NTSB CAROL · Event
Event WPR23FA092
Registry · N4765G
FAA Aircraft Registry record.
Make / Model
CESSNA 414
Year of manufacture
1977 · 46 years old at event
Engine
CONT MOTOR TSIO-520 SER (300 hp)
Seats / Engines
7 seats · 2 engines
Last airworthiness date
19850818
ADS-B equipped
Yes — Mode-S A5DA72
Registrant of record
AIRCRAFT CHARTER AND LEASING LLC
Source: FAA Aircraft Registry (releasable master file).
Aircraft involved
Probable cause & findings
The pilot’s exceedance of the airplane’s critical angle of attack and failure to maintain proper airspeed during a turn to final, resulting in an aerodynamic stall and subsequent impact with terrain. Contributing to the accident was the pilot’s distraction due to a non-critical radio anomaly.
Factual narrative
HISTORY OF FLIGHTOn January 18, 2023, at 1307 Pacific daylight time, a Cessna 414 airplane, N4765G, was destroyed when it was involved in an accident near Modesto, California. The pilot was fatally injured. The airplane was operated as a Title 14 Code of Federal Regulations Part 91 personal flight. The airplane departed runway 10L at Modesto City-County Airport-Harry Sham Field (MOD), Modesto, California, at 1259. According to the Modesto tower controller, the pilot’s planned destination was Buchanan Field Airport (CCR), Concord, California. ADS-B flight data showed that the airplane climbed to 3,200 ft PA as it made a right turn and departed to the northwest, reaching about 150 kts. At 1301, the Modesto local tower controller instructed the pilot to switch radio frequencies to Northern California Terminal Radar Approach Control. The pilot responded that he was switching frequencies, but his subsequent radio transmission was on the MOD frequency. The pilot made several more radio transmissions that indicated he was attempting to change radio frequencies, but that his radio was not changing frequencies. The tower controller asked the pilot if he wanted to return to MOD, and the pilot responded that he did. The pilot was then instructed to make a left 180° turn and enter a left downwind pattern to runway 28 right (28R). The flight track data showed that about 1302 the airplane made a left turn back to the southeast and paralleled the runway about 3 miles west of MOD before descending and flying a non-standard traffic pattern for runway 28R. At 1304, the pilot queried the tower controller if they could hear him, and the tower controller responded that they had heard all his transmissions. The pilot again stated that his radio was not changing frequencies. At 1305, the flight track data showed the airplane had descended to a PA of about 1,500 ft and a groundspeed of 96 kts and was abeam the runway 28R threshold and the controller asked if he had the runway in sight. The pilot replied that he did have the runway in sight, and he was subsequently cleared to land. The pilot was informed runway 28R “was the long runway” and he read back that he was cleared to land runway 28R. The airplane then made a left base turn to the northeast on a heading directly towards the runway threshold. During the left base turn, the airplane angled further left towards a point about 1,000 ft beyond the runway 28R threshold and maintained a groundspeed of about 90 kts and continued to descend until it reached 200 PA about 0.5 miles from the runway. The airplane then entered a right turn to about a 090° heading before it started a left turn to the north. During the left turn, the groundspeed decreased from about 72 kts to 53 kts and the altitude decreased to 100 ft PA when the last ADS-B return was recorded at 1306:56 near site of the accident (Figure 1). Figure 1 – ADS-B Flight Track An aeromedical helicopter pilot and flight nurse reported they had just departed a hospital helipad about three miles north of MOD when they heard a pilot on the MOD tower frequency asking the controller if he could hear the pilot. The tower controller responded that they heard the pilot the entire time. The helicopter crew then observed the airplane maneuvering on what they thought was a downwind leg of the traffic pattern. They said the airplane was doing unusual maneuvers, “like S-turns.” The flight nurse, who was a private pilot, told the crew that the pilot was going to stall the airplane. A few seconds later, they witnessed the airplane stall and spin to the ground. Another witness, who was about a mile from the accident site, observed the airplane’s departure and then the final moments of the flight. He said the engines sounded normal as the airplane departed and returned, and he heard the engines rpm increase as the airplane descended in a spin. Dash camera video was obtained from an unknown witness that showed the final seconds of the flight. The video showed the airplane’s bank angle increase, the nose drop, and the airplane enter a near vertical left spin (Figure 2). Figure 2 – Dash Camera Capture, 3 Seconds Before Impact AIRCRAFT INFORMATIONThe airplane had undergone an annual inspection at MOD that was completed January 4, 2023. The airplane remained at MOD until the pilot picked it up on the day of the accident. Fueling records indicate the airplane was refueled with 73.5 gallons of AvGas (100LL) on January 18, 2023. AIRPORT INFORMATIONThe airplane had undergone an annual inspection at MOD that was completed January 4, 2023. The airplane remained at MOD until the pilot picked it up on the day of the accident. Fueling records indicate the airplane was refueled with 73.5 gallons of AvGas (100LL) on January 18, 2023. WRECKAGE AND IMPACT INFORMATIONThe airplane impacted soft terrain and was resting about 80° nose down on a 240° heading. Both the left and right engines and propellers were fully buried, with just the aft portions of the engines at ground level. Both the left and right wings were impact separated near the outboard edges of the wing flaps on each wing. The flap system was observed with the left flaps in the extended position and the right flaps impact damaged (the control rod was fractured). The landing gear were in the down position. The forward portion of the fuselage forward of the instrument panel was crushed and embedded in the ground. The fuselage was intact aft of the cockpit until just forward of the empennage. The empennage, including the left and right horizontal stabilizers and the vertical stabilizer, was bent to the right side of the aircraft. Both the left and right elevators and the rudder remained attached to the empennage. All major structural components of the airplane were identified at the accident site. Flight control cable continuity was established from the control surfaces to the cockpit controls with overload separation at both aileron bell cranks consistent with impact damage. Postaccident examination of the airframe and left engine revealed no evidence of any preimpact mechanical malfunctions or failures that would have precluded normal operation. A complete examination of the right engine was not accomplished due to impact damage. The three propeller blades on the right engine were bent aft and exhibited leading edge polishing and chordwise scratches. The airplane was equipped with an Insight engine data monitor that stored engine performance data. Data was recovered from the device that was dated from the day of the accident. The data did not record identical performance parameters for each engine during all phases of flight. Generally, the data for the No. 1 engine reflected higher performance numbers than the No. 2 engine. The disparity was more evident when the data reflected both engines were operating at lower power settings. No anomalous data was observed when viewing the data for each engine individually. ADDITIONAL INFORMATIONThe Federal Aviation Administration Airplane Flying Handbook states the following: “The downwind leg is a course flown parallel to the landing runway, but in a direction opposite to the intended landing direction. This leg is flown approximately 1/2 to 1 mile out from the landing runway and at the specified traffic pattern altitude. Pattern altitude is maintained until at least abeam the approach end of the landing runway. At this point, the pilot should reduce power and begin a descent. The pilot should continue the downwind leg past a point abeam the approach end of the runway to a point approximately 45° from the approach end of the runway, and make a medium-bank turn onto the base leg.” “The placement of the base leg is one of the important judgments made by the pilot to set up for a good landing. The pilot accurately judges the height, distance from the approach end of the runway, and rate of descent to allow a stabilized approach, round out, and touchdown at the desired spot.” “The final approach leg is a descending flightpath starting from the completion of the base-to-final turn and extending to the point of touchdown. This is probably the most important leg of the entire pattern, because of the sound judgment and precision needed to accurately control the airspeed and descent angle while approaching the intended touchdown point.” MEDICAL AND PATHOLOGICAL INFORMATIONAn autopsy of the pilot was performed by the Stanislaus County Sherriff's Coroner’s Office, Modesto, California. The cause of death was blunt force injuries. Toxicology testing performed by the Federal Aviation Administration (FAA) Forensic Sciences Laboratory detected the sedating antihistamine, diphenhydramine, in the pilot’s liver and muscle tissue. Loratadine and its metabolite, desloratadine, were also identified in his liver and muscle tissue; this antihistamine is generally considered non-impairing. No blood specimens were available for toxicology testing to determine therapeutic concentrations. Diphenhydramine is a sedating antihistamine (commonly marketed as Benadryl) and is available over the counter in many products used to treat colds, allergies, and insomnia. Diphenhydramine carries the warning that use of the medication may impair mental and physical ability to perform potentially hazardous tasks. It has a half-life of 3 to 14 hours. FAA provides guidance on wait times before flying after using this medication; post-dose observation time is 60 hours. Shortly after taking off, the pilot was instructed to change from the airport tower frequency to the departure control frequency. Numerous radio transmissions followed between tower personnel and the pilot that indicated the airplane’s radio was operating normally on the tower frequency, but the pilot could not change frequencies to departure control as directed. The pilot subsequently requested and received approval to return to the departure airport. During the flight back to the airport, the pilot made radio transmissions that indicated he continued to troubleshoot the radio problems. The airplane’s flight track showed the pilot flew directly toward the runway aimpoint about 1,000 ft from, and perpendicular to, the runway during the left base turn to final and allowed the airplane to descend as low as 200 ft pressure altitude (PA). The pilot then made a right turn about .5 miles from the runway followed by a left turn towards the runway. A pilot witness near the accident location observed the airplane maneuvering and predicted the airplane was going to stall. The airplane’s airspeed decreased to about 53 knots (kts) during the left turn and video showed the airplane’s bank angle increased before the airplane aerodynamically stalled and impacted terrain. Postaccident examination of the airframe, engines, and review of recorded engine monitoring data revealed no evidence of any preimpact mechanical malfunctions or failures that would have precluded normal operation. Toxicology testing showed the pilot had diphenhydramine, a sedating antihistamine, in his liver and muscle tissue. While therapeutic levels could not be determined, side effects such as diminished psychomotor performance from his use of diphenhydramine were not evident from operational evidence. Thus, the effects of the pilot’s use of diphenhydramine was not a factor in this accident. The accident is consistent with the pilot becoming distracted by the reported non-critical radio anomaly and turning base leg of the traffic pattern too early during his return to the airport. The pilot then failed to maintain adequate airspeed and proper bank angle while maneuvering from base leg to final approach, resulting in an aerodynamic stall and impact with terrain. 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).
- — Aircraft-Aircraft systems-Communications system-VHF communication system-Unknown/Not determined
- — Personnel issues-Task performance-Workload management-Task overload-Pilot
- — Aircraft-Aircraft oper/perf/capability-Performance/control parameters-Lateral/bank control-Capability exceeded
- — Aircraft-Aircraft oper/perf/capability-Performance/control parameters-Airspeed-Not attained/maintained
- — Personnel issues-Psychological-Attention/monitoring-Attention-Pilot
- — Personnel issues-Task performance-Use of equip/info-Aircraft control-Pilot
Verbatim from NTSB's published report. Source file
NTSB_2023_WPR23FA092.txt.
Findings + structured fields enriched from FAA avall.mdb.
Full investigation docket on
data.ntsb.gov ↗.
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Related research
What the literature says.
Academic papers and agency reports matching this event's aircraft type or causal vocabulary (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.
- NASA NTRS 2026 · Conference Paper
Computational Analysis of Steady State Aerodynamics of Transonic Truss-Braced Wing Configuration in Deep Stall
This study presents a computational investigation of steady state aerodynamics of the Subsonic Ultra-Green Aircraft Research (SUGAR) Transonic Truss-Braced Wing (TTBW) configuration over a wide range …
- arXiv 2023 · arXiv preprint
Automating Bird Diverter Installation through Multi-Aerial Robots and Signal Temporal Logic Specifications
This paper tackles the task assignment and trajectory generation problem for bird diverter installation using a fleet of multi-rotors.
- 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 2023 · arXiv preprint
Polycrystallinity enhances stress build-up around ice
Damage caused by freezing wet, porous materials is a widespread problem, but is hard to predict or control. Here, we show that polycrystallinity makes a great difference to the stress build-up process…
- 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…
- Embry-Riddle Scholarly Commons 2021 · Journal article (JAAER)
Analysis on the Negative Emotional, Physiological, and Cognitive Responses Elicited from of the Activation of a Stall Alarm
Failing to identify an aerodynamic stall can lead to the inability of an aircraft to sustain flight. To warn pilots of an impending or fully-developed stall, many aircraft have safety devices installe…
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