In a few years, Genghis Kahn and his sons conquered the largest contiguous empire in history.
It is hard to quite explain the dramatic Mongol victories of the 13th century (the 1200s) over far larger armies of China, India, Russia, Bagdad, Germany, and Poland. Over 50 years or so, Genghis Kahn, an illiterate horseman with few troops built the largest contiguous empire in history, defeating far more advanced armies. The British empire was larger, but not contiguous, and they mostly fought less-trained armies than their own.
Most attempts to explain the victories talk about Mongol unity, an issue I treat elsewhere, but include comments to the effect that the Mongol bow worked better and sent an arrow further. Armed with better bows, the books and articles maintain, the Mongols could kill from a distance without fear of being killed. There is also a curious note by Weatherford (Genghis Khan and the Making of the Modern World) that the Mongol arrows could not be nocked in the Russian bows, but that Russian arrows were easily nocked in Mongol bows. At first glance these two sound contradictory, and bizarre. Let me try an explanation — one that seems to fit the physics — but first allow me to provide some background and reject some (all) the explanations I’d seen:
Force vs pull distance for several medieval bows, and a modern compound bow (blue). The longbow was better than the Mongol
There are several reasons to doubt that Mongol bows were better than the European, Moslem, and Chinese bows of the time. Most significantly, each Mongol made his own bow and his own arrows, or stole them, and that is a recipe for some very crude bows and some very un-straight arrows. Most countries had professional shops of bow makers and professional families of arrow makers. One person or guild made only arrow heads; others grew straight wood for arrows and bows; yet-others made finished bows, or added the feathers (fletching) to arrows. It is highly unlikely that a soldier could do anywhere near as well as this team of professionals. While it is possible that some arrows were better, it is far more likely that they were worse and that all were different, besides.
Books and web-sites also like to claim that the Mongol’s highly recurve (bent forward) bow was the key advantage. Recurve helps, but not much, and recurve also appears in the bows of the Moslems and Chinese. As the force-distance curve above shows, recurve bows provide, at most, 10% more energy than a straight bow other things being equal – arrow energy is related the area under the curve. This is far less advantage that with a modern compound bow (one with wheels– the blue curve above), and no 13th century culture had the modern compound bow. Recurve or not, the force-distance curve of a non-compound bow is a virtual straight line. Unless the Mongols had longer arms or stronger pulls, their arrows would go the same distance as everyone else’s, or would fall shorter because of lousy craftsmanship.
2. The nock issue. There are two ways this might work: a) that the Mongol bowstrings were narrower, e.g. silk instead of flax, or b) that the Mongol arrows were shorter. I’m willing to accept both answers. Either answer would explain how the Mongols could use European arrows while the Europeans were not able to nock the Mongol arrows. But these answers just make the range issue thornier. A silk string does not give you extra distance; a short arrow would decrease the shot-length. The energy given to the arrow is the integral. In a perfect world,
E = ∫fdx
E is the energy of the arrow, f is the force produced by the bow, and x is distance. Thus assuming no energy goes to the twanging of the bow, the energy of the arrow is equals the area under the force-distance curve, above. if the bow is unchanged, and the arrow is shortened, the draw distance will be shortened, and the range will be reduced.
The real reason that Mongol arrows went further, I suspect, has to do with the fact that the Mongols like to fire their arrows from horse-back, and I like to imagine from horse running towards the enemy at 25 to 35 mph. Now lets compare two archers. One, a standing archer (Russian, lets say) carries a 70 lb bow shooting a 100 gm arrow (2/9 lb) at 50% energy efficiency. I call this a 70 lb bow because the maximum force at the end of the pull is 70 lbs — more force than we use currently, but quite reasonable for medieval war where shot distance was the key to survival. Modern bows are approximately 80% efficient, but I take 50% efficiency just because wood (or bone for Mongols) isn’t as good as fiberglass in this regard, and leather bow strings are not as good as nylon.
I could solve the integral above for the arrow velocity and distance, using Euler’s approximation, but for now I’ll use a simpler approximation. For the above case, the average force is seen to be 35 lb (the force goes from 0 to 70 lbs), or 156 Nt. The energy in the arrow is then 1/2 156 x, where x is the pull distance, the draw. If we assume the draw is 1/2 m. the energy deposited is 39 joules and maximum speed of the arrow turns out to be 28 m/s, 63 mph.
v = √ (2)(.5)(39)/(.100) = 28 m/s.
The Mongol army was almost entirely cavalry archers.
The above suggests a flight time of about 8 seconds and a maximum range of 28 x 8 = 224 meters. This is about what you find with European bows. Now consider firing that same arrow from the back of a horse galloping at 32 mph, 19 m/s: The range for the same 8 second hang-time is now about 50% more, about 336 meters or 380 yards. If the riding Mongol released his arrows while going 32 mph, he would easily hit a standing archer 350 yards away, while the archer could not reach the Mongol. The only trick is the Mongol has to pull up before he reaches the 225 yard mark. Having a moving horse did more for the Mongol than having a better bow, better arrows, or a longer pull.
Robert Buxbaum, September 24, 2017 I’d mentioned Genghis Kahn in an essay about military statues. and felt compelled to come up with an explanation of how he won so much land, so fast, with so few men. Similar to my treatment of Mongol bows, I discuss aircraft carrier catapults.
I don’t understand how riding a horse would give your arrows more hang time.
Arrow velocity adds as a vector, while both energy and range scale with velocity squared. If you fire from galloping horseback, you can add about 20% to the arrow’s velocity, and about 44% to the arrow’s kinetic energy. Assuming you fire at 45° to the ground, that extra 44% will translate to an increase in arrow height of 44% (about) and a similar increase in range.
I have read that the draw weight of the mongolian bow was between 100 and 160lbs meaning, your assumption that the draw weight was the same as their European counterparts might be the flaw. A bunch of very strong, ripped Mongol warriors with huge draw weight bows would definitely outshoot bows with lighter pulls. Additionally, there are a few records of shots over 500ft which just wasn’t possible without a massive draw weight.
That sort of draw weight was typical of European, Asian, and African bows at the time. The bows of the Mary Rose were up to about 170 or 180 pounds in draw weight. The later Qing Dynasty in China (which kept careful records of what draw weights its archers were capable of using) had plenty of archers who used those draw weights. In fact, one of their archers managed to shoot a 240 pound bow once during a competition, though that is much higher than they would have used in battle since you want your archers to be using a draw weight they can shoot repeatedly,even when fatigued.
500 feet is also a rather short distance for flight archery. The English had regulations stating that flight arrows could not be used in practice at distances of less than 660 feet, while the Ottomans (masters of flight archery that they were) were shooting up to more than 2,700 feet. Of course, this was with specialized flight archery equipment, but their war bows and arrows were still hitting arrow speeds much higher than anything the Mongols would have managed, given their more aggressive siyah angles, shorter limbs, and lighter arrows.
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I am no expert on mongolian history or their crafting. My understanding is that when the tribes where seperate they did indeed make their own bows and own arrows. But no where have I found evidence that each individual made their own. Also, it is known that on a ride the tumans would try to recover and salvage arrows. But also the families would make arrows. Older warriors or those too maimed to maybe fight would combine their knowledge. Thus you would have fletchers. You would have metal smiths. And you would have bowyers.
Also, multiple tests have been done to compare the materials and design on mongolian archery equipment compared to Western Europe equipment. It is usually shown to be far superior. To date I believe it was a mongolian shot that was both furthest and struck a target.
I’m creating a physics course for homeschoolers and I want to give an example of computing energy based on a force vs displacement diagram. Could I use the Mongol Bow graph in your article cited here? http://www.rebresearch.com/blog/why-mongol-arrows-flew-further/
Sure. It’s as nice an example as any; the graph itself came from an archery site, though the analysis is mine. Depending on the grade, you might also include the idea that a moving frame of reference changes things. Good luck.
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