NTSB CAROL · Event
Event CEN18LA146
Registry · N9746C
FAA Aircraft Registry record.
Make / Model
CESSNA T303
Engine
CONT MOTOR GTSI0-520-F-K (435 hp)
Seats / Engines
4 seats · 2 engines
Last airworthiness date
19830502
ADS-B equipped
Yes — Mode-S AD95AE
Registrant of record
BAS PART SALES LLC
Source: FAA Aircraft Registry (releasable master file).
Aircraft involved
Probable cause & findings
The airplane’s inadvertent encounter with severe icing conditions during descent, which resulted in structural icing, the pilot’s inability to maintain altitude, and an emergency landing. Contributing to the accident was an incomplete preflight weather briefing.
Factual narrative
On April 24, 2018, about 1000 mountain daylight time, a Cessna T303 airplane, N9746C, impacted terrain during an emergency off-airport landing after encountering severe icing conditions near Pine Ridge, South Dakota. The commercial pilot and two passengers sustained minor injuries, and one passenger was not injured. The airplane sustained substantial damage to the wings and fuselage. The airplane was registered to and operated by Aberdeen Flying Service, Aberdeen, South Dakota, as a Title 14 Code of Federal Regulations Part 135 on-demand air taxi flight. Day instrument meteorological conditions (IMC) prevailed, and an instrument flight rules flight plan was filed for the flight. The flight departed Aberdeen Regional Airport (ABR), Aberdeen, about 0930 central daylight time, and was destined for the Pine Ridge Airport (IEN), Pine Ridge, South Dakota. Prior to the flight, the pilot obtained a weather briefing via the company computer system and reviewed the weather information with the company chief pilot. The pilot stated that based on the computer briefing, which did not include icing conditions, he was aware of the forecasted weather conditions along the route of flight and at the intended destination. After takeoff and during the climb to 12,000 ft mean sea level (msl), the airplane encountered light rime ice, and the pilot activated the de-ice equipment with no issues noted with the equipment. After crossing over the Pierre Regional Airport (PIR), Pierre, South Dakota, the pilot heard via the radio reports of better weather at a lower altitude, and the pilot requested a descent to between 5,000 and 6,000 ft. During a descent to 6,000 ft msl, the airplane encountered light to moderate icing conditions. Prior to the descent, the airplane was clear of ice accumulation. The pilot thought about turning back to PIR but could not get clearance until the airplane was closer to IEN due to poor radio coverage. Shortly thereafter, the pilot stated it felt "like a sheet of ice fell on us" as the airplane encountered severe icing conditions. The pilot applied full engine power in an attempt to maintain altitude. The airplane exited the overcast cloud layer about 500 ft above ground level (agl). The pilot decided to execute an off-airport emergency landing because the airplane could not maintain altitude. The airplane touched down in a field about 25 miles from IEN. During the emergency landing, the landing gear separated, and the airplane came to rest upright. The pilot reported no preaccident mechanical malfunctions or failures with the airplane that would have precluded normal operation, and the airplane was below its maximum gross weight. A review of photograph images obtained by the operator confirmed the airplane retained structural icing after the landing. At 0852, the IEN Automated Surface Observation System (ASOS), located 19 miles west-southwest of the accident site, reported wind from 350° at 15 knots gusting to 22 knots, 5 miles visibility in unknown precipitation and mist, ceiling overcast at 1,200 ft agl, temperature 2° C, dew point 1° C, altimeter 30.43 inches of mercury (Hg). At 0952, IEN ASOS reported wind from 360° at 11 knots gusting to 20 knots, 6 miles visibility in unknown precipitation and mist, ceiling overcast at 1,300 ft agl, temperature 2° C, dew point 1° C, altimeter 30.45 inches of Hg. The National Weather Service Aviation Weather Center Current Icing Products, which were available online for the preflight briefing, reported the probability of icing at 5,000 ft, 7,000 ft, and 9,000 ft, as follows: the probability indicated a greater than 75% probability of icing over South Dakota from below 5,000 ft through 9,000 ft. In addition, the icing intensity was depicted as light to moderate intensity, with a high threat of Supercooled Large Droplets at 5,000 ft and 7,000 ft over the region. The preflight weather briefing did not include any inflight weather advisories, which would have alerted the pilot of moderate icing conditions expected over the flight route in the form of airmen's meteorological information (AIRMET) Zulu that was issued at 0700 and valid for 0900. AIRMET Zulu included moderate ice between 5,000 ft and flight level 180 with conditions continuing beyond 0900. The preflight weather briefing did include a pilot report which indicated light rime icing conditions encountered by a commercial airplane climbing through IMC conditions between 3,500 ft and 10,000 ft. There was no current significant meteorological information (SIGMET) to prohibit the flight from operating at the time of the accident. According to the Federal Aviation Administration's Instrument Flying Handbook FAA-H-8083-15B; Chapter 10 on page 10-24: "The very nature of flight in IMC means operating in visible moisture such as clouds. At the right temperatures, this moisture can freeze on the aircraft, causing increased weight, degraded performance, and unpredictable aerodynamic characteristics. Understanding avoidance and early recognition followed by prompt action are the keys to avoiding this potentially hazardous situation … Structural icing is a condition that can only get worse." Before the air taxi flight, the commercial pilot obtained a weather briefing via the company computer system and reviewed the weather information with the company chief pilot. The pilot stated that based on the computer briefing, which did not include icing conditions, he was aware of the forecasted weather conditions along the route of flight and at the intended destination. However, the briefing was incomplete as it did not contain any in-flight weather advisories, which would have alerted the pilot of moderate icing conditions expected over the flight route in the form of AIRMET Zulu. After takeoff and during the climb to 12,000 ft mean sea level (msl), the airplane encountered light rime ice, and the pilot activated the de-ice equipment with no issues noted. After hearing reports of better weather at a lower altitude, the pilot requested a descent to between 5,000 and 6,000 ft. During the descent to 6,000 ft msl and with the airplane clear of ice, the airplane encountered light to moderate icing conditions. The pilot considered turning back to another airport but could not get clearance until the airplane was closer to his destination. Shortly thereafter, the pilot stated that it felt “like a sheet of ice fell on us” as the airplane encountered severe icing conditions. The pilot applied full engine power in an attempt to maintain altitude. The airplane exited the overcast cloud layer about 500 ft above ground level. The pilot chose to execute an off-airport emergency landing because the airplane could not maintain altitude. During the landing, the landing gear separated; the airplane came to rest upright and sustained substantial damage to the wings and fuselage. The pilot reported that there were no preaccident mechanical malfunctions or failures with the airplane that would have precluded normal operation and that the airplane was within its maximum gross weight. Structural icing was observed on the airframe after the landing. Based on the weather information, which indicated the probability of icing between 5,000 and 9,000 ft over the region and a high threat of supercooled large droplets between 5,000 and 7,000 ft, it is likely that the airplane, which was equipped for flight in icing conditions, inadvertently encountered severe icing conditions consistent with supercooled large droplets, which resulted in structural icing that exceeded the airplane’s capabilities to maintain altitude. 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 Environmental issues-Conditions/weather/phenomena-Temp/humidity/pressure-Conducive to structural icing-Ability to respond/compensate - C
- C Environmental issues-Conditions/weather/phenomena-Ceiling/visibility/precip-Freezing rain/sleet-Ability to respond/compensate - C
- C Aircraft-Aircraft structures-(general)-(general)-Capability exceeded - C
- C Aircraft-Aircraft oper/perf/capability-Performance/control parameters-Altitude-Attain/maintain not possible - C
- F Personnel issues-Task performance-Planning/preparation-Weather planning-Not specified - F
Verbatim from NTSB's published report. Source file
NTSB_2018_CEN18LA146.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 (icing, imc). 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 · Contractor Report (CR)
Icing Physics Studies Using the 3D SIDRM Test Article: 2023 Icing Tests Analysis
In-flight icing is an important safety issue and is a factor that affects aircraft design and performance. Newer regulations are driving a need for improvements in airframe and engine icing simulation…
- arXiv 2025 · arXiv preprint
Multi-Agent Deep Reinforcement Learning for UAV-Assisted 5G Network Slicing: A Comparative Study of MAPPO, MADDPG, and MADQN
The growing demand for robust, scalable wireless networks in the 5G-and-beyond era has led to the deployment of Unmanned Aerial Vehicles (UAVs) as mobile base stations to enhance coverage in dense urb…
- Embry-Riddle Scholarly Commons 2025 · Journal article (JAAER)
A Mathematical Model on the Temporal Dynamics of Aviation Competitive Pricing
This study investigates the competitive dynamics of airport pricing using U.S. airport data to validate the findings. It employs linear and nonlinear ordinary differential equation models to analyze t…
- NASA NTRS 2025 · Presentation
NASA Icing Update – March 2025
This NASA Icing Update was prepared for presentation to the SAE International AC-9C Inflight Icing Technology Committee. This update includes the following topics: planned Rotational Icing Scaling tes…
- arXiv 2024 · arXiv preprint
An energy-stable phase-field model for droplet icing simulations
A phase-field model for three-phase flows is established by combining the Navier-Stokes (NS) and the energy equations, with the Allen-Cahn (AC) and Cahn-Hilliard (CH) equations and is demonstrated ana…
- NASA NTRS 2024 · Presentation
NASA Icing Update – Oct 2024
This presentation provides a status update on select NASA icing research activities for the SAE AC-9C Icing Technical Committee Meeting on Oct 21, 2024.
Browse the full corpus — academia portal ↗