8-28-2021

Spyderco Mule Team list

Most of this information is taken from the descriptions on the Spyderco website. I find these valuable short summaries of the different steels, and was afraid that someday they would just vanish due to some whim. All credit to Spyderco.

I find these descriptions to be unique and insightful, worth reading by anyone interested in knife steels.

MT1 in 52100

52100 is a high carbon steel used primarily for ball bearings. It has a good amount of carbon (0.98 - 1.10) and very few other alloys. Ball bearing steels usually have to withstand a great deal of force in a very small area. Traditionally, ball bearing steels make good edge steels because an edge also has to withstand much force in a small area. 52100 serves that function well.

Oil quenched and drawn to Rc 62, it is a difficult steel to heat treat. A very fine molecular structure permits very sharp edges, even at thin angles. Toughness is good, corrosion resistance isn't. It is not a stainless steel and will have to be cared for.

My comments here. I missed this early mule, but this is a very interesting steel. As a ball bearing steel it is a very refined carbon steel. It will rust easily, but this has not been an issue for me (I now have the PM2 in 52100). The following are some comments by EvilD on the Spyderco forums:

Something I've noted in using and sharpening mine is what I like to call "repeatable results". Any steel I've owned and used, I can get to my desired sharpness eventually and one way or another. Some of them are more finicky than others and need more attention and your technique needs to be spot on. With this steel, I've had the easiest time getting repeatable sharpness every time on the Sharpmaker. I have yet to reach a point where I've struggled to get it to that level of sharpeness I'm looking for.

Maybe something of note, is that for whatever reason I can't seem to reach that level with just the brown stones. Someone here mentioned in the first 52100 discussion thread, in so many words, that people would need to brush up on their sharpening techniques and really work to get this steel sharp because you won't have carbides to rely on for cutting ability. This makes sense, because to get it as sharp as I want it, I have to use the white rods every time. I can get it very sharp on the browns, sharp enough to slice any type of paper and shave, but when I put it on the fine and then super fine rods it kicks it way up into the "tree topping hairs" sharpness where it will catch and cut free hanging hairs without touching your skin at all.

There definitely seems to be a difference between 52100 and something like the S##V steels that perform well with ~400-600 grit edges. This steel seems to really excel at higher polish edges and I would suspect that anyone who takes the time to polish the edge up to a mirror finish will be rewarded with a ridiculously sharp edge. I haven't put mine on the Edge Pro yet but when I do I'll be polishing the edge for sure.

Another note for those interested is that I haven't stropped this knife one time. I'm not into the idea of maintaining an edge with just a strop, and it's so sharp coming off the super fine rods that I haven't bothered even trying to see what a couple passes on leather will do. Before I take it to the Edge Pro I'll probably play around with some diamond paste and see how that goes.

MT2 in CPM M4

CPM M4 is a high-speed, wear resistant, tool steel. It is non-stainless steel. Its high content of Molybdenum and Tungsten gives it a fine grain size, greater strength, hardness and toughness. It is a triple temper heat treat to make it as tough as possible without brittleness. The grinding combined with the triple temper heat treating process can cause warping up to 50 thousandths (.050) of an inch which is not enough to affect the performance of the knife. CPM M4 will provide high edge retention and impact resistance with an Rc of 58-63, you'll also find it's relatively easy to sharpen.

MT3 in S90V

CPM S90V is not a new steel, but it is one not commonly used in the knife industry. It is a high carbon stainless steel formerly known as CPM 420V. With 2.3% carbon it offers wicked edge retention and higher tensile strength. It has more than twice the Vanadium than CPM S30V, providing greater wear resistance. CPM S90V may be uncommon in our industry due to it's strength, hardness and toughness; all things that can prove to be difficult in a production atmosphere. Given the extreme wear resistance, it proved to be difficult to grind, the steel didn't want to "give" or "let go" of molecules. Although frustrating in production, this characteristic speaks to what can be expected in edge retention.

MT4 in ZDP-189

In 2009 ZDP-189 blade steel was the hottest, hardest and highest performing Japanese knife steel in the knife industry. 3% of its component ingredient is pure carbon and 20% chrome (unheard of chemistries twenty-years ago), making the steel harder and in turn extending its edge retention. This is done through a powdered metallurgic process. At the time of MT04P Mule's release, Spyderco was one of a handful of cutlers around the world working with ZDP-189 blades.

MT04P ZDP-189 Mule was originally released in a very limited quantity due to unforeseen issues. The Mule Team project was created to give more people access to various steels using a standard pattern for a fixed blade knife. The hope of the project was to find out what these steels can do by making them available at an affordable price for our Knife Knuts and Steel Junkies. We test our products constantly, but we’ve always maintained that no amount of “testing” can provide the information that real-world use can.

With the ZDP-189 Mule our goal was to reach the optimal hardness that we had in our folders (in 2009 as well as presently). Shortly after the release of MT04P it was discovered that the optimal hardness is different for a fixed blade. Once this was discovered Spyderco placed a hold on shipping any additional MT04P Mules.

The Mule Team is a project based upon the desire to learn more about different types of steel and the performance of each steel. The scenario with the MT04P Mule, although not planned, certainly provided some previously unknown and valuable information into one of our industry’s most exotic steels.

MT5 in 9Cr18Mo

This was a $20 item, made in China! Sorry I missed it.

9Cr18Mo is a premium ingot high-carbon steel. In our experience it's the best knife steel being produced in China today. The name is derived from its component elements: .9% carbon, 18% chromium and 1% molybdenum. With controlled heat treat and tempering it reaches a HRc of 58-62. Before its entry into the knife industry it was widely used for high-end Chinese barbering scissors, roller bearings and surgical tools due to its corrosion resistance and high processing quality. The application of 9Cr18Mo to knife manufacturing opens up another steel option for high-end knife manufacturers and their high-end knife enthusiasts alike. The addition of a 9Cr18Mo Spyderco Mule fleshes out the series further by offering users the opportunity to evaluate and test drive a high-performance steel from yet another country.

MT6 in S35VN

Crucible Steel in NY created CPM S30V as steel developed specifically to be used for knife blades. A first, and the knife industry appreciates such purpose built efforts.

Shortly after the introduction of CPM S30V, Chris Reeve (of Chris Reeve Knives) began working with Dick Barber, a metallurgist at Crucible Steel (at the time). The goal was to create an even better version of the steel that had better machinability and finish. After several years of testing and development, the result was CPM S35VN. Chemically the same as S30V, but with the additional of Niobium (also referred to as Columbium).

High Chromium ferritic steels containing Niobium exhibit increased temperature stability and refined grain structure which is important when working hard steels used in items like jet and rocket engines, welding and knife blades. It increases a blade's strength and ability to take and retain sharpness.

Crucible worked with a few makers to test and refine the steel. Production began on CPM S35VN just before changes were made in the Crucible business model. At this time, there is still question as to whether this fine steel will be in production. Spyderco was fortunate to be able to grab some while it was still available and this Mule Team model is the result of that opportunity.

CPM S35VN is exotic in its chemistry, even for powdered steels. This is an opportunity for some to be able to play with this new evolution to blade steel.

(The general word is that this is virtually indistinguishable from S30V for the end user, but is somewhat easier to machine for the knife maker.)

MT7 in Damascus

These sold for $85. In the English language the term mule has multiple definitions: There's the obvious equine reference being the offspring of a male donkey and a female horse. It can be a coin minted from two dies by mistake and the auto industry refers to their test vehicles as a mules. Spyderco also calls knife models designed and built for testing and evaluation Mules. When a group of these are brought together they make a team of mules, thus the name of our new knife release: The Mule Team.

Knife and steel-devotees love trying out new blade steels. Spyderco leads the industry in offering, testing and manufacturing knives using new and exotic blade steels. Taking that idea a step up, why not offer a series (team) of blades using different, exotic and freshly unveiled steels? In doing this steel-obsessed knife knuts can try, test and use something normally not offered to the industry.

Spyderco's Damascus Mule Team is a laminated fifteen-layer steel with a Suminagashi pattern. The Damascus Mule's steel is composed of layers of erosive and non-erosive material over a VG-10 core center. The erosive layers are hard martensite stainless steel and the non-erosive layers are anti-corrosion nonferrous metal. These layers block carbon particles in the core from spreading to the outer layers. After layering the blade is forged to intentionally distort the layer-lines making a complicated, artistically beautiful pattern called Suminagashi. Suminagashi is the traditional Japanese art form of creating ripples of Chinese ink on the surface of water. This steel mimics the art form with interesting results on a knife blade. Once the layers are distorted, the blade is bathed in acid, etching the pattern to vivid relief.

MT8 in Aogami Super Blue

Aogami Super Blue steel is produced exclusively by Hitachi Metals for tools and knives. In Hitachi's plant in the Shimane Prefecture, Japan, they use high quality iron-sand found only in this region. Shimane Prefecture sand has been used and preferred for making Japanese cutlery since ancient times. Hitachi creates and offers different grades of steels including white steels and blue steels. The steel isn't blue or white but the designation refers to the color of the paper the raw steel is wrapped in when delivered to Hitachi. It is common practice for Japanese steels to be named and referred to; based on what colored packaging the raw steel arrives to the maker. Super Blue is the highest grade blue steel and contains up to 1-1/2% carbon for wear resistance and chrome to elevate hardness and improve edge holding and corrosion resistance. Steel smiths agree Super Blue is easier to heat-treat and work with than some steels but is more wear resistant and harder to hand grind. Classified as exotic steel by cutlery standards, it has a loyal following with custom kitchen knifemakers looking for superior cutting performance for cutting materials that are soft and sticky to rock hard or fibrous.

MT9 in Cobalt special

Takefu is a premier Japanese steel company specializing in the production of steels used for household and industrial cutlery. They produce blades using clad steel. Clad steels are a composite of different metals some hard, some softer, fused or bonded to each other. Pairing different steel types together elevates performance by combining the best characteristics of each material and where the steels overlay each other, a fine Hamon or line develops. Traditional Japanese swords featured clad steels, layering tough harder steel with softer bendable ones which resulted in a steel combination that made them difficult to break or bend. Spyderco's MT09 Mule Team is Takefu's Cobalt Special steel enveloped within slices of SUS420J2. The two steels laminated as one boost toughness, improve corrosion resistance and generate lasting sharpness in a blade that is relatively easy to sharpen.

MT10 in CTS BD1

High-performance American-made blade steels are propelling the quality and performance of today's knives to new and higher levels. A U.S.A company called Carpenter Steel recently entered the knife making arena, cutlery people noticed. Carpenter isn't a newcomer to alloy manufacturing just a new-neighbor in the community of blade steel manufacturing and they're launching a new family of alloys called CTS' steels specifically for cutlery. One of those is CTS BD1.

CTS BD1 is patterned on Gingami I (also known as G2), the gold-standard for Japanese cutlerers. Its superior edge retention and surface finish are machined to a fine edge and it heat-treats consistently. From a performance standpoint, it's a winner and it's used in Spyderco's latest Mule Team fixed blade. The CTS BD1 Mule is a limited 500-piece run with a sharpened PlainEdge cutting edge.

MT11 in M390

The Austrian's Bohler Group merged with Sweden's Uddeholm Steel Works in 1991, creating the world's largest tool steel manufacturer, Bohler Uddeholm. Specializing in aviation/aerospace and automotive steels, they also produce tool steels used in the manufacture of consumer goods including electronics and cutlery. Through a powdered metallurgy processes, they produce M390 Microclean steel which is highly sought and well suited to today's high-performance cutlery. M390 is a martensitic chromium steel highly resistant to corrosion. The powdered granules of Chromium and Vanadium in the steel are small, consistently sized, and finely dispersed in the steel's matrix (mix) making it exceptionally homogenous. This means for the consumer cutting with M390 will experience a high-level wear and corrosion resistance and the blade steel can be polished to a mirror-like finish.

MT12 in Cruwear

This blade was somewhat less expensive, $60.

Upstate New York's Crucible Steel manufacturers Cru-Wear which is very similar to Vascowear, a steel used by Gerber Legendary Blades in many of their past production knives.

Cru-Wear is a high-performance "V" tool steel that is difficult to process making it challenging for knife manufacturers to work with. It follows the same high-alloy, metallurgical tool-steel recipe used to produce D2, but with greater levels of vanadium, tungsten, and molybdenum. It is air-hardened and worked in a cold state. Cru-Wear exhibits exceptional toughness, impact resistance, and hardness for exceptional edge retention and is the first tool steel offering in Spyderco's Mule Team Series.

MT13 in Elmax

Elmax steel is produced by Böhler-Uddeholm Steel of Kapfenberg, Austria.

Böhler first sold steel in North America in 1925 by providing European-made steels to toolmakers, manufacturing industries and construction jobs in the U.S. Their Elmax is an alloy composed using powdered metallurgic technology that was designed specifically for high-tech applications, primarily for use in the electronics industry. It contains elevated levels of chromium, vanadium-molybdenum that deem it a well-tailored fit for making knife blades. These elements translate into resistance to wear and corrosion and it has a homogenous grain structure making it malleable when grinding and forming.

MT14

There ain't no 14. This was going to be CTS 204P. One rumor is that the batch of CTS 204P they got that would have been used for the mules had some kind of problem. This was back in 2012.

MT15 in CTS B75P

It is made with CTS B75P powdered steel produced by Carpenter Steel of Reading, Pennsylvania U.S.A.

Carpenter’s CTS B75P is comparable in elemental composition to BG42 blade steel but is produced using a powdered steel manufacturing process rather cast steel construction. Powdered steel manufacturing renders the ingredients and carbides making up the steel’s structure more consistent in grain size to each other and homogenize the steel. For the knife user this translates into a high-performance knife steel with exceptional wear and corrosion resistance and long term edge retention. CTS B75P’s hard vanadium carbides further augment its wear resistance and edge retention making it the new knife steel that production knife companies and custom knifemakers are excited to use.

The Carpenter MT15 CTS B75P Mule is a limited-piece run with a sharpened PlainEdge cutting edge.

MT16 in CTS XHP

CTS XHP powdered steel is produced exclusively by Carpenter Steel Corporation of Reading, Pennsylvania U.S.A.

CTS XHP is air hardened, high carbon, high chromium, corrosion resistant blade steel. It exhibits exceptional hardness similar to that found in tool steels such as D2, but also offers corrosion resistance on par with high chromium stainless steels like Type-440C.

The powdered steel manufacturing process renders the steel’s ingredients and its carbides with a more consistent grain size. When grains are similar sized, the result is a more homogenized steel structure. For the person cutting with the blade this translates into higher-performing knife steel that has exceptional wear and corrosion resistance and long lasting edge retention. CTS XHP contains hard vanadium carbides further augmenting its hardness level to produce a keenly sharp cutting edge and surface finish. Even exposed to moisture, petroleum products and organic materials it exhibits exceptional corrosion resistance.

MT17 in K390

It is made from K390 steel produced by the Böhler steel company, headquartered in Vienna, Austria.

K390 is a powdered metallurgy, cold work tool steel with 9% vanadium and added tungsten and cobalt for excellent wear resistance and high compressive strength that is a workhorse in even the most severe applications.

The carbides in the K390 mix are fine in texture and the steel’s remaining components are uniformly sized and distributed evenly throughout the matrix. This equal distribution of elements adds to the overall strength and cutting capacity when the blade is finished and sharpened.

MT18 in S110V

CPM S110V blade steel is produced using a CPM - Crucible Particle Metallurgy process developed by Crucible Industries of Solvay, New York, U.S.A.

What differentiates CPM S110V from other blade steels is its volume of vanadium-rich (9.0%) and niobium-rich (3.0%) alloys which classify it as a martensitic stainless tool steel. Crucible’s powdered metal process creates uniform carbide distribution of the steel’s components throughout the blade for superior wear resistance, toughness and corrosion protection. These are positive performance characteristics highly desired in state-of-the-art exotic blade steels.

MT19 in PSF27

PSF27 is a tool steel produced using the Spray Forming Process. Spray forming—also known as spray casting or spray deposition—begins by melting an alloy steel in an induction furnace. The molten steel is then poured through a ceramic nozzle and broken up into droplets by an array of gas jets. The droplets are accelerated by the jets to impact onto a collection surface while still in a semi-solid condition. There they build up to form a spray-formed billet, assuming the shape of the substrate surface. The small size and rapid cooling of the droplets minimizes alloy segregation to produce an extremely fine-grained homogenous steel.

PSF27 combines the advantages of the Spray Forming Process with an alloy composition (1.55% carbon, 12.00% chromium, 0.75% molybdenum, 1.00% vanadium) that is basically equivalent to D2 tool steel. The synergy of these alloys and the Spray Forming Process results in a steel that offers increased toughness, wear resistance, crack resistance, and higher hardness. It is also more predictable and dimensionally stable during the heat-treatment process.

MT20 in CTS B70P

Carpenter® CTS B70P® blade steel—a high-chromium, air-hardening steel alloyed with molybdenum, vanadium and niobium. Like conventional steels, the particle metallurgy process begins with a homogenous molten bath of high-alloy steel. However, rather than being poured into ingot molds, the molten steel is forced through a nozzle under high pressure to create a spray of small spherical droplets that quickly solidify into powder particles. The small size of the particles forms micro-ingots, drastically reducing the alloy segregation in the steel and ensuring an extremely fine, uniform carbide structure. This enhances the steel’s edge retention, as well as its grinding and polishing characteristics.

CTS B70P is a powder metallurgy derivative of Carpenter’s CRB-7 alloy, but offers improved wear resistance and hardness capability. Its corrosion resistance is very comparable to 440C stainless steel. Collectively, these qualities make it an excellent candidate for cutlery applications.

MT21 in CPM 4V

Crucible® CPM® 4V® blade steel—a powder metallurgy tool steel that offers high impact toughness and very good wear resistance. Developed for demanding industrial applications where a combination of strength, wear resistance and toughness is required, CPM 4V has significantly more carbon, vanadium, and molybdenum than CPM 3V. The result is a steel that is capable of a higher attainable hardness and even greater abrasion resistance than CPM 3V and significantly better toughness and wear resistance than D2. Despite these advanced performance qualities, CPM 4V has only 5% chromium -- below the threshold of stainless steel--and therefore must be properly maintained to protect it from corrosion.

Like conventional steels, particle metallurgy steels begin with a homogenous bath of molten high-alloy steel. However, instead of being poured into ingot molds, the molten steel is forced through a nozzle under high pressure to create a spray of small spherical droplets that quickly solidify into powder particles. The small size of the particles forms micro-ingots, drastically reducing the alloy segregation in the steel and ensuring an extremely fine, uniform carbide structure. This enhances the steel’s edge retention, as well as its grinding and polishing characteristics.

CPM 4V's exact alloy composition is as follows: Carbon: 1.35%, Manganese: 0.40%, Silicon: 0.80%, Chromium: 5.0%, Molybdenum: 2.95%, Vanadium: 3.85%.

MT22 in RWL-34

Spyderco’s twenty-second Mule Team installment features RWL 34, a "rapidly solidified powder" (RSP) martensitic stainless steel made by the renowned Swedish firm Damasteel®. RWL 34 is a variation of the 420 martensitic stainless family that contains 14% chromium, as well as molybdenum and vanadium for improved corrosion resistance, hardness, and strength. The performance of these alloys is further enhanced by the RSP process, which involves using high-pressure nitrogen gas to force the molten steel through a nozzle. Just as in the CPM process used by Crucible, this creates a spray of small spherical droplets that rapidly solidify into powder particles, drastically reducing the segregation, or settling, of the alloys in the steel to produce an extremely fine, uniform carbide structure.

RWL 34 has long been a favorite of custom knifemakers—particularly Canadian maker Brian Tighe, designer of the Tighe Stick—because of its high-performance characteristics and the fact that it is capable of taking an extremely high polish. However, it has not been used in the production of factory-made knives because it was not available in large sheets. Recent improvements in the availability of the material have changed that situation, so Spyderco quickly seized the opportunity to incorporate RWL 34 into our Mule Team Project.

RWL 34's alloy composition is as follows: Carbon - 1.05%, Manganese - 0.50%, Silicon - 0.50%, Chromium - 14.0%, Molybdenum - 4.00%, Vanadium - 0.20%. This advanced alloy mix makes it a very close equivalent of 154 CM and ATS-34 stainless steels, but since it has the additional advantages offered by the RSP process, it is actually closest to CPM 154—Crucible’s particle metallurgy version of 154 CM — with the addition of several trace elements.

MT23 in CPM-20CV

Spyderco's twenty-third Mule Team installment features CPM 20CV steel, a highly wear resistant, powder metallurgy stainless tool steel. CPM 20CV is unique in that it contains a high volume of vanadium carbides and the highest amount of chromium of any high-vanadium stainless steel currently available. This potent combination of elements gives it a remarkable combination of high wear resistance, superior corrosion resistance, good impact toughness, and excellent polishability. These properties are maximized by the powder metallurgy process, which ensures an extremely clean steel with small carbides and a very fine grain size.

CPM 20CV excels in industrial applications that demand high wear resistance and high corrosion resistance, such as plastic injection feed screws, barrel liners, screw tips, and mold cavities. It is also used in food processing equipment and pelletizer knives and is an extremely popular blade steel in high-performance custom knives.

CPM 20CV's alloy composition is as follows: Carbon: 1.90%, Manganese: 0.30%, Silicon: 0.30%, Chromium: 20.0%, Tungsten: 0.60%, Molybdenum: 1.00%, and Vanadium: 4.00%. An advanced alloy that offers outstanding potential in high-performance cutlery applications, CPM 20CV is a truly unique blade material and we are proud to feature it on the MT23 Mule Team blade.

MT24 in Maxamet

Spyderco’s twenty-fourth Mule Team installment features Carpenter® steel\'s Micro-Melt® Maxamet® alloy - a super-hard high-speed powdered tool steel possessing properties that transcend conventional high-speed tool steels, approach those of cemented carbides, the ultra-hard materials used to machine other steels. When Carpenter developed this amazing alloy, they sent samples to various companies in the knife industry to evaluate as a blade material. Although many tried, Spyderco was one of only a handful of companies to successfully develop the specialized methods necessary to machine, heat treat, and grind this demanding material to yield reliable, high-performance knife blades. We are now extremely proud to offer it to our Mule Team enthusiasts - so proud in fact that the MT24 Maxamet Mule \"jumped the line\" ahead of our scheduled MT23 release.

Maxamet\'s remarkable alloy composition includes: Carbon: 2.15%, Manganese: 0.30%, Sulfur: 0.070%, Silicon: 0.25%, Chromium: 4.75%, Cobalt: 10.00%, Vanadium: 6.00%, and Tungsten: 13.00%. This sophisticated mix of elements, combined with the advantages of powdered metal technology, give it an extraordinary balance of wear resistance and toughness at high hardness levels.

MT25 in LC200N

Expected April 12, 2017

Spyderco’s twenty-fifth Mule Team installment features LC200N steel - a high nitrogen alloyed tool steel that offers extreme corrosion resistance. LC200N is produced by a combination of the PESR (Pressurized Electric Slag Remelting) process and “smart forging” technology to yield an amazing increase in the steel’s purity and a very fine and homogenous microstructure. It is also a true martensitic steel that achieves its hardness through traditional heat treating, so its hardness level can be precisely controlled to meet the demands of specific uses. Regarded as the material of choice for applications that involve high static and dynamic loads in corrosive environments, LC200N is widely used in the food, chemical, recycling, and pharmaceutical industries, as well as in mirror-polished dies used in the plastics industry. It is best known, however, as NASA’s preferred material for the ball bearings used in their aerospace equipment.

LC200N’s unique alloy composition includes: 0.3% Carbon, 15% Chromium, 0.5% Nitrogen, 0.95% Molybdenum, 0.5% Nickel, and 1.00% Manganese. When this alloy recipe is translated to knife blades, LC200N provides an exceptional blend of toughness, edge holding, and corrosion resistance.

MT26 in PMA11

Announced for August 7, 2017

Spyderco’s twenty-sixth Mule Team installment features Carpenter® Technology Corporation's Micro-Melt® A11, a particle metallurgy version of A11 tool steel. Also known as AISI A11, K294 (Böhler-Uddeholm), CPM® 10V (Crucible®), and PMA11. It is an extremely wear-resistant tool steel that is capable of achieving a high working hardness. One of the world's premier steel choices for highly wear-resistant industrial tooling, in its CPM 10V form it is also one of the favorite steels of renowned custom knifemaker and Spyderco collaborator Phil Wilson.

PMA11's alloy composition is as follows: Carbon: 2.45%, Manganese: 0.50%, Silicon: 0.90%, Chromium: 5.30%, Molybdenum: 1.30%, Vanadium: 9.50%, Sulfur 0.08%. Its large volume of hard vanadium carbides provides substantially better wear-resistance than typical high-carbon, high-chromium die steels such as D2 and D7. In knife blades, this translates to outstanding edge retention and good toughness, especially in shorter knives. These properties are maximized through the particle metallurgy process, which greatly reduces alloy segregation and ensures a homogenous microstructure. Please note, however, that PMA11 is a tool steel and must be maintained properly to safeguard it against corrosion. PMA11 is an advanced alloy that offers excellent potential in high-performance cutlery applications.

MT27 in PD1

This was the "last mule" for some time (until 2020 when Spyderco gave hints about reviving the program). This alloy is almost identical to Crucible's "Cruwear", which is highly regarded.
Amazingly these blades are still available in July of 2020!

Spyderco’s twenty-seventh Mule Team installment features Carpenter® steel's Micro-Melt® PD#1 alloy, an air-hardening cold-work die steel. PD#1's unique alloy composition gives it wear resistance significantly superior to conventional steels like D2, while still maintaining excellent toughness. Thanks to Carpenter's advanced Micro-Melt powder metallurgy process, PD#1 possesses an extremely fine microstructure and uniform carbide distribution, as well as the enhanced compressive strength necessary for the demands of tooling applications. Collectively, these qualities give it a unique combination of wear resistance and toughness that make it ideal for use as a blade steel.

PD#1's unique alloy composition includes: 1.1% Carbon, 7.75% Chromium, 1.2% Silicon, 1.6% Molybdenum, 1.1% Tungsten, 0.25% Manganese, and 2.35% Vanadium. Note that its moderate Chromium content provides only limited corrosion resistance, so please maintain your knife properly.

MT28 in SPY27

Indicated as "coming soon" as of July 16, 2020.

Note that "27" is the atomic number for cobalt. It was said that the initial inspiration for this steel was to make a domestic version of VG10, but if you look at the composition you will see that they have gone significantly beyond that.

Expertly crafted from our new, proprietary blade steel, CPM SPY27, the MT28 Mule Team is a fully sharpened fixed-blade blank that allows knife enthusiasts and hobbyists to attach their own handle scales and conduct their own performance testing.

In close cooperation with Crucible® Industries, we have developed CPM SPY27, a particle metallurgy stainless steel containing a proprietary mix of alloys, including vanadium, molybdenum, niobium, nitrogen, and cobalt. This remarkable composition, enhanced by the amplifying effects of cobalt and the state-of-the-art Crucible Particle Metallurgy process, is produced exclusively for Spyderco.

MT29 in Z-Max

I was fortunate enough to get one of these.

The latest addition to this elite family features Z-Max PM, an ultra-high-performance powder metallurgy tool steel enriched with vanadium, tungsten, molybdenum, cobalt, and two percent carbon. Capable of being heat treated to extreme hardness, it offers exceptional wear resistance and edge holding properties.

Z-Max is almost identical to CPM Rex 121, which is a very exotic steel. It has a huge amount of carbides and can be heat treated to 68HRC. It is closer to Maxamet than any other knife steel. It is extremely hard, with tremendous edge holding, but sacrifices toughness. It can be hardened even beyond HRC 68, but that will sacrifice even more toughness.

MT30 in Z-Wear

This is a Cru-wear clone like PD1, so I wasn't terribly upset that I missed the announcement and did not get one.

This addition to Spyderco's popular Mule Team series showcases Z-Wear PM -- a particle metallurgy cold work tool steel produced in Germany by Zapp. Created to tackle the most demanding industrial applications, it offers wear resistance superior to A2 and D2 tool steels while providing increased toughness and resistance to chipping.

MT31 in CMP S45VN

I missed this one (but got a PM2 with S45VN and like the steel a lot).

When Crucible Industries created CPM S35VN for the cutlery industry, they formulated it to provide increased toughness over CPM S30V while maintaining the same level of edge retention. CPM S45VN takes that development a step further, adding Niobium and Nitrogen in place of some Vanadium and Carbon to provide a more finely tuned balance of edge retention, wear resistance, and corrosion resistance.


Feedback? Questions? Drop me a line!

Tom's Knife Info / [email protected]