etching darkens the 1080 plain
carbon steel more than it does the 15N20
low alloy nickel steel, producing alternating bands of light and dark on the surface. Pattern welding developed out of the necessarily complex process of making blades that were both
hard and
tough from the erratic and unsuitable output from early iron smelting in
bloomeries. The bloomery does not generate temperatures high enough to melt iron and steel, but instead
reduces the
iron oxide ore into particles of pure
iron, which then weld into a mass of
sponge iron, consisting of lumps of impurities in a matrix of relatively pure iron, which is too soft to make a good blade.
Carburizing thin iron bars or plates forms a layer of harder, high carbon steel on the surface, and early bladesmiths would forge these bars or plates together to form relatively homogeneous bars of steel. This laminating process, in which different types of steel together produce patterns that can be seen in the surface of the finished blade, forms the basis for pattern welding.
Pattern welding in Europe Pattern welding dates to the first millennium BC, with Celtic, and later Germanic swords exhibiting the technique, with the Romans describing the blade patternation. By the 2nd and 3rd century AD, the
Celts commonly used pattern welding for decoration in addition to structural reasons. The technique involves folding and forging alternating layers of steel into rods, then twisting the steel to form complex patterns when forged into a blade. By the 6th and 7th centuries, pattern welding had reached a level where thin layers of patterned steel were being overlaid onto a soft iron core, making the
swords far better as the iron gave them a flexible and springy core that would take any shock from sword blows to stop the blade bending or snapping. By the end of the
Viking Age, pattern welding fell out of use in Europe. In medieval swords, pattern welding was more prevalent than commonly thought. However, the presence of rust makes detection difficult without repolishing. During the
Middle Ages,
Wootz steel was produced in
India and exported globally, including to Europe. The similarities in the markings led many to believe it was the same process being used, and pattern welding was revived by European smiths who were attempting to duplicate the
Damascus steel. The methods used by Indian smiths to produce their Wootz steel was lost over the centuries. The ancient swordmakers exploited the
aesthetic qualities of pattern welded steel. The
Vikings, in particular, were fond of twisting bars of steel around each other, welding the bars together by hammering and then repeating the process with the resulting bars, to create complex patterns in the final steel bar. Two bars twisted in opposite directions created the common
chevron pattern. Often, the center of the blade was a core of soft steel, and the edges were solid high carbon steel, similar to the laminates of the Japanese.
Modern decorative use Pattern welding is still popular with contemporary bladesmiths both for visual effect and for recreating historic patterns and swords. Modern steels and methods allow for patterns with much higher number of visible layers compared to historical artifacts. Large numbers of layers can either be produced by folding similar to historical processes or by forge welding a small number of layers together, then cutting the billet in pieces to stack and forge-weld it again. This can be repeated until the desired number of layers have been achieved. A blade ground from such a blank can show a pattern similar to wood grain with small random variations in pattern. Some manufactured objects can be re-purposed into pattern welded blanks. "Cable Damascus", forged from high carbon multi-strand cable, is a popular item for bladesmiths to produce, producing a finely grained, twisted pattern, while
chainsaw chains produce a pattern of randomly positioned blobs of color. Some modern bladesmiths have taken pattern welding to new heights, with elaborate applications of traditional pattern welding techniques, as well as with new technology. A layered billet of steel rods with the blade blank cut perpendicular to the layers can also produce some spectacular patterns, including
mosaics or even writing.
Powder metallurgy allows alloys that would not normally be compatible to be combined into solid bars. Different treatments of the steel after it is ground and polished, such as
bluing, etching, or various other chemical surface treatments that react differently to the different metals used can create bright, high-contrast finishes on the steel. Some master smiths go as far as to use techniques such as
electrical discharge machining to cut interlocking patterns out of different steels, fit them together, then weld the resulting assembly into a solid block of steel. Blacksmiths will sometimes apply
Wite-Out,
Liquid Paper, or other types of correction fluid to metal that they do not want to weld together, as the
titanium dioxide in the correction fluid forms a barrier between the metal it is applied-to and any other pieces of metal. For example, when creating pattern-welded steel by filling a steel canister with pieces of metal and powdered steel and forging it together into a single mass ("canister damascus steel,") smiths frequently coat the inside of the canister with correction fluid and let it dry before adding their materials. Thus, when the canister is
heated and compressed using a hammer or pneumatic press, the material on the inside of the correction fluid is forged together, but it does not forge to the canister, allowing the pattern created by forging the different materials together to be seen in the finished piece because it is not covered by the homologous steel of the canister. ==Etymology==