Static electricity hypothesis
Hugo Eckener argued that the fire was started by an electric spark which was caused by a buildup of static electricity on the airship. The spark ignited hydrogen on the outer skin.
Proponents of the static spark hypothesis point out that the airship's skin was not constructed in a way that allowed its charge to be distributed evenly throughout the craft. The skin was separated from the duralumin frame by non-conductive ramie cords which had been lightly covered in metal to improve conductivity but not very effectively, allowing a large difference in potential to form between the skin and the frame.
In order to make up for the delay of more than 12 hours in its transatlantic flight, the Hindenburg passed through a weather front of high humidity and high electrical charge. Although the mooring lines were not wet when they first hit the ground and ignition took place four minutes after, Eckener theorised that they may have become wet in these four minutes. When the ropes, which were connected to the frame, became wet, they would have grounded the frame but not the skin. This would have caused a sudden potential difference between skin and frame (and the airship itself with the overlying air masses) and would have set off an electrical discharge – a spark. Seeking the quickest way to ground, the spark would have jumped from the skin onto the metal framework, igniting the leaking hydrogen.
In his book LZ-129 Hindenburg (1964), Zeppelin historian Douglas Robinson commented that although ignition of free hydrogen by static discharge had become a favored hypothesis, no such discharge was seen by any of the witnesses who testified at the official investigation into the accident in 1937. He continues:
But within the past year, I have located an observer, Professor Mark Heald of Princeton, New Jersey, who undoubtedly saw St. Elmo's Fire flickering along the airship's back a good minute before the fire broke out. Standing outside the main gate to the Naval Air Station, he watched, together with his wife and son, as the Zeppelin approached the mast and dropped her bow lines. A minute thereafter, by Mr. Heald's estimation, he first noticed a dim "blue flame" flickering along the backbone girder about one-quarter the length abaft the bow to the tail. There was time for him to remark to his wife, "Oh, heavens, the thing is afire," for her to reply, "Where?" and for him to answer, "Up along the top ridge" – before there was a big burst of flaming hydrogen from a point he estimated to be about one-third the ship's length from the stern.
Unlike other witnesses to the fire whose view of the port side of the ship had the light of the setting sun behind the ship, Professor Heald's view of the starboard side of the ship against a backdrop of the darkening eastern sky would have made the dim blue light of a static discharge on the top of the ship more easily visible.
Harold G. Dick was Goodyear Zeppelin's representative with Luftschiffbau Zeppelin during the mid-1930s. He flew on test flights of the Hindenburg and its sister ship, the Graf Zeppelin II. He also flew on numerous flights in the original Graf Zeppelin and ten round-trip crossings of the north and south Atlantic in the Hindenburg. In his book The Golden Age of the Great Passenger Airships Graf Zeppelin & Hindenburg, he observes:
There are two items not in common knowledge. When the outer cover of the LZ 130 [the Graf Zeppelin II] was to be applied, the lacing cord was prestretched and run through dope as before but the dope for the LZ 130 contained graphite to make it conductive. This would hardly have been necessary if the static discharge hypothesis were mere cover-up. The use of graphite dope was not publicized and I doubt if its use was widely known at the Luftschiffbau Zeppelin.
In addition to Dick's observations, during the Graf Zeppelin II's early test flights, measurements were taken of the airship's static charge. Ludwig Durr and the other engineers at Luftschiffbau Zeppelin took the static discharge hypothesis seriously and considered the insulation of the fabric from the frame to be a design flaw in the Hindenburg. Thus, the German Inquiry concluded that the insulation of the outer covering caused a spark to jump onto a nearby piece of metal, thereby igniting the hydrogen. In lab experiments, using the Hindenburg's outer covering and a static ignition, hydrogen was able to be ignited but with the covering of the LZ 127 Graf Zeppelin, nothing happened. These findings were not well-publicized and were covered up, perhaps to avoid embarrassment of such an engineering flaw in the face of the Third Reich.
A variant of the static spark hypothesis, presented by Addison Bain, is that a spark between inadequately grounded fabric cover segments of the Hindenburg itself started the fire, and that the doping compound of the outer skin was flammable enough to be ignited before hydrogen contributed to the fire. The Hindenburg had a cotton skin covered with a finish known as "dope". It is a common term for a plasticized lacquer that provides stiffness, protection, and a lightweight, airtight seal to woven fabrics. In its liquid forms, dope is highly flammable, but the flammability of dry dope depends upon its base constituents, with, for example, butyrate dope being far less flammable than cellulose nitrate. Proponents of this hypothesis claim that when the mooring line touched the ground, a resulting spark could have ignited the dope in the skin. However, the validity of this theory has been contested.
An episode of the Discovery Channel series Curiosity entitled "What Destroyed the Hindenburg?", which first aired in December 2012, investigated both the static spark theory and St. Elmo's Fire, as well as sabotage by bomb. The team, led by British aeronautical engineer Jem Stansfield and US airship historian Dan Grossman, concluded that the ignition took place above the hydrogen vent just forward of where Mark Heald saw St. Elmo's Fire, and that the ignited hydrogen was channeled down the vent where it created a more explosive detonation described by crew member Helmut Lau.
An episode of the PBS series Nova titled Hindenburg: The New Evidence, which first aired in April 2021 on SBS in Australia, focuses on the static electricity hypothesis. It confirms that the Hindenburg's fabric outer skin and metal air-frame were, by design, electrically isolated from each other (via air gaps between skin and frame), and finds that although this may have been done with safety in mind, it likely put the airship at greater risk for the type of accident that occurred. It also finds that there likely was a leak of hydrogen gas at the Hindenburg's stern, as evidenced by the difficulty the crew had in bringing the airship in trim prior to the landing (its aft was too low). The episode also features laboratory experiments, conducted by Konstantinos Giapis of Caltech, designed to explain how the fatal spark occurred. Through them Dr. Giapis demonstrates the effects of rainy weather on representations of the airship's skin, air-frame and a landing rope — and successfully generates sparks between skin and frame. As Giapis notes, when its landing ropes were cast to the ground, the Hindenburg had a significant electrical charge (many thousands of volts with respect to ground), due to its altitude, about 300 feet (91 m), and to stormy weather conditions. Although these ropes, made of Manila hemp, would have become more electrically conductive as they absorbed falling rain, Giapis finds the ropes would have conducted electricity even when dry, effectively grounding the airship the instant they touched earth. But even as the voltage of the airship's frame dropped, the voltage at its outer skin would have remained largely unchanged, due to its isolation from the rest of the airship. Thus, the voltage difference between frame and skin would have grown dramatically, greatly increasing the risk of a spark. Yet, significantly, the fire didn't erupt until four minutes later, raising the question of what could account for such a delay. From his experiments, Dr. Giapis theorizes that during the landing, the Hindenburg behaved like a capacitor — actually an array of them — in an electrical circuit. (In his analogy, one of the two conductive plates of each "capacitor" is represented by a panel of the airship's charged outer skin, the other plate by the grounded portion of the airship.) Further, Giapis finds that the Cellon dope painted on the fabric skin acted like a capacitor's dielectric, increasing the skin's ability to hold charge beyond what it held before the airship became grounded — which he says would explain the delay in spark formation. Once the ropes dropped, charge would continue building on the skin and, according to his calculations, the additional time required to produce a spark would be slightly under four minutes, in close agreement with the investigation report. Giapis believes that there were likely many sparks occurring on the airship at the time of the accident, and that it was one near the hydrogen leak that triggered the fire. Additionally, he demonstrates experimentally that rain was a necessary component of the Hindenburg disaster, showing that the airship's skin would not have conducted electricity when dry, but that adding water to the skin increases its conductivity, allowing electric charge to flow through it, setting off sparks across gaps between skin and frame.
Lightning hypothesis
A. J. Dessler, former director of the Space Science Laboratory at NASA's Marshall Space Flight Center and a critic of the incendiary paint hypothesis (see below), favors a much simpler explanation for the conflagration: lightning. Like many other aircraft, the Hindenburg had been struck by lightning several times in its years of operation. This does not normally ignite a fire in hydrogen-filled airships due to the lack of oxygen. However, airship fires have been observed when lightning strikes the vehicle as it vents hydrogen as ballast in preparation for landing. The vented hydrogen mixes with the oxygen in the atmosphere, creating a combustible mixture. The Hindenburg was venting hydrogen at the time of the disaster.
However, witnesses did not observe any lightning storms as the ship made its final approach.
Engine failure hypothesis
On the 70th anniversary of the accident, The Philadelphia Inquirer carried an article[49] with yet another hypothesis, based on an interview of ground crew member Robert Buchanan. He had been a young man on the crew manning the mooring lines.
As the airship was approaching the mooring mast, he noted that one of the engines, thrown into reverse for a hard turn, backfired, and a shower of sparks was emitted. After being interviewed by Addison Bain, Buchanan believed that the airship's outer skin was ignited by engine sparks. Another ground crewman, Robert Shaw, saw a blue ring behind the tail fin and had also seen sparks coming out of the engine. Shaw believed that the blue ring he saw was leaking hydrogen which was ignited by the engine sparks.
Eckener rejected the idea that hydrogen could have been ignited by an engine backfire, postulating that the hydrogen could not have been ignited by any exhaust because the temperature is too low to ignite the hydrogen. The ignition temperature for hydrogen is 500 °C (932 °F), but the sparks from the exhaust only reach 250 °C (482 °F). The Zeppelin Company also carried out extensive tests and hydrogen had never ignited. Additionally, the fire was first seen at the top of the airship, not near the bottom of the hull.
Fire's initial fuel
Most current analyses of the fire assume ignition due to some form of electricity as the cause. However, there is still much controversy over whether the fabric skin of the airship, or the hydrogen used for buoyancy, was the initial fuel for the resulting fire.
Static spark hypothesis
The theory that hydrogen was ignited by a static spark is the most widely accepted theory as determined by the official crash investigations. Offering support for the hypothesis that there was some sort of hydrogen leak prior to the fire is that the airship remained stern-heavy before landing, despite efforts to put the airship back in trim. This could have been caused by a leak of the gas, which started mixing with air, potentially creating a form of oxyhydrogen and filling up the space between the skin and the cells. A ground crew member, R.H. Ward, reported seeing the fabric cover of the upper port side of the airship fluttering, "as if gas was rising and escaping" from the cell. He said that the fire began there, but that no other disturbance occurred at the time when the fabric fluttered. Another man on the top of the mooring mast had also reported seeing a flutter in the fabric as well. Pictures that show the fire burning along straight lines that coincide with the boundaries of gas cells suggest that the fire was not burning along the skin, which was continuous. Crew members stationed in the stern reported actually seeing the cells burning.
Two main theories have been postulated as to how gas could have leaked. Eckener believed a snapped bracing wire had torn a gas cell open, while others suggest that a maneuvering or automatic gas valve was stuck open and gas from cell 4 leaked through. During the airship's first flight to Rio, a gas cell was nearly emptied when an automatic valve was stuck open, and gas had to be transferred from other cells to maintain an even keel. However, no other valve failures were reported during the ship's flight history, and on the final approach there was no indication in instruments that a valve had stuck open.
Although some opponents of this theory claim that the hydrogen was odorized with garlic, it would have been detectable only in the area of a leak. Once the fire was underway, more powerful odors would have masked any garlic scent. No reports of anyone smelling garlic during the flight surfaced and no official documents have been found to prove that the hydrogen was even odorized.
Opponents of this hypothesis note that the fire was reported as burning bright red, while pure hydrogen burns blue if it is visible at all, although many other materials were consumed by the fire which could have changed its hue.
Some of the airship-men at the time, including Captain Pruss, asserted that the stern heaviness was normal, since aerodynamic pressure would push rainwater towards the stern of the airship. The stern heaviness was also noticed minutes before the airship made its sharp turns for its approach (ruling out the snapped wire theory as the cause of the stern heaviness), and some crew members stated that it was corrected as the ship stopped (after sending six men into the bow section of the ship). Additionally, the gas cells of the ship were not pressurized, and a leak would not cause the fluttering of the outer cover, which was not seen until seconds before the fire. However, reports of the amount of rain the ship had collected have been inconsistent. Several witnesses testified that there was no rain as the ship approached until a light rain fell minutes before the fire, while several crew members stated that before the approach the ship did encounter heavy rain. Albert Sammt, the ship's first officer who oversaw the measures to correct the stern-heaviness, initially attributed to fuel consumption and sending crewmen to their landing stations in the stern, though years later, he would assert that a leak of hydrogen had occurred. On its final approach the rainwater may have evaporated and may not completely account for the observed stern-heaviness, as the airship should have been in good trim ten minutes after passing through rain. Eckener noted that the stern heaviness was significant enough that 70,000 kilogram·meter (506,391 foot-pounds) of trimming was needed.
Incendiary paint hypothesis
The incendiary paint theory (IPT) was proposed in 1996 by retired NASA scientist Addison Bain, stating that the doping compound of the airship was the cause of the fire, and that the Hindenburg would have burned even if it were filled with helium. The hypothesis is limited to the source of ignition and to the flame front propagation, not to the source of most of the burning material, as once the fire started and spread the hydrogen clearly must have burned (although some proponents of the incendiary paint theory claim that hydrogen burned much later in the fire or that it otherwise did not contribute to the rapid spread of the fire). The incendiary paint hypothesis asserts that the major component in starting the fire and feeding its spread was the canvas skin because of the compound used on it.
Proponents of this hypothesis argue that the coatings on the fabric contained both iron oxide and aluminum-impregnated cellulose acetate butyrate (CAB) which remain potentially reactive even after fully setting. Iron oxide and aluminum can be used as components of solid rocket fuel or thermite. For example, the propellant for the Space Shuttle solid rocket booster included both "aluminum (fuel, 16%), (and) iron oxide (a catalyst, 0.4%)". The coating applied to the Hindenburg's covering did not have a sufficient quantity of any material capable of acting as an oxidizer, which is a necessary component of rocket fuel, however, oxygen is also available from the air.
Bain received permission from the German government to search their archives and discovered evidence that, during the Nazi regime, German scientists concluded the dope on the Hindenburg's fabric skin was the cause of the conflagration. Bain interviewed the wife of the investigation's lead scientist Max Dieckmann, and she stated that her husband had told her about the conclusion and instructed her to tell no one, presumably because it would have embarrassed the Nazi government. Additionally, Dieckmann concluded that it was the poor conductivity, not the flammability of the doping compound, that led to the ignition of hydrogen. However, Otto Beyersdorff, an independent investigator hired by the Zeppelin Company, asserted that the outer skin itself was flammable. In several television shows, Bain attempted to prove the flammability of the fabric by igniting it with either an open flame or a Jacob's Ladder machine. Although Bain's fabric ignited, critics argue that Bain had to correctly position the fabric parallel to a machine with a continuous electric current inconsistent with atmospheric conditions. In response to this criticism, the IPT therefore postulates that a spark would need to be parallel to the surface, and that "panel-to-panel arcing" occurs where the spark moves between panels of paint isolated from each other. Astrophysicist Alexander J. Dessler points out a static spark does not have sufficient energy to ignite the doping compound, and that the insulating properties of the doping compound prevents a parallel spark path through it. Additionally, Dessler contends that the skin would also be electrically conductive in the wet and damp conditions before the fire.
Critics also argue that port side witnesses on the field, as well as crew members stationed in the stern, saw a glow inside Cell 4 before any fire broke out of the skin, indicating that the fire began inside the airship or that after the hydrogen ignited, the invisible fire fed on the gas cell material. Newsreel footage clearly shows that the fire was burning inside the structure.
Proponents of the paint hypothesis claim that the glow is actually the fire igniting on the starboard side, as seen by some other witnesses. From two eyewitness statements, Bain asserts the fire began near cell 1 behind the tail fins and spread forward before it was seen by witnesses on the port side. However, photographs of the early stages of the fire show the gas cells of the Hindenburg's entire aft section fully aflame, and no glow is seen through the areas where the fabric is still intact. Burning gas spewing upward from the top of the airship was causing low pressure inside, allowing atmospheric pressure to press the skin inwards.
Occasionally, the Hindenburg's varnish is incorrectly identified as, or stated being similar to, cellulose nitrate which, like most nitrates, burns very readily. Instead, the cellulose acetate butyrate (CAB) used to seal the zeppelin's skin is rated by the plastics industry as combustible but nonflammable. That is, it will burn if placed within a fire but is not readily ignited. Not all fabric on the Hindenburg burned. For example, the fabric on the port and starboard tail fins was not completely consumed. That the fabric not near the hydrogen fire did not burn is not consistent with the "explosive" dope hypothesis.
The TV show MythBusters explored the incendiary paint hypothesis. Their findings indicated that the aluminum and iron oxide ratios in the Hindenburg's skin, while certainly flammable, were not enough on their own to destroy the zeppelin. Had the skin contained enough metal to produce pure thermite, the Hindenburg would have been too heavy to fly. The MythBusters team also discovered that the Hindenburg's coated skin had a higher ignition temperature than that of untreated material, and that it would initially burn slowly, but that after some time the fire would begin to accelerate considerably with some indication of a thermite reaction. From this, they concluded that those arguing against the incendiary paint theory may have been wrong about the airship's skin not forming thermite due to the compounds being separated in different layers. Despite this, the skin alone would burn too slowly to account for the rapid spread of the fire, as it would have taken four times the speed for the ship to burn. The MythBusters concluded that the paint may have contributed to the disaster, but that it was not the sole reason for such rapid combustion.
Puncture hypothesis
Although Captain Pruss believed that the Hindenburg could withstand tight turns without significant damage, proponents of the puncture hypothesis, including Hugo Eckener, question the airship's structural integrity after being repeatedly stressed over its flight record.
The airship did not receive much in the way of routine inspections even though there was evidence of at least some damage on previous flights. It is not known whether that damage was properly repaired or even whether all the failures had been found. During the ship's first return flight from Rio, Hindenburg had once lost an engine and almost drifted over Africa, where it could have crashed. Afterwards, Eckener ordered section chiefs to inspect the airship during flight. However, the complexity of the airship's structure would make it virtually impossible to detect all weaknesses in the structure. In March 1936, the Hindenburg and the Graf Zeppelin made three-day flights to drop leaflets and broadcast speeches via loudspeaker. Before the airship's takeoff on March 26, 1936, Ernst Lehmann chose to launch the Hindenburg with the wind blowing from behind the airship, instead of into the wind as per standard procedure. During the takeoff, the airship's tail struck the ground, and part of the lower fin was broken. Although that damage was repaired, the force of the impact may have caused internal damage. Only six days before the disaster, it was planned to make the Hindenburg have a hook on her hull to carry aircraft, similar to the US Navy's use of the USS Akron and the USS Macon airships. However, the trials were unsuccessful as the biplane hit the Hindenburg's trapeze several times. The structure of the airship may have been further affected by this incident.
Newsreels, as well as the map of the landing approach, show that the Hindenburg made several sharp turns, first towards port and then starboard, just before the accident. Proponents posit that either of these turns could have weakened the structure near the vertical fins, causing a bracing wire to snap and puncture at least one of the internal gas cells. Additionally, some of the bracing wires may have even been substandard. One bracing wire tested after the crash broke at a mere 70% of its rated load. A punctured cell would have freed hydrogen into the air and could have been ignited by a static discharge, or it is also possible that the broken bracing wire struck a girder, causing sparks to ignite hydrogen. When the fire started, people on board the airship reported hearing a muffled detonation, but outside, a ground crew member on the starboard side reported hearing a crack. Some speculate the sound was from a bracing wire snapping.
Eckener concluded that the puncture hypothesis, due to pilot error, was the most likely explanation for the disaster. He held Captains Pruss and Lehmann, and Charles Rosendahl responsible for what he viewed as a rushed landing procedure with the airship badly out of trim under poor weather conditions. Pruss had made the sharp turn under Lehmann's pressure; while Rosendahl called the airship in for landing, believing the conditions were suitable. Eckener noted that a smaller storm front followed the thunderstorm front, creating conditions suitable for static sparks.
During the US inquiry, Eckener testified that he believed that the fire was caused by the ignition of hydrogen by a static spark:
The ship proceeded in a sharp turn to approach for its landing. That generates extremely high tension in the after part of the ship, and especially in the center sections close to the stabilizing fins which are braced by shear wires. I can imagine that one of these shear wires parted and caused a rent in a gas cell. If we will assume this further, then what happened subsequently can be fitted in to what observers have testified to here: Gas escaped from the torn cell upwards and filled up the space between the outer cover and the cells in the rear part of the ship, and then this quantity of gas which we have assumed in the hypothesis was ignited by a static spark.
Under these conditions, naturally, the gas accumulated between the gas cells and the outer cover must have been a very rich gas. That means it was not an explosive mixture of hydrogen, but more of a pure hydrogen. The loss of gas must have been appreciable.
I would like to insert here, because the necessary trimming moments to keep the ship on an even keel were appreciable, and everything apparently happened in the last five or six minutes, that is, during the sharp turn preceding the landing maneuver, that therefore there must have been a rich gas mixture up there, or possibly pure gas, and such gas does not burn in the form of an explosion. It burns off slowly, particularly because it was in an enclosed space between outer cover and gas cells, and only in the moment when gas cells are burned by the burning off of this gas, then the gas escapes in greater volume, and then the explosions can occur, which have been reported to us at a later stage of the accident by so many witnesses.
The rest it is not necessary for me to explain, and in conclusion, I would like to state this appears to me to be a possible explanation, based on weighing all of the testimony that I have heard so far.
However, the apparent stern heaviness during the landing approach was noticed thirty minutes before the landing approach, indicating that a gas leak resulting from a sharp turn did not cause the initial stern heaviness.
Fuel leak
The 2001 documentary Hindenburg Disaster: Probable Cause suggested that 16-year-old Bobby Rutan, who claimed that he had smelled "gasoline" when he was standing below the Hindenburg's aft port engine, had detected a diesel fuel leak. During the investigation, Commander Charles Rosendahl dismissed the boy's report. The day before the disaster, a fuel pump had broken during the flight, but the chief engineer testified that the pump had been replaced. The resulting vapor of a diesel leak, in addition to the engines being overheated, would have been highly flammable and could have self-combusted.
However, the documentary makes numerous mistakes into assuming that the fire began in the keel. First, it implies that the crewmen in the lower fin had seen the fire start in the keel and that Hans Freund and Helmut Lau looked towards the front of the airship to see the fire, when Freund was actually looking rearward when the fire started. Most witnesses on the ground reported seeing flames at the top of the ship, but the only location where a fuel leak could have a potential ignition source is the engines. Additionally, while investigators in the documentary suggest it is possible for a fire in the keel to go unnoticed until it breaks the top section, other investigators such as Greg Feith consider it unlikely because the only point diesel comes into contact with a hot surface is the engines.
Rate of flame propagation
Regardless of the source of ignition or the initial fuel for the fire, there remains the question of what caused the rapid spread of flames along the length of the airship, with debate again centered on the fabric covering of the airship and the hydrogen used for buoyancy.
Proponents of both the incendiary paint hypothesis and the hydrogen hypothesis agree that the fabric coatings were probably responsible for the rapid spread of the fire. The combustion of hydrogen is not usually visible to the human eye in daylight, because most of its radiation is not in the visible portion of the spectrum but rather ultraviolet. Thus what can be seen burning in the photographs cannot be hydrogen. However, black-and-white photographic film of the era had a different light sensitivity spectrum than the human eye, and was sensitive farther out into the infrared and ultraviolet regions than the human eye. While hydrogen tends to burn invisibly, the materials around it, if combustible, would change the color of the fire.
The motion picture films show the fire spreading downward along the skin of the airship. While fires generally tend to burn upward, especially including hydrogen fires, the enormous radiant heat from the blaze would have quickly spread fire over the entire surface of the airship, thus apparently explaining the downward propagation of the flames. Falling, burning debris would also appear as downward streaks of fire.
Those skeptical of the incendiary paint hypothesis cite recent technical papers which claim that even if the airship had been coated with actual rocket fuel, it would have taken many hours to burn – not the 32 to 37 seconds that it actually took.
Modern experiments that recreated the fabric and coating materials of the Hindenburg seem to discredit the incendiary fabric hypothesis. They conclude that it would have taken about 40 hours for the Hindenburg to burn if the fire had been driven by combustible fabric. Two additional scientific papers also strongly reject the fabric hypothesis. However, the MythBusters Hindenburg special seemed to indicate that while the hydrogen was the dominant driving force the burning fabric doping was significant with differences in how each burned visible in the original footage.
The most conclusive proof against the fabric hypothesis is in the photographs of the actual accident as well as the many airships which were not doped with aluminum powder and still exploded violently. When a single gas cell explodes, it creates a shock wave and heat. The shock wave tends to rip nearby bags which then explode themselves. In the case of the Ahlhorn disaster on January 5, 1918, explosions of airships in one hangar caused the explosions of others in three adjoining hangars, wiping out all five Zeppelins at the base.
The photos of the Hindenburg disaster clearly show that after the cells in the aft section of the airship exploded and the combustion products were vented out the top of the airship, the fabric on the rear section was still largely intact, and air pressure from the outside was acting upon it, caving the sides of the airship inward due to the reduction of pressure caused by the venting of combustion gases out the top.
The loss of lift at the rear caused the airship to nose up suddenly and the back to break in half (the airship was still in one piece), at that time the primary mode for the fire to spread was along the axial gangway which acted as a chimney, conducting fire which burst out the nose as the airship's tail touched the ground, and as seen in one of the most famous pictures of the disaster.
Memorial
The actual site of the Hindenburg crash is at the Lakehurst Naval entity of Joint Base McGuire–Dix–Lakehurst. It is marked with a chain-outlined pad and bronze plaque where the airship's gondola landed. It was dedicated on May 6, 1987, the 50th anniversary of the disaster. Hangar No. 1, which still stands, is where the airship was to be housed after landing. It was designated a National Historic Landmark in 1968. Pre-registered tours are held through the Navy Lakehurst Historical Society.
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