- Location: Bangor, ME
- Accident Number: CEN26FA098
- Date & Time: January 25, 2026, 19:44 Local
- Registration: N10KJ
- Aircraft: Bombardier CL-600-2B16
- Injuries: 6 Fatal
- Flight Conducted Under: Part 91: General aviation - Business
https://data.ntsb.gov/carol-repgen/api/Aviation/ReportMain/GenerateNewestReport/202338/pdf
https://registry.faa.gov/AircraftInquiry/Search/NNumberResult?nNumberTxt=N10KJ
On January 25, 2026, at 1944 eastern standard time (EST), a Bombardier CL-600-2B16
(Challenger 650) airplane, N10KJ, sustained substantial damage when it was involved in an
accident near Bangor, Maine. The pilot, copilot, and 4 passengers were fatally injured. The
airplane was operated as a Title 14 Code of Federal Regulations Part 91 business flight.
A review of ADS-B flight track data revealed that at 1420:47 central standard time, the airplane
departed William P Hobby Airport (KHOU), Houston, Texas, on the first leg of a two-leg
transatlantic flight to Châlons Vatry Airport (LFOK), Châlons-en-Champagne, France. At
1809:15 EST (all times EST unless otherwise noted), the airplane landed on runway 33 at
Bangor International Airport (KBGR) and then taxied to the airport’s fixed based operator (FBO)
ramp to refuel.
According to the airplane’s flight data recorder (FDR), at 1815:22, the airplane arrived to the
FBO ramp. The left-and-right engines were shut down, and the airplane remained electrically
powered by the auxiliary power unit (APU) while the airplane was refueled with Jet A-1 fuel.
After refueling, the airplane’s total fuel load was about 19,872 lbs.
At 1913:42, the airplane began taxiing from the FBO ramp toward the deice pad. At 1917:46,
the airplane stopped at the deice pad and subsequently shut down the engines in preparation
for deicing.
According to a preliminary review of airport closed-circuit television (CCTV) footage, the
airplane was facing northwest during the deicing and anti-icing applications. The airplane
deicing process started at 1919:26 and concluded at 1927:04. According to FBO
documentation, about 41 gallons of Type I deice fluid (Inland Technologies SafeTemp ES Plus)
were used to deice the airplane.
Continued airport CCTV footage showed the application of Type IV anti-ice started at 1927:43
and concluded at 1930:55. According to FBO documentation, about 28 gallons of Type IV antiice fluid (Dow Chemical Inc. UCAR FLIGHTGUARD AD-49) were dispensed during the anti-ice
process. The reported airport weather conditions when the anti-ice fluid was dispensed
included a surface visibility of 3/4 statute miles (sm), light snow, an outside temperature of -
16°C, and a surface wind from 040° at 6-8 knots (055° magnetic). Nighttime conditions existed
during the deice/anti-icing process.
Following the anti-icing application, the airplane sat for 4 minutes 51 seconds before it taxied
from the deice pad at 1935:46. At that time, about 8 minutes 3 seconds had elapsed since the
start of the anti-icing application.
According to a preliminary review of the cockpit voice recorder (CVR), the flight crew
discussed holdover times during the taxi to runway 33. The pilot commented that it was
“standard” to have 14-18 minutes and that if the wait was more than 30 minutes, they would
return to the ramp to deice again. The copilot concurred with the pilot.
At 1940:16, the airplane stopped about 200 ft before the runway 33 hold short line. At 1940:54,
the tower controller asked the flight crew to report when they were ready for takeoff. The
copilot replied that they would advise when ready. At 1942:50, the copilot told the tower
controller that they were ready for takeoff on runway 33. About 3 seconds later, the tower
controller told the flight crew that the runway 33 runway visibility range (RVR) was greater than
6,000 ft, the surface wind was 060° magnetic at 9 knots, the flight was cleared for takeoff on
runway 33, and to fly runway heading after takeoff. At 1942:56, the airplane resumed the taxi
onto runway 33, and at 1943:04, the copilot read back the takeoff clearance correctly to the
tower controller. There were no additional radio transmissions recorded between the flight
crew and the tower controller.
According to the FDR, at 1943:57, the engine power began to increase toward the selected
takeoff thrust of 85%, as depicted in figure 1. The takeoff began with the flaps extended to 20°,
the pitch trim set at -4.8°, and the wing and cowl anti-ice systems engaged.
According to the CVR, at 1944:05, the copilot announced that the takeoff power was set and
that the airspeed indicator was functioning. At 1944:10, the copilot announced that the
airspeed was 80 knots indicated airspeed (KIAS). At 1944:18, the copilot announced that the
airplane had reached decision speed V1 (136 KIAS). However, according to the FDR, the
airplane was accelerating through 127 KIAS when the copilot made the V1 callout. At 1944:22,
the copilot announced that the airplane was at rotation speed VR (139 KIAS). According to the
FDR, at that time the airplane was accelerating through 140 KIAS and the nosewheel weighton-wheel indication changed from ground to air. At 1944:24, the left and right main landing
gear weight-on-wheel indications changed from ground to air.
At 1944:25, the airplane’s radio altitude was 6 ft, the pitch angle was about 13° nose-up, the
angle-of-attack (AOA) was about 19°, and the airplane roll was nearly level. About a second later, the airplane’s radio altitude was 11 ft, the pitch angle was about 11° nose-up, the airplane
was in a 1°-2° left roll, the AOA was about 20°, and both stick shakers independently activated
for about 1 second.
At 1944:27, the airplane’s radio altitude was 14 ft, the pitch angle was about 9° nose-up, the
AOA was about 16°, and the airplane transitioned from a left to a right roll. Despite the airplane
not being equipped (nor required) to record control wheel position, as the airplane’s right roll
increased the deflection of both ailerons increased to their respective limits, consistent with
full left-wing-down control wheel input.
At 1944:30, just before the FDR stopped recording, the airplane’s pitch angle was about 6°
nose-up and the bank angle was about 77° right-wing-down. Both stick shakers activated again
during the final second of recorded data. Although the radio altimeter indicated 31 ft, this
height value was likely affected by the roll angle.
A preliminary review of the FDR data did not reveal any evidence of a flight control malfunction
or failure, and both engines continued to develop takeoff power until the FDR recording
stopped.
There were multiple airport CCTV cameras that captured the airplane during the takeoff.
Several of these cameras showed the airplane impact the ground followed by multiple
explosions as the impact sequence progressed.
Evidence of the impact sequence began with a series of scrapes on the runway and fuel
residue, as depicted in figure 2. The scrape marks began about 5,808 ft from the approach end
of runway 33, 42 ft to the right of the runway centerline, and were generally orientated on a
338° magnetic heading. A wide area of fuel residue was observed with a shift in direction to
about 355° magnetic that extended about 57 ft near the right edge of the runway.
The airplane departed the right side of runway 33 into the grass runway safety area about 20°
right of the runway heading, as depicted in figure 3. The wreckage debris path consisted of the
right winglet and both winglet tips, windshield sections, the main entry door, several flight deck
components, and engine parts. The debris field was about 1,270 ft long and 150 ft wide. The
airplane came to rest upside down on a magnetic heading of 355°. The cockpit, cabin, and
empennage exhibited thermal damage consistent with a prolonged postimpact fire. The
fuselage, between the main entry door and wing root, exhibited damage consistent with airport
rescue and firefighting rescue efforts. The wings remained attached to the fuselage.
Photographs captured immediately after the accident showed the nose and main landing gear extended. The two turbofan engines remained partially attached to the pylons. Both engines
contained debris and a significant amount of firefighting foam and ice. There was no evidence
of a preimpact separation of any airplane component, flight control, or structure.
Holdover time is the estimated period for which deicing or anti-icing fluid will prevent the
accumulation of ice, snow or frost on an aircraft. According to the FAA Holdover Time
Guidelines for Winter 2025-2026, the corrected snowfall intensity associated with 3/4 sm
visibility at night and an outside temperature at or below -1°C was considered “moderate”, as
shown in Figure 4. Additionally, a “moderate” snowfall intensity and a -16°C outside
temperature resulted in a maximum holdover time of 9 minutes from the start of the anti-ice
application, as shown in Figure 5.
The airplane wreckage was recovered to a secure storage facility for further examination. As
part of the investigation, on-going activities include aircraft operations, aircraft performance,
flight recorders, airport operations, survival factors, and human performance. A transcript of
the CVR content applicable to the accident flight will be released as part of the investigation.
