Bladesmiths outline which carbon steel combos they use and why.
Damascus steel is a broad category with nearly infinite variations. It includes everything from low-layer random patterns to powdered canister creations and complex mosaic patterns.
The basics of damascus include forge-welded combinations of steels. Changes in the steel choices, in the welding or forging processes, and even in the etching method result in a wide variety of patterns and looks. Let’s dive into the many levels of damascus through the work of a few excellent smiths.
Smiths Takes On Damascus Steels
ABS apprentice smith Chris McPherson began making knives only four years ago, but he had a strong start attending classes taught by ABS master smiths Jason Knight and Josh Fisher. Now he forges his own damascus. One of his fighters (IMAGE 1) features a blade of 1075 carbon and 15N20 nickel-alloy steels.
“I made the knife for a local state trooper benefit, for the teenage son of an officer who lost his life in the line of duty in March 2023,” Chris explained. When asked about why he chose 1075 for his fighter, he said he “just wanted to try it out” after making other billets with 1095, 1084 and 1080 carbon steels. Though he’d heard that the 1075 may have a bit less contrast due to its lower manganese levels, it came out with beautiful contrast after a deeper etch.
Knifemaker Brian Sellers likes to mix things up a bit. In addition to the standard carbon steels of 1095 or 1084, Sellers occasionally includes 1080, 5160 or 52100. “Adding a third steel to damascus gives a unique depth to the finished blade, kind of like adding shades of gray to a tattoo,” he says. For example, in a recent Persian fighter (IMAGE 2), Sellers included 1080 and 5160 along with 15N20 in a ladder pattern blade. Brian indicated all the steels work well with his equipment. He uses a 50-ton Riverside hydraulic press and a 50-pound Little Giant power hammer.
Damascus is time and labor intensive, and the maker loses a good bit of the steel in the forging process. Bladesmith Blake Nichols knows this and is from the “waste not, want not” school of thought.
“My mentor Greg Shahan gave me the end cut of a feather damascus billet a few years ago,” Nichols said. “It sat on my shelf for a long time before I incorporated it into [one of my] hunters.”
Regarding his damascus, he added, “I wish I had a profound scientific answer as to why I use 15N20 and 1095 but I do not. The simple answer is it’s what I learned on. I’m comfortable with the heat-treating process. I also feel like I get the performance out of that combination that I desire.” I agree with Nichols when he said, “No matter what it’s made of, it has to function like a knife. Even the fancy ones need to hold up to the performance standards.”
Why 15N20 In Damascus?
You may have noticed one thing the featured bladesmiths all have in common: they include 15N20 in their damascus billets. The 15N20 is a simple carbon steel, basically 1075, but has a relatively large amount of a special ingredient: nickel. The nickel content makes 15N20 etch more slowly and show more brightly when polished. Because of the similar composition to the 10-series steels (1080, 1084, etc.), it welds well and hardens in similar temperatures, making it the perfect steel for high contrast in the damascus pattern.
Some smiths use pure nickel foil or sheet in their damascus for the same effect. The challenge is that the pure nickel won’t harden, so it must be kept away from the edge in the forging process. The contrast is great but the nickel itself won’t hold an edge. I like a nickel layer in between layers of san-mai or go-mai damascus. It really pops!
Bladesmith Robert Wayman illustrates the go-mai technique well on one of his kitchen knives (IMAGE 3). The blade was made from a patterned go-mai billet. There’s a core layer running down the center of the blade with two layers of material on each side. The core is 100-layer random pattern damascus forged from 1084 and 15N20. On each side of the core steel is a layer of nickel and on the outside of the billet is a layer of matching random pattern damascus.
Key Element Comparisons by Steel
Steel | 1084 | 1075 | 1095 | 15N20 | 1080 | 5160 | 52100 |
C | .865 | .750 | 1.000 | .750 | .75-.88 | .60 | .98-1.10 |
Mn | .750 | .550 | .450 | .375 | .06-.09 | .80 | .24-.45 |
N | — | — | .200 | 1.950 | — | — | — |
Once the final billet is forge welded, some of the cladding material is removed with a grinder to create a visual effect in the pattern, and then the billet is drawn out to length. Keeping the core material centered during the process is very important. “You want to take your time when laying out your billet,” Wayman advised. “I typically use a thicker core material and a thinner cladding material, but it’s definitely taken some time and practice to dial it in.”
Other Damascus Steels
Before 15N20 and 10-series combos became prevalent for damascus, one of the standard high-contrast combinations was O1 and L6 tool steels. While the latter combo makes great damascus, the two steels are harder to find in today’s market. Simply put, properly sized and affordable 15N20 and 10-series steels are much more available than all the other combos on the market.
Copper is another material that has caught on in the forging of copper-mai and other forms of copper damascus. Outfits like Baker Forge specialize in the process in which the copper is often clad over a standard carbon steel damascus core, as the copper itself won’t harden.
Titanium alloys have been pattern welded, often called Timascus™, and can be anodized in an array of wild colors. Unfortunately, it’s difficult to produce and doesn’t harden, so Timascus blades are probably not in your future. Instead, Timascus makes a great folder frame, bolsters and other non-blade knife parts.
What Metals To Avoid
Are there any materials that don’t make a great contrasting damascus? Sellers reports that the “S” series high silicon steels like S5 and S7 don’t work. He speculated that it was either the steel composition or improper heat control, but welds of S5 and S7 don’t stick during forging.
I can attest that meteorite is a tempting addition to damascus because various samples are often high in nickel and mostly made of iron. Unfortunately, every meteorite varies widely in terms of content, so that individual pieces of the same meteorite each may have a very different chemical composition. As another confounding factor, many meteorites contain high silicon or other elements besides iron, carbon and nickel. Each new element adds its own problems to the process.
I was able to produce a satisfactory pair of billets containing some meteorite by putting small chunks in a canister with 1084 powder, and then welding and re-stacking the billet with more 1084 bar stock until the final layer count was over 1,000. By adding only 1084, I was assured that any bright spots in the final pattern were from the nickel in the meteorite. Even with this process, there were a few inclusions/flaws in the final product. Could I have continued to push the layer count and minimized the flaws further? We’ll never know.
Some may think AEBL stainless steel is nice and shiny. Can it or another stainless steel be put in the mix with carbon steel? If you think that “shiny” makes sense for high contrast, that part is true. Unfortunately, the high chromium in stainless steels causes problems for damascus makers in two ways. First, chromium steels don’t like to weld together. The chromium oxidizes quickly and prevents the welds from sticking. Second, the chromium changes the hardening properties. In a hypothetical AEBL and 1084 billet, the AEBL hardens from 1,900°F while the 1084 hardens from 1,500°F. If you quench the hypothetical billet from 1,900°F, the 1084 will have huge, brittle grain. If you quench the same billet from 1,500°F, the AEBL won’t harden.
While there are smiths who have figured out how to weld multiple types of stainless steel together in contrasting patterns, the process requires careful and precise heating and mitigation of oxygen, both procedures which are often beyond the scope of the backyard smith. Because of the complex process required to make it, stainless damascus commands premium prices.
Final Cut
Modern damascus retains strong demand in the knife market. By combining a choice of several standard carbon steels and 15N20, smiths can create damascus patterns that will make any knife stand out. Whether the pattern is random or ladder, raindrop or mosaic and more, a high-quality damascus knife is sure to be a winner.
More On Damascus:
- Spectacles In Steel: A Look At Definitive Damascus Patterns
- Stainless Damascus: Challenges In Forging
- Damascus: Mass Producing The Unique Knife Material
- Copper Damascus: An Exciting New Way To Make Knives
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