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These old documents on steel and iron manufacturing, are a valuable resource for our research. I have only searched for documents in the English language. I can't help but wonder if there may be similar resources that were published in French. If we could access and translate steel and iron publications in the French language, perhaps we could find more complete information on the materials used in Belgian barrels.

I know a gentleman in France who is a knifemaker, but who also worked in some of the museums in France. I plan to contact him to see if he can direct us to additional information.


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Steve: I bet there are some old hay rakes rusting in barns near you. A piece of tine might reflect c. 1900 steel?

There are some French resources here
https://docs.google.com/a/damascusknowle...zJ9Q/edit?pli=1

Last edited by Drew Hause; 05/01/14 04:04 PM.
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Drew,

I think that you are quite correct that we can learn a lot by examining items that were made during the 19th century. I really would like to see some items from Belgium.

BTW; I couldn't get the link in your last post to work.

Coincidentally, a friend of mine very recently made a knife from some parts from an old buggy. Below are a couple photos of the knife. You can clearly see the inclusions and banded layering of materials in the blade. The blade was etched slightly with ferric chloride to display these features.

The gentleman who made this knife is Master Bladesmith, Lin Rhea. Lin is the blacksmith at the Historic Arkansas Museum, in Little Rock. Below is Lin's own description of the knife and the materials used in making it.

I just finished a hunting knife made from 19th century buggy parts. The blade I forged from a small piece of the axle spring. The guard is a bit of the wrought iron tongue strap. The wood is the last scrap of the tongue that was not dry rotted.




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Hat's off to you Doc Drew for the digging in the old literature that you do, as well as the modern analysis. Though there seems to be mentions of best iron and steel, the description of the various scrap used and the experience that they could work with that material might suggest that it was not necessary to work with highly refined material.

I wonder if the images of the size and distribution of the inclusion in the damascus are a sort of benchmark fluid steel had to meet, cost effectively, to take over and exceed.

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Sorry guys - I corrected the link
https://docs.google.com/a/damascusknowle...zJ9Q/edit?pli=1

Relevant information. One can imagine that removing all the cast iron from the scrap simply by visual inspection would be an inexact process.

Appleton's Dictionary of Machines, Mechanics, Engine-work, and Engineering 1873
“It would be difficult to define what scrap iron is, or what it is not, being composed of everything in iron that has previously been manufactured, as well as of the cuttings from the various manufactories...”

The Gunsmith’s Manual; a complete Handbook for the American Gunsmith, Being a Practical Guide to All Branches of the Trade J.P Stelle & William B. Harrison 1883
“Best Materials for Gun Barrels”
The barrels of the finest and best guns, either Damascus, or other steel, or iron, are formed as made in Europe and England, of scraps of iron suited to the purpose, and selected with great skill and the greatest possible care. These scraps, which are usually bought up about the country, are placed in what is called a "shaking tub"-a vessel which is violently shaken and rocked about by machinery or otherwise(depending on the particular locality)for the purpose of scouring and brightening the scraps. This done, they are carefully picked over by adepts, who cull out the unsuitable pieces. So rigid is the culling that it often happens that out of a ton of scoured scraps not more than one hundred pounds weight of them are chosen as suitable for going into the best barrels.
Among the scraps usually thought to be best are old chains that have been used for many years, the wear and rust of time having left only the best elements of the iron. The Damascus steel, which has attained to so high a reputation, got it by being manufactured out of old coach springs. Of course it is not all made of coach springs now, but it was in years ago; agents then traveled all over the country hunting and buying them up, paying a much higher price for an old broken spring than a new one would cost it's owner.

Journal of The Federation of Insurance Institutes of Great Britain and Ireland, 1904, “Gun and Small-Arms Factories” by A.E. Patrick
“The iron for the manufacture of sporting gun barrels was formerly made from finest scrap iron, such as old horse-shoes, nail stubs and the like. In preparing the metal…a number of scraps were collected of various proportions, the clippings of saws, steel pens, and scraps of best iron, which were placed for some time in a shaking barrel for cleansing, and then hand picked, in order that any pieces which had the appearance of cast iron might be removed.”

The hay rake on my grandparent's place in Missouri is probably still there frown

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Drew--Still can't get your link to work.

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Sorry guys. The aliens that run Google decide to mess with my site once yearly apparently for their own entertainment frown

Try clicking on the Home Page
https://sites.google.com/a/damascusknowledge.com/www/home
then scroll down to Table of Contents and click on
Puraye's Le Damas & Documents Historiques Français et Belgique

Please let me know if that works.
As a last resort you may need to open the docs in Google Chrome smirk

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Drew,

These are indeed interesting documents. But, I have been looking for information that is a step back in the manufacturing process; that of the making of the iron and steel. Among my questions are; what where they speaking of when they used the words "iron" and "steel"? Terminology changes over time, so what was the understanding of these terms, contemporary to the manufacture of damascus barrels?

My next question is, from where did the steel and iron used in gun barrels originate? Was it primarily newly manufactured stock, or from scrap? Many sources indicate recycled scrap in the early years, changing to new stock later. When did this change occur? If the steel was of scrap carriage springs and scythe blades, where did the steel for the springs and blades originate?

In the early years of steel and iron manufacturing, the trace elements came primarily from the iron ore. There can be found analysis' of ore samples from different mines around the world. What mine did the ore come from to make the steel for carriage springs and scythe blades?

There are quite a number of old treatises that can be found on the manufacture of iron and steel. Most that I have found were written by British authors; since I have only searched in the English language. I would expect that similar works were written by French authors. The British documents include very good information, but I wonder if we could find more complete information on Belgian made barrels by looking into documents written closer to the region where they were made. As the French and Belgian firearms industries worked closely together, I think it possible that we could find valuable metallurgical information in French language documents. While most of the Belgian documentation may have been lost, there may be documents in France that consist of correspondence between their industries, as well as shared production techniques.

Essentially, I am looking to back into an analysis of the steel and iron in gun barrels by examining contemporary steel and iron production in that region of the world.

Below is a link to a very good metallurgical book from 1889.
A Treatice on the Metallurgy of Iron


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Maybe another viewpoint

Japanese swordsmithing
From Wikipedia, the free encyclopedia
This date March 2011 needs additional citations for verification. Please help improve this article by adding citations to reliable sources. Unsourced material may be challenged and removed. (March 2011)
Visual glossary of Japanese sword terms

Japanese swordsmithing is the labour-intensive bladesmithing process developed in Japan for forging traditionally made bladed weapons (nihonto)[1][2] including katana, wakizashi, tantō, yari, naginata, nagamaki, tachi, uchigatana, nodachi, ōdachi, kodachi, and ya (arrow).

Japanese sword blades were often forged with different profiles, different blade thicknesses, and varying amounts of grind. Wakizashi and tantō were not simply scaled-down katana; they were often forged without ridge (hira-zukuri) or other such forms which were very rare on katana.

Contents

1 Traditional methods
1.1 Steel production
1.2 Construction
1.2.1 Forging
1.2.2 Assembly
1.2.3 Geometry (shape and form)
1.2.4 Heat treating
1.3 Metallurgy
1.3.1 Metallography
1.4 Decoration
1.5 Polishing
1.6 Mountings
2 Modern swordsmithing
3 Commercial folded steel swords
4 Notable swordsmiths
5 See also
6 References
7 External links

Traditional methods
Steel production

The steel used is known as tamahagane (玉鋼:たまはがね?), or "jewel steel" (tama - ball or jewel, hagane - steel). Tamahagane is produced from iron sand, a source of iron ore, and mainly used to make Samurai swords, such as the katana, and some tools.
Diagram of a tatara and bellows

The smelting process used is different from the modern mass production of steel. A clay vessel about 4 ft (1.2 m) tall, 12 ft (3.7 m) long, and 4 ft (1.2 m) wide is constructed. This is known as a tatara. After the clay tub has set, it is fired until dry. A charcoal fire is started from soft pine charcoal. Then the smelter will wait for the fire to reach the correct temperature. At that point he will direct the addition of iron sand known as satetsu. This will be layered in with more charcoal and more iron sand over the next 72 hours. Four or five people need to constantly work on this process. It takes about a week to build the tatara and complete the iron conversion to steel. The steel is not allowed to become fully molten, and this allows both high and low carbon material to be created and separated once cooled. When complete, the Tatara is broken to remove the steel bloom, known as a kera. At the end of the process the tatara will have consumed about 10 short tons (9.1 t) of satetsu and 12 short tons (11 t) of charcoal leaving about 2.5 short tons (2.3 t) of kera, from which less than a ton of tamahagane can be produced.[3] A single kera can typically be worth hundreds of thousands of dollars, making it many times more expensive than modern steels.[4]
Tamahagane

The swordsmiths will carefully break the kera apart, and separate the various carbon steels. The lowest carbon steel is called hocho-tetsu, which is used for the shingane (translated as "core-steel") of the blade. The high carbon tamahagane and higher carbon steel, called nabe-gane, will then be forged in alternating layers, using very intricate methods to form the kawagane (or, "skin steel"). The most useful process is the folding, where the metals are forge welded, folded, and welded again, as many as 16 times. The folding removes impurities and helps even out the carbon content, while the alternating layers combine hardness with ductility to greatly enhance the toughness.[5][6][7] Currently, tamahagane is only made three or four times a year by Nittoho and Hitachi Metals[8] during winter in a wood building and is only sold to the master swordsmiths to use once it is made.
Construction

The forging of a Japanese blade typically took many days or weeks, and was considered a sacred art, traditionally accompanied by a large panoply of Shinto religious rituals.[9] As with many complex endeavors, rather than a single craftsman, several artists were involved. There was a smith to forge the rough shape, often a second smith (apprentice) to fold the metal, a specialist polisher, and even a specialist for the edge itself. Often, there were sheath, hilt, and tsuba specialists as well.
Forging
Katana made by folding, showing alternating layers.
Forge scenes, print from an Edo period book, Switzerland, Museum of Ethnography of Neuchâtel

The steel bloom, or kera, that is produced in the tatara contains steel that varies greatly in carbon content, ranging from wrought iron to pig iron. Three types of steel are chosen for the blade; a very low carbon steel called hocho-tetsu is used for the core of the blade, called the shingane. The high carbon steel, called tamahagane, and the remelted pig iron, called nabe-gane,[10] are combined to form the outer skin of the blade, called kawagane.[6][11][12] Only about 1/3 of the kera produces steel that is suitable for sword production.[13]

The best known part of the manufacturing process is the folding of the steel, where the swords are made by repeatedly heating, hammering and folding the metal. The process of folding metal to improve strength and remove impurities is frequently attributed to specific Japanese smiths in legend.

In traditional Japanese sword making, the low carbon hocho-tetsu is folded several times by itself, to purify it. This produces the soft metal, called shingane, to be used for the core of the blade. The high carbon tamahagane and the higher carbon nabe-gane are then forged in alternating layers. The nabe-gane is heated, quenched in water, and then broken into small pieces to help free it from slag. The tamahagane is then forged into a single plate, and the pieces of nabe-gane are piled on top, and the whole thing is forge welded into a single block, which is called the age-kitae process. The block is then elongated, cut, folded, and forge welded again. The steel can be folded transversely, (from front to back), or longitudinally, (from side to side). Often both folding directions are used to produce the desired grain pattern.[7] This process, called the shita-kitae, is repeated from 8 to as many as 16 times. After 20 foldings, (220, or about a million individual layers), there is too much diffusion in the carbon content, the steel becomes almost homogenous in this respect, and the act of folding no longer gives any benefit to the steel.[14] Depending on the amount of carbon introduced, this process forms either the very hard steel for the edge, called hagane, or the slightly less hardenable spring steel, called kawagane, which is often used for the sides and the back.[7]

During the last few foldings, the steel may be forged into several thin plates, stacked, and forge welded into a brick. The grain of the steel is carefully positioned between adjacent layers, with the exact configuration dependent on the part of the blade for which the steel will be used.[6]

Between each heating and folding, the steel is coated in a mixture of clay, water and straw-ash to protect it from oxidation and carburization. This clay provides a highly reducing environment. At around 1,650 °F (900 °C), the heat and water from the clay promote the formation of a wustite layer, which is a type of iron oxide formed in the absence of oxygen. In this reducing environment, the silicon in the clay reacts with wustite to form fayalite and, at around 2,190 °F (1,200 °C), the fayalite will become a liquid. This liquid acts as a flux, attracting impurities, and pulls out the impurities as it is squeezed from between the layers. This leaves a very pure surface which, in turn, helps facilitate the forge-welding process.[15][7][11] Due to the loss of impurities, slag, and iron in the form of sparks during the hammering, by the end of forging the steel may be reduced to as little as 1/10 of its initial weight.[16] This practice became popular due to the use of highly impure metals, stemming from the low temperature yielded in the smelting at that time and place. The folding did several things:
Blacksmith scene, print from an Edo period book, Museum of Ethnography of Neuchâtel, Switzerland.

It provided alternating layers of differing hardenability. During quenching, the high carbon layers achieve greater hardness than the medium carbon layers. The hardness of the high carbon steels combine with the ductility of the low carbon steels to form the property of toughness.[5][13]
It eliminated any voids in the metal.
It homogenized the metal, spreading the elements (such as carbon) evenly throughout - increasing the effective strength by decreasing the number of potential weak points.
It burned off many impurities, helping to overcome the poor quality of the raw Japanese steel.
It created up to 65000 layers, by continuously decarburizing the surface and bringing it into the blade's interior, which gives the swords their grain (for comparison see pattern welding).

Generally, swords were created with the grain of the blade (called hada) running down the blade like the grain on a plank of wood. Straight grains were called masame-hada, wood-like grain itame, wood-burl grain mokume, and concentric wavy grain (an uncommon feature seen almost exclusively in the Gassan school) ayasugi-hada. The difference between the first three grains is that of cutting a tree along the grain, at an angle, and perpendicular to its direction of growth (mokume-gane) respectively, the angle causing the "stretched" pattern. The blades that were considered the most robust, reliable, and of highest quality were those made in the Mino tradition, especially those of Magoroku Kanemoto. Bizen tradition, which specialized in mokume, and some schools of Yamato tradition were also considered strong warrior's weapons.[citation needed]
Assembly
Katana brique.png

In addition to folding the steel, high quality Japanese swords are also composed of various distinct sections of different types of steel. Known in China as bao gang 包钢 (literally "wrapped steel") since at least the Tang Dynasty, this manufacturing technique uses different types of steel in different parts of the sword to accentuate the desired characteristics in various parts of the sword beyond the level offered by differential tempering.[17]

The vast majority of modern katana and wakizashi are the maru (sometimes also called muku) type which is the most basic, with the entire sword being composed of one single steel. The kobuse type is made using two steels, which are called hagane (edge steel) and shingane (core steel). Honsanmai and shihozume types add the third steel, called kawagane (skin steel). There is almost an infinite number of ways the steel could be assembled, which often varied considerably from smith to smith.[6] Sometimes the hagane is "drawn out," (hammered into a bar), bent into a 'U' shaped trough, and the very soft shingane is inserted into the harder piece. Then they are forge welded together and hammered into the basic shape of the sword. By the end of the process, the two pieces of steel are fused together, but retain their differences in hardenability.[5][6] The more complex types of construction are typically only found in antique weapons, with the vast majority of modern weapons being composed of a single section, or at most two or three sections.

Another way is to assemble the different pieces into a block, forge weld it together, and then draw out the steel into a sword so that the correct steel ends up in the desired place.[7] This method is often used for the complex models, which allow for parrying without fear of damaging the side of the blade. To make honsanmai or shihozume types, pieces of hard steel are added to the outside of the blade in a similar fashion. The shihozume and soshu types are quite rare, but added a rear support.
Geometry (shape and form)
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A range of Japanese blade types, from left to right: Naginata, Tsurugi or ken, Tantō, Uchigatana and Tachi.

As Japan entered the Bronze Age, the swords found in Japan were very similar in shape to those found in continental Asia, i.e., China or Korea, and the Japanese adopted the Chinese convention for sword terminology along with metallurgy and swordmaking technology, classifying swords into the (either straight or curved) single-edged variety called tou 刀 and the (straight) double-edged variety called ken 剣. There is some small overlap in that there were some double-edged curved swords such as Tulwars or Scimitars which were called Tou, because the curvature meant that the "front" edge was used in the overwhelming majority of instances.

Over time, however, the curved single-edged sword became so dominant a style in Japan that tou and ken came to be used interchangeably to refer to swords in Japan and by others to refer to Japanese swords. For example, the Japanese typically refer to Japanese swords as 日本刀 nihontou ("Japanese tou" i.e. "Japanese (single-edged) blade"), while the character ken 剣 is used in such terms as kendo and kenjutsu. Modern formal usage often uses both characters in referring to a collection of swords, for example, in naming the The Japanese Sword Museum 日本美術刀剣博物館 .

The prototype of the Japanese sword was the chokuto 直刀, or "straight (single-edged) sword", a design that can be fairly described as a Japanese sword without any curvature, with a handle that is usually only a few inches long and therefore suitable for single-handed use only, with a sword guard that is prominent only on the front (where the edge is pointed) and back sides and sometimes only on the front side of the sword blade, and with a ring pommel. This design was moderately common in China and Korea during the Warring States and Han Dynasties, fading from popularity and disappearing during the Tang Dynasty. A number of such swords have been excavated in Japan from graves dating back to the kofun period.

As the chokuto evolved into the Japanese sword as it is known today[citation needed], it acquired its characteristic curvature and Japanese style fittings, including the long handle making it suitable for either one-handed or two-handed use, the non-protruding pommel, and a tsuba sword guard that protruded from the sword in all directions, i.e., that is not a cross piece or a guard for the edge or edge and back sides of the blade only but a guard intended to protect the hand on all sides of the blade. The shape of the Japanese tsuba evolved in parallel with Japanese swordsmithing and Japanese swordsmanship.[citation needed] As Japanese swordsmiths acquired the ability to achieve an extremely hard edge, Japanese swordsmanship evolved to protect the edge against chipping, notching, and breakage by parrying with the sides or backs of swords, avoiding edge-to-edge contact.[citation needed] This in turn resulted in the need to protect the sword hand from a sliding blade in parries on the sides and backs, i.e., parts of the blade other than the edge side, forming the rationale behind the Japanese styled tsuba[citation needed], which protrudes from the blade in every direction.

This style of parrying in Japanese swordsmanship has also resulted in some antique swords that have been used in battle exhibiting notches on the sides or backs of blades.[citation needed]
Heat treating
This section needs additional citations for verification. Please help improve this article by adding citations to reliable sources. Unsourced material may be challenged and removed. (May 2012)
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A katana, showing the hardened edge. The inset shows the nioi, which is the bright, wavy line following the hamon. The nioi is made up of niye, which are single martensite crystals surrounded by darker pearlite.
The curving of a katana as it cools at different rates.

Having a single edge also has certain advantages, one of the most important being that the entire rest of the sword can be used to reinforce and support the edge, and the Japanese style of sword making takes full advantage of this. When forging is complete, the steel is not quenched or tempered in the conventional European fashion (i.e.: uniformly throughout the blade). Steel’s exact flex and strength vary dramatically with heat treating. If steel cools quickly it becomes martensite, which is very hard but brittle. Slower and it becomes pearlite, which bends easily and does not hold an edge. To maximize both the cutting edge and the resilience of the sword spine, a technique (which originated in China during the first century BC) is used. In this process, referred to as differential hardening or differential quenching, the sword is painted with layers of clay before heating—the mixture being closely guarded trade secrets of the various smiths, but generally containing clay and coal ash as the primary ingredients—with a thin layer or none at all on the edge of the sword, ensuring quick cooling to maximize the hardening for the edge. A thicker layer of clay on the rest of the blade causes slower cooling and creates softer, more resilient steel, allowing the blade to absorb shock without breaking.[18][19] This process is sometimes erroneously called differential tempering[17] but this is actually an entirely different form of heat treatment.

When steel with a carbon content of 0.7 percent is heated beyond 750 degrees C it enters the "austenite phase". When austenite is cooled very suddenly by quenching in water the structure changes into "martensite", which is an extremely hard form of steel. When austenite is allowed to cool slowly its structure changes into a mixture of ferrite and cementite, called pearlite, which is much softer than martensite. To produce a difference in hardness, the steel is cooled at different rates by controlling the thickness of the insulating layer. By carefully controlling the heating and cooling of the blade, Japanese swordsmiths were able to produce a blade that had a softer body and a hard edge, creating a superior weapon.[20] This process also has two side effects that have come to characterize Japanese swords: First, it makes the edge of the blade, which cools quickly and forms evenly dispersed cementite particles embedded within a ferrite matrix (typical of tempered martensite). When quenched, the uninsulated edge contracts, causing the sword to bend towards the edge, but the edge cannot contract fully before the martensite forms, because the rest of the sword remains hot and in a thermally expanded state. Because of the insulation, the sword spine remains hot and pliable for several seconds, but then contracts much more than the edge, bending away from the edge and aiding the smith in establishing the curvature of the blade. Second, the differentiated hardness and the methods of polishing the steel can result in the hamon 刃紋 (frequently translated as "tempering line" but really better translated as "tempering pattern"). The hamon is used as a factor to judge both the quality and beauty of the finished blade. The various hamon patterns result from the manner in which the clay is applied, and can also act as an indicator of the style of sword-making, and sometimes also as a signature for the individual smith. The differences in the hardenability of steels may be enhanced near the hamon, revealing layers or even different parts of the blade, such as the intersection between an edge made from hagane and sides made from kawagane.[21][22]
Antique Japanese wakizashi sword blade showing the horimono of a chrysanthemum.

If the thickness of the coating on the edge is balanced just right with the temperature of the water, the proper hardness can be produced without the need for tempering. However, in most cases, the edge will end up being too hard, so tempering the blade for a short time is usually required to bring the hardness down to a more suitable point. The ideal hardness is usually between HRc58--60 on the Rockwell hardness scale. Tempering is performed by heating the entire blade evenly to around 400 °F (204 °C), reducing the hardness in the martensite and turning it into a form of tempered martensite. The pearlite, on the other hand, does not respond to tempering, and does not change in hardness.[23]
Metallurgy

Tamahagane, as a raw material, is a highly impure metal. Formed in a bloomery process, the kera of sponge iron begins as an inhomogeneous mixture of wrought iron, steels, and pig iron. The pig iron contains more than 2% carbon. The tamahagane has about 1 to 1.5% carbon while the hocho iron contains about 0.2%. Steel that has a carbon content between tamahagane and hocho iron is called bu-kera, which is often resmelted with the pig iron to make saga-hagane, containing roughly 0.7% carbon. Most of the bu-kera, hocho iron and saga-hagane will be sold for making other items, like tools and knives, and only the best pieces of tamahagane, hocho iron, and pig iron are used for swordsmithing.

The various metals are also filled with slag, phosphorus and other impurities. Separation of the various metals from the kera was traditionally performed by breaking it apart with small hammers dropped from a certain height, and then examining the fractures, in a process similar to the modern Charpy impact test. The nature of the fractures are different for different types of steel. The tamahagane, in particular, contains pearlite, which produces a characteristic pearlescent-sheen on the crystals.[24]

During the folding process, most of the impurities are removed from the steel, continuously refining the steel while forging. By the end of forging, the steel produced was some of the purest steel-alloys of the ancient world. Due to the continuous heating, a good quantity of carbon is either extracted from the steel as carbon dioxide or redistributed more evenly through diffusion, leaving a nearly eutectoid composition (containing 0.77 to 0.8% carbon).[25][26] The hagane itself will generally end up with a composition that ranges from eutectoid to slightly hypoeutectoid (containing a carbon content under the eutectoid composition), giving enough hardenability without sacrificing ductility[27] The shingane, however, remains nearly pure iron, responding very little to heat treatment.[28] Cyril Stanley Smith, a professor of metallurgical history from MIT, performed an analysis of four different swords, each from a different century, determining the composition of the surface of the blades:[29]

c. 1940s -- Carbon (edge) 1.02%, Carbon (body) 1.02%, Manganese 0.37%, Silicon 0.18%, Phosphorus 0.015%, Copper 0.21%

c. 1800s -- Carbon (edge) 0.62%%, Carbon (body) 0.1%, Manganese 0.01%, Silicon 0.07%, Phosphorus 0.046%, Copper 0.01%

c. 1700s -- Carbon (edge) 0.69%, Carbon (body) 0.43%, Manganese 0.005%, Silicon 0.02%, Phosphorus 0.075%, Copper 0.01%

c. 1500s -- Carbon (edge) 0.5%, Carbon (body) 0.5%, Manganese 0.005%, Silicon 0.04%, Phosphorus 0.034%, Copper 0.01%

In 1993, Jerzy Piaskowski performed an analysis of a katana of the kobuse type by cutting the sword in half and taking a cross section. The analysis revealed a carbon content ranging from 0.6 to 0.8% carbon at the surface, but only 0.2% at the core.[30][31]

The steel in even the ancient swords may have sometimes come from whatever steel was available at the time. Due to its rarity in the ancient world, steel was usually recycled, so broken tools, nails and cookwear often provided a ready supply of steel. Even steel looted from enemies in combat was often valued for its use in swordsmithing.[32]

According to Smith, the different layers of steel are made visible during the polishing due to one or both of two reasons: 1.) Either the layers have a variation in carbon content, or 2.) they have variation in the content of slag inclusions. When the variation is due to slag inclusions by themselves, there will not be a noticeable effect near the hamon, where the yakiba meets the hira. Likewise, there will be no appreciable difference in the local hardness of the individual layers. However, when the patterns occur from a difference in carbon content, there will be distinct indications of this near the hamon, because the steel with higher hardenability will become martensite beyond the hamon while the adjacent layers will turn into pearlite. This leaves a distinct pattern of bright "nioi," which appear as bright streaks or lines that follow the layers a short distance away from the hamon and into the hira, giving the hamon a wispy or misty appearance. The patterns were most likely revealed during the polishing operation by using a method similar to lapping, without bringing the steel to a full polish, although sometimes chemical reactions with the polishing compounds may have also been used to provide a level of etching. The differences in hardness primarily appear as a difference in the microscopic scratches left on the surface. The harder metal produces shallower scratches, so it diffuses the reflected light, while the softer metal has deeper, longer scratches, appearing either shiny or dark depending on the viewing angle. However, a difference in slag inclusions generally appear as layers that are somewhat pitted while the adjacent layers are not.[33]
Metallography

Metallurgy did not arise as a science until the early 1900s. Before this, metallography was the primary method used for studying metals. Metallography is the study of the patterns in metals, the nature of fractures, and the microscopic crystal-formations. However, neither metallography as a science nor the crystal theory of metals emerged until the invention of the microscope.[34] The ancient swordsmiths had no knowledge of metallurgy, nor did they understand the relationship between carbon and iron. Everything was typically learned by a process of trial-and-error, apprecticeship, and, as sword-making technology was often a closely guarded secret, some espionage. Prior to the 1300s, very little attention was paid to the patterns as an aesthetic quality. However, the Japanese smiths often prided themselves on their understanding of the internal macro-structure of metals.

In Japan, steel-making technology was imported from China, most likely through Korea. The steel used in the Chinese swords, called "chi-kang" (combined steel), was similar to pattern welding, and edges of it were often forge welded to a back of soft iron, or "jou thieh." In trying to copy the Chinese method, the ancient smiths paid much attention to the various properties of steel, and worked to combine them to produce an internal macro-structure that would provide a similar combination of hardness and toughness. Like all trial-and-error, each swordsmith often attempted to produce an internal structure that was superior to swords of their predecessors, or even ones that were better than their own previous designs.[35] The harder metals provided strength, like "bones" within the steel, whereas the softer metal provided ductility, allowing the swords to bend before breaking. The Japanese smiths, especially in ancient times, would often display these inhomogeneities in the steel, especially on fittings like the guard, creating rough, natural surfaces by letting the steel rust or by pickling it in acid, making the internal structure part of the entire aesthetic of the weapon.

In later times, this effect was often imitated by partially mixing various metals like copper together with the steel, forming mokume (wood-eye) patterns, although this was unsuitable for the blade itself. After the 1300s, more attention began to be paid to the patterns in the blade as an aesthetic quality. Intentionally decorative forging-techniques were often employed, such as hammering dents in certain locations, which served only to create a mokume pattern when the sword was filed and polished into shape, or by intentionally forging-in layers of high slag content. By the 1600s, decorative hardening methods were often being used to increase the beauty of the blade, by shaping the clay. Hamons with trees, flowers, pill boxes, or other shapes became common during this era. By the 1800s, the decorative hamons were often being combined with decorative folding-techniques to create entire landscape-portraits, often portraying specific islands or scenery, crashing waves in the ocean, and misty mountain-peaks.[36]
Decoration
A section of an antique Japanese katana showing two grooves hi and the temper line hamon.

Almost all blades are decorated, although not all blades are decorated on the visible part of the blade. Once the blade is cool, and the mud is scraped off, the blade has designs and grooves cut into it. One of the most important markings on the sword is performed here: the file markings. These are cut into the tang, or the hilt-section of the blade, where they will be covered by a hilt later. The tang is never supposed to be cleaned: doing this can cut the value of the sword in half or more. The purpose is to show how well the blade steel ages. A number of different types of file markings are used, including horizontal, slanted, and checked, known as ichi-monji, ko-sujikai, sujikai, ō-sujikai, katte-agari, shinogi-kiri-sujikai, taka-no-ha, and gyaku-taka-no-ha. A grid of marks, from raking the file diagonally both ways across the tang, is called higaki, whereas specialized "full dress" file marks are called kesho-yasuri. Lastly, if the blade is very old, it may have been shaved instead of filed. This is called sensuki. While ornamental, these file marks also serve the purpose of providing an uneven surface which bites well into the tsuka, or the hilt which fits over it and is made from wood. It is this pressure fit for the most part that holds the tsuka in place during the strike, while the mekugi pin serves as a secondary method and a safety.

Some other marks on the blade are aesthetic: signatures and dedications written in kanji and engravings depicting gods, dragons, or other acceptable beings, called horimono. Some are more practical. The so-called "blood groove" or fuller does not in actuality allow blood to flow more freely from cuts made with the sword,[37] but is simply to reduce the weight of the sword while keeping structural integrity and strength.[37] Grooves come in wide (bo-hi), twin narrow (futasuji-hi), twin wide and narrow (bo-hi ni tsure-hi), short (koshi-hi), twin short (gomabushi), twin long with joined tips (shobu-hi), twin long with irregular breaks (kuichigai-hi), and halberd-style (naginata-hi).
Polishing
Japanese sword blade, sharpening stone, and water bucket at the 2008 Cherry Blossom Festival, Seattle Center, Seattle, Washington.
For more details on this topic, see Japanese sword polishing.

When the rough blade is completed, the swordsmith turns the blade over to a polisher called a togishi, whose job it is to refine the shape of a blade and improve its aesthetic value. The entire process takes considerable time, in some cases easily up to several weeks. Early polishers used three types of stone, whereas a modern polisher generally uses seven. The modern high level of polish was not normally done before around 1600, since greater emphasis was placed on function over form. The polishing process almost always takes longer than even crafting, and a good polish can greatly improve the beauty of a blade, while a bad one can ruin the best of blades. More importantly, inexperienced polishers can permanently ruin a blade by badly disrupting its geometry or wearing down too much steel, both of which effectively destroy the sword's monetary, historic, artistic, and functional value.
Mountings
For more details on this topic, see Japanese sword mountings.

In Japanese, the scabbard for a katana is referred to as a saya, and the handguard piece, often intricately designed as an individual work of art — especially in later years of the Edo period — was called the tsuba. Other aspects of the mountings (koshirae), such as the menuki (decorative grip swells), habaki (blade collar and scabbard wedge), fuchi and kashira (handle collar and cap), kozuka (small utility knife handle), kogai (decorative skewer-like implement), saya lacquer, and tsuka-ito (professional handle wrap, also named emaki), received similar levels of artistry.

After the blade is finished it is passed on to a mountings-maker, or sayashi (literally "Sheath Maker" but referring to those who make fittings in general). Sword mountings vary in their exact nature depending on the era, but generally consist of the same general idea, with the variation being in the components used and in the wrapping style. The obvious part of the hilt consists of a metal or wooden grip called a tsuka, which can also be used to refer to the entire hilt. The hand guard, or tsuba, on Japanese swords (except for certain twentieth century sabers which emulate Western navies') is small and round, made of metal, and often very ornate. (See koshirae.)

There is a pommel at the base known as a kashira, and there is often a decoration under the braided wrappings called a menuki. A bamboo peg called a mekugi is slipped through the tsuka and through the tang of the blade, using the hole called a mekugi-ana ("peg hole") drilled in it. This anchors the blade securely into the hilt. To anchor the blade securely into the sheath it will soon have, the blade acquires a collar, or habaki, which extends an inch or so past the hand guard and keeps the blade from rattling.

The sheaths themselves are not an easy task. There are two types of sheaths, both of which require exacting work to create. One is the shirasaya, which is generally made of wood and considered the "resting" sheath, used as a storage sheath. The other sheath is the more decorative or battle-worthy sheath which is usually called either a jindachi-zukuri, if suspended from the obi (belt) by straps (tachi-style), or a buke-zukuri sheath if thrust through the obi (katana-style). Other types of mounting include the kyū-guntō, shin-guntō, and kai-guntō types for the twentieth-century military.

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Joined: Jan 2006
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RESULTS ARE IN! And many thanks again to all who donated barrel segments, esp. Dennis Potter. I'm saving some of the good stuff for the article but:
1. The findings were remarkably consistent
After discarding the highest and lowest mean:
Twist - 53,300 psi
Crolle - 54,500 psi

2. Four 125 year old samples, Twist and Damascus Twist - 51,500 psi. I guess the mythical delaminating, rusting welds and voids don't really weaken Pattern Welded barrels over time smile

3. As Steve Culver predicted, the JABC Twist barrels were just as strong as the crolle samples.

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