries.
Related research
What the literature says.
Academic papers and agency reports matching this event's aircraft type or causal vocabulary (icing, stall). Sourced from NASA NTRS, NTSB Safety Studies, FAA CAMI, AOPA Air Safety Institute, Embry-Riddle Scholarly Commons, arXiv, and the Semantic Scholar academic graph.
- arXiv 2023 · arXiv preprint
Large-eddy simulations of the NACA23012 airfoil with laser-scanned ice shapes
In this study, five ice shapes generated at NASA Glenn's Icing Research Tunnel (IRT) are simulated at multiple angles of attack (Broeren et al., J. of Aircraft, 2018).
- arXiv 2023 · arXiv preprint
Novel Online-Offline MA2C-DDPG for Efficient Spectrum Allocation and Trajectory Optimization in Dynamic Spectrum Sharing UAV Networks
Unmanned aerial vehicle (UAV) communication is of crucial importance for diverse practical applications. However, it is susceptible to the severe spectrum scarcity problem and interference since it op…
- Semantic Scholar 2019 · Article (International Conference on Interaction Sciences)
Using lda2vec Topic Modeling to Identify Latent Topics in Aviation Safety Reports
The study of aviation safety report in the aviation industry usually relies on manually labeled data sets, and then classifies and models related problems, which have become insufficient in the face o…
- arXiv 2023 · arXiv preprint
Variation of Critical Crystallization Pressure for the Formation of Square Ice in Graphene Nanocapillaries
Two-dimensional square ice in graphene nanocapillaries at room temperature is a fascinating phenomenon and has been confirmed experimentally.
- arXiv 2022 · arXiv preprint
Enhanced Prediction of Three-dimensional Finite Iced Wing Separated Flow Near Stall
Icing on three-dimensional wings causes severe flow separation near stall. Standard improved delayed detached eddy simulation (IDDES) is unable to correctly predict the separating reattaching flow due…
- NASA NTRS 2019 · Contractor Report (CR)
An Evaluation of an Analytical Simulation of an Airplane with Tailplane Icing by Comparison to Flight Data
This report presents the assessment of an analytical tool developed as part of the NASA/FAA Tailplane Icing Program. The analytical tool is a specialized simulation program called TAILSM4 which was de…
Browse the full corpus — academia portal ↗