Blade materials are those used to make the blade of a knife or other simple edged hand tool or weapon, such as a hatchet or sword.
The blade of a knife can be made from a variety of materials, the most common being carbon steel, stainless steel, tool steel and alloy steel. Other less common materials used in knife blades include: cobalt and titanium alloys, ceramics, obsidian, and plastic.
The hardness of steel is usually stated as a number on the Rockwell C scale (HRC). The Rockwell scale is a hardness scale based on the resistance to indentation of a material, as opposed to other scales such as the Mohs scale (scratch resistance) testing used in mineralogy. As hardness increases, the blade becomes capable of taking and holding a better edge, but is more difficult to sharpen and more brittle (commonly called less "tough"). Laminating a harder steel between a softer one is an expensive process that to some extent gives the benefits of both types (see Damascus steel).
5160, Spring steel. Popular forging steel for swords and large knives. High toughness and good wear resistance.
V-toku1 / V-toku2, alloyed steel with W /Cr's original characteristics.
Popular sword manufacturers that use 5160 spring steel are Hanwei Forge and Generation 2. 5160 spring steel is mainly used on Medieval type swords.
Tool steel grades used in cutlery : A, D, O, M, T, S, L, W. See also AISI Tool Steel Grades.
The following are tool steels, which are alloy steels commonly used to produce hardened cutting tools:
A2, a steel that trades wear resistance for toughness. It is used in custom made fighting knives by makers such as Phill Hartsfield, Rob Criswell, Mike Snody and John Fitzen (Razor Edge US) and one of the latest to standardise his camp/survival knives in A2 tool steel is Aaron Gough from Gough custom, Canada.
A3, (No description available)
A4, (No description available)
A5, (No description available)
A6, This grade of tool steel air-hardens at a relatively low temperature (approximately the same temperature as oil-hardening grades) and is dimensionally stable. Therefore, it is commonly used for dies, forming tools, and gauges that do not require extreme wear resistance but do need high stability.
A7, (No description available)
A8, C .55% Mn .30% Si .30% Cr 5.00% Mo 1.25% W 1.25%
A9, (No description available)
A10, This grade contains a uniform distribution of graphite particles to increase machinability and provide self-lubricating properties. It is commonly used for gauges, arbors, shears, and punches.
D2, has a high chrome content of 12.00%, it is called "semi-stainless", because of the lack of free Chromium in solution. While not as tough as premium carbon steels, it is much tougher than premium stainless steels.
O1, popular forging steel. Good wear resistance and edge stability. Relatively tough, but not as much as A2 or 5160. It is most commonly used by Randall Knives, Mad Dog Knives, and many other custom knife makers.
M2, slightly tougher than D-2. Capable of keeping a tempered edge at high temperatures. However, it is hardly used anymore in factory production knives, CPM M4 is becoming more popular. Custom knife makers still use it for knives intended for fine cutting with very thin edges.
M4, see High speed CPM REX M4.
T1 (No description available)
T2 (No description available)
S1 is a shock-resistant medium carbon tool steel which combines moderate hardness with good impact toughness. Carbon content .40 - .55%.
W1, water hardening tool steel.High carbon content.
W2, a tool steel that holds its edge quite well but not very tough. Has a carbon content of 1.5. Most readily available W2 has a carbon content of no more than 1-1.1%. It can be left at high hardness levels (it can attain a quenched hardness of 67 Rc) and still be quite tough especially in larger knives with thicker spines as the core of the thick portion of the blade does not attain full hardness because of the shallow hardening nature of the steel. Bill Moran considered it to be almost a tough as 5160, but it was unavailable for a period of time.
SK3, SK4, SK5 - Japanese carbon steels. SK stands for "Steel Kougu" meaning "Steel Tool". The lower number indicates less impurities.
Crucible Industries produces Crucible Particle Metallurgy (CPM) tool steels using a powder metal forge process.
CPM 1V, proprietary steel, very high toughness, several times higher than A2 with same level of wear resistance.
CPM 3V, proprietary steel, very high toughness, less than CPM 1V, but more than A2, and high wear resistance, better than CPM 1V. Used by several custom knives makers and factories, including Jerry Hossom, Reese Weiland. Makes good choice for swords and large knives.
CPM 4V, high impact toughness and a very good wear resistance.
CPM 9V, modification of CPM 10V with lower carbon and vanadium to improve toughness and heat check resistance.
CPM 10V (AISI A11), highly wear-resistant tool steel, toughness comparable with D2 tool steel. Currently used by a few custom knife makers. Phil Wilson uses CPM 10V and other CPM steels.
CPM 15V, proprietary, extremely high wear-resistant tool steel, thanks to 14.5% Vanadium content. Found only in custom knives.
Chrome steel is one of a class of non stainless steels which are used for applications such as bearings, tools and drills.
AISI 52100, ball bearing steel. In terms of wear resistance, a little better than that of the O1 steel, however 52100 is also tougher. It has very fine carbides, which translates into high edge stability. Used by many custom makers, Swamp Rat knives uses 52100 steel under the name SR101. Also referred to as 100 Cr 6/102 Cr6 as per ISO nomenclature and confrorms to BS grade En31.
SUJ2, Japanese equivalent to AISI 52100 steel.
DIN 5401
Steels that did not fit into the stainless category because they may not have enough of a certain element, such as chromium.
V-Gin1, Fine-grained steel with Mo, V for the best effect of Cr.
V-Gin2, More Cr is added for better corrosion resistance.
V-Gin3B, More Cr is added for better corrosion resistance.
Stainless steel is a popular class of material for knife blades because it resists corrosion and is easy to maintain. However, it is not impervious to corrosion or rust. In order for a steel to be considered stainless it must have a chromium content of at least 13%.
The principle of stainless steel is that in an oxidizing chemical environment the oxide (chromium and sometimes nickel and other metal oxides) is stable, and when in a reducing (shortage of oxygen) environment at least one metal is stable. This usually works, except in an acid environment.
Austenitic stainless retains its non-magnetic crystal structure at room temperature, usually because it has high nickel content. It is therefore not hardenable by heat treating as typical hard steels are. So as knife steel it depends on other hardening methods such as alloying elements and cold working. It is highly corrosion resistant, except to stress corrosion cracking.
154CM/ATS-34 steels
These two steels are practically identical in composition. They were introduced into custom knives by Bob Loveless circa 1972.
154CM is produced by Crucible Industries. It is used extensively by Benchmade Knife Company.
CPM 154 is identical to 154CM in composition, produced using CPM Process, with all the benefits of the CPM technology.
ATS-34 is produced by Hitachi Metals.
The latter two are considered premium cutlery steels for both folding knives and fixed blades.
300 series
American stainless steel manufactured by Allegheny Ludlum steel Co and Crucible Industries.
The 300 series is non-magnetic.
302 is a Chromium-Nickel austenitic alloy used for blenders and mixers.
303 is an austenitic stainless steel specifically designed to exhibit improved machinability.
303 SE is an austenitic chromium-nickel steel to which selenium has been added to improve machinability and non-galling characteristics.
304L is a low carbon austenitic chromium-nickel steel designed for special applications.
316L is a low carbon austenitic chromium-nickel steel with superior corrosion and heat resisting qualities.
321 is an austenitic chromium-nickel steel with a high chromium content of 18.00%.
400 series
The 400 series remains one of the most popular choices for knife makers because it is easy to sharpen and it is resistant to corrosion.
The 400 series is magnetic.
410 is a hardenable, straight-chromium stainless steel which combines superior wear resistance with excellent corrosion resistance.
416 is very similar to 410 with the addition of sulfur to improve machinability.
420 has more carbon than 410, but less than 440. As such it is softer than 440, but has a higher toughness.
420 series contain 4 types, which is defined by its carbon content. 420A / 1.4021, 420B / 1.4024, 420C / 1.4034, and 420D / 1.4037. 420D stainless steel has about 0.66 carbon content, this steel grade is widely used to make high end razor blades, surgical scalpels etc. It obtains about 57 HRC after suitable heat treatment. 420HC ( 420C ) is a higher carbon content 420 stainless. The HC stands for "high carbon" and it can be brought to a higher hardness than 420 and should not be mistaken for it. Buck Knives and Gerber Knives use 420HC extensively. 420A ( 420J1 ) and 420B ( 420J2 ) are economical, highly corrosion resistant stainless steel grades. Knife manufacturers use this material in budget knives, also in diving knives due to its high resistance to corrosion.
440 series has three types, 440A, 440B and 440C. 440A is a relatively a low cost, highly corrosion resistant stainless steel. In China, Ahonest ChangJiang Stainless steel developed 440A modified 7Cr17MoV, by adding more element vanadium. 440B is almost identical to 440A, but has a higher carbon content range compared to 440A 440C is considered a high-end stainless steel. It is very resistant to corrosion and is one of the most common stainless alloys used for knife making. The once ubiquitous American Buck Model 110 Folding Hunter was made of 440C before 1981. 440C has highest carbon content in 440 group. Böhler n695 is equivalent to 440C.
AUS series
The AUS stainless steel series is produced by Aichi Steel Corporation, Japan. They differ from the AISI 4xx series because they have vanadium added to them. Vanadium improves the wear resistance, toughness, and ease of sharpening. In the alloy name the appended 'A' indicates the alloy has been annealed.
AUS-6 (6A) is comparable to 440A with a carbon content close to 0.65%. It is a low cost steel, slightly higher wear resistance compared to 420J.
AUS-8 (8A) is comparable to 440B with a carbon content close to 0.75%. AUS-8 is often used instead of 440C. SOG knives uses AUS-8 extensively.
AUS-10 (10A) is comparable to 440C with a carbon content close to 1.10%. It is slightly tougher than 440C.
CPM SxxV series
The SxxV series are Crucible Industries stainless steels produced using CPM process.
CPM S30V, on the lower end of the SxxV steels, it has a carbon content of 1.45%. However, S30V is still considered to be a superior choice for knife making. CPM S30V is used in a wide range of ZT knives.
CPM S35VN is a martensitic stainless steel designed to offer improved toughness over CPM S30V. It is also easier to machine and polish than CPM S30V. It is used in many high end kitchen knives including those by New West Knifemakers
CPM S60V (formerly CPM T440V) (discontinued), very rich in vanadium. CPM S60V has a carbon content of 2.15%. It was an uncommon steel, but both Spyderco and Kershaw Knives offered knives of this steel, Boker still offers folders made from CPM S60V.
CPM S90V (formerly CPM T420V) has less chromium than S60V, but has almost twice as much vanadium. S90V's carbon content is also higher, resting around 2.30%.
CPM S110V has higher corrosion resistance than S90V and marginally better wear resistance. The additional corrosion resistance while retaining all the benefits of S90V makes this steel extremely desired for kitchen cutlery.
CPM S125V, online information is not available as of August 2014, contact Crucible Industries sales for information. It contains 3.25% carbon, 14% chromium and 12% Vanadium and other alloying elements. Exceptionally high wear resistance, making it difficult to process and machine for knifemakers. At first only used in custom knives, it has been utilized by larger manufacturers more recently in limited quantities.
VG series
Japanese stainless steels, manufactured by Takefu Special Steel.
VG-1, Takefu stainless steel. Popular steel in Japanese kitchen knives.
VG-2, Middle-carbon Mo stainless blade steel.
VG-5, Synergic effect of Mo and V makes carbide finer.
VG-7/VG-8W, strengthens substrate and improves tempering performance.
VG-10(B/W), Takefu stainless steel, similar composition to VG-1 but also contains cobalt and vanadium. Good wear resistance and rust resistance.
San-mai, A composite steel used by Knife manufacture Cold Steel in their high end knives. The core is VG-1 and the outside layers are 420j for good rust resistance. In the United States, SAN MAI III is a registered trademark of Cold Steel, Inc., U.S. Reg. Nos. 1471971, 3540202 and 3540187.
Due to small Vanadium content VG-10 has finer grain content compared to VG-1. Cobalt and Nickel improve toughness. Overall, it has better edge stability compared to VG-1. VG-10 is widely used in Japanese kitchen knives, several manufacturers use it in various folders and fixed blade knives, including Spyderco, Cold Steel and Fallkniven.
CTS series
American stainless steels produced by Carpenter Technology using vacuum melt technology.
CTS-BD1, high-carbon chromium steel that provides stainless properties with high hardness and excellent wear resistance.
CTS-20(CP), offers superior edge retention and surface finish, an ability to be machined to a fine edge, and consistent heat-treatability from lot to lot.
CTS-BD30P
CTS-40C(CP), a powder metallurgy, high-carbon chromium stainless steel designed to provide stainless properties with maximum hardness.
CTS-TMT, A hardenable martensitic stainless steel that combines improved corrosion resistance over Type 410 stainless with hardness up to 53 HRC and improved formability over 17Cr-4Ni.
CTS-XHP, is a powder metallurgy, air-hardening, high carbon, high chromium, corrosion-resistant alloy. It can be considered either a high hardness 440C stainless steel or a corrosion-resistant D2 tool steel.
Mo/MoV series
Chinese and American stainless steels; the manufacturers are unknown with the exception of 14-4CrMo which is manufactured by Latrobe Specialty Metals.
(sorted by first number.)
14-4CrMo, Manufactured by Latrobe Specialty Metals. A wear resistant, martensitic stainless tool steel that exhibits better corrosion resistance than 440C stainless steel.
2Cr13, belongs to 420 grade series, very basic. EN 1.4021 / DIN X20Cr13, widely used in economic cutting tools, 50HRC max after heat treatment.
3Cr13, in 420 grade series, it contains 420A 420B 420C 420D. 3Cr13 steel is 420B, EN 1.4028 / DIN X30Cr13, 52HRC Approx after heat treatment.
3CR13MoV, made by adding more elements molybdenum and vanadium to the 420J2-3Cr13 formula.
4Cr13, EN 1.4034 / DIN X46Cr13, 420C stainless steel, it obtains about 55-57HRC.
4Cr13Mo, EN 1.4419 / DIN X38CrMo14, developed based on GB 4Cr13 / DIN X46Cr13 by adding elements Molybdenum.
4Cr14MoV, EN 1.4117 / DIN X38CrMoV15, good enough to make kitchen knives.
5Cr15MoV, Some knives manufacturers define as 5Cr13MoV, the hardness could be 55-57 HRC. It's widely used to make kitchen knives, high-end scissors, folding knives and hunting knives etc.
6CR13MoV, It's also wrote as 6Cr14MoV. The Patented name applied by Ahonest Changjiang Stainless steel Co.,Ltd. Similar stainless steel grade 6Cr14 ( 6Cr13 ) / 420D which does not contain molybdenum and vanadium is superior to make razor blades, surgical scalpels etc.
7CR17MoV, it's 440A modified which contains more elements vanadium, the benefits of Vanadium (V) • Increases strength, wear resistance, and increases toughness the recommended hardness about 55/57 HRC.
8CR13MoV & 8CR14MoV, actually these grades do not have very big difference. They are similar to AICHI AUS-8, an excellent value priced steel for its performance.
9Cr13MoVCo ( 9Cr13CoMoV ), produced by Ahonest Changjiang stainless steel, described as forged high carbon cobalt stainless steel, uses include high end barber scissors, hunting knives etc.
9Cr18MoV, 440B modified, a higher end Chinese stainless steel used mostly in high-end barbering scissors and surgical tools.
9Cr19MoV used in items such as the Ultimate Pro Bear Grylls Survival knife.
99Cr18MoV, 440C modified. Developed by jaktkit and Ahonest Changjiang in cooperation. Uses ESR technology and hot forging. This improves its work performance, especially toughness, and edge holding ability.
Sandvik series
6C27, A common knife steel grade with good corrosion resistance and low hardness, mainly used in applications where the need for wear resistance is low.
7C27Mo2 Generally the same properties as Sandvik 6C27, but with improved corrosion resistance.
12C27, A grade with high hardness and good wear resistance. Takes very keen edge with ok edge holding.
12C27M, Another Swedish stainless razor steel. A very pure, fine grained alloy. A grade with good wear resistance and good corrosion resistance, well suited for the manufacture of kitchen tools.
13C26, Also known as a Swedish stainless razor steel. Generally the same properties as Sandvik 12C27, but with slightly higher hardness but less corrosion resistant. The Swedish steel maker Uddeholm AB also makes a virtually identical razor steel composition known as AEB-L, which they patented in 1928. Swedish razor steel is a very pure, fine grained alloy which positively affects edge holding, edge stability and toughness.
14C28N, was designed by Sandvik at Kershaw's behest to have the edge properties of 13C26 but with increased corrosion resistance by adding nitrogen and chromium. Available in Kershaw knives (as of 2012) and in other brands.
19C27, A grade with very high hardness and wear resistance.
Daido stainless tool steels used for kitchen knives and scissors.
DSR1K6(M), similar to Aus6 and VG2
DSR7F, used for high-hardness cutting parts.
DSR1K7, a steel known to exist. No further information is available.
DSR1K8, a steel known to exist. No further information is available.
DSR1K9, a steel known to exist. No further information is available.
DSR10UA, used for small scissors.
DSR1K11, a steel known to exist. No further information is available.
Other stainless
ATS-55, produced by Hitachi Metals. It has lower molybdenum content than ATS-34, is less wear-resistant than ATS-34 and has been reported to be also less rust-resistant than ATS-34.
Kin-2, Middle-carbon Mo,V stainless blade steel.
BNG10, a steel known to exist. No further information is available.
Co-Special, a steel known to exist. No further information is available.
M390 - BOHLER M390 MICROCLEAN. Third-generation powder metal technology. Developed for knife blades requiring good corrosion resistance and very high hardness for excellent wear resistance. Chromium, molybdenum, vanadium, and tungsten are added for excellent sharpness and edge retention. Can be polished to an extremely high finish. Hardens and tempers to 60-62 HRC. Due to its alloying concept this steel offers extremely high wear resistance and high corrosion resistance.
CPM-20CV, a very high-quality martensitic stainless steel, with outstanding corrosion resistance and excellent edge holding. CPM-20CV does lack the impact toughness of CPM-3V but being made with the CPM process, this steel is still very resistant to lateral stress (flex) breakage. Consider CPM-20CV for a very low maintenance, all-weather cutting tool.
Several steel alloys have carbon amount close or above 3%. As usual those steels can be hardened to extremely high levels, 65-67HRC. Toughness levels are not high compared to CPM S90V steel, however, they have high wear resistance and edge strength, making them good choice for the knives designed for light cutting and slicing works.
Cowry-X is produced by Daido steel using PM process. Contains 3% carbon, 20% chromium, 1.7% molybdenum and Less than 1.00% vanadium. Other elements are not published or may not even exist. Used by Hattori knives in their kitchen knives KD series.
ZDP-189 is produced by Hitachi steel using PM process. It contains 3% carbon and 20% chromium and contains tungsten and molybdenum. Used by several custom knife makers and factory makers including Spyderco and Kershaw in the limited run of the Ken Onion Shallot folders. The Henckels Miyabi line markets this steel with the name "MC66".
Elmax, produced by Bohler-Uddeholm, is a through-hardening corrosion resistant mold steel using third-generation powder metallurgy process. Often said to be far superior to S3xv for edge retention and ease of sharpening. Used in most of the 2013 and forward Microtech knives.
R2 is a PM steel made by Kobe Steel Japan (Kobelco). It is also known as SG2 (Special Gold 2) when it is marked by Takefu Specialty Steel.
SRS-15 a High Speed Tool Steel (HSS) where the 15 represents 1.5% C. One of the earliest known Japanese "super steels" the maker is unknown. A SRS-13 with 1.3% C also exists.
CPM REX series
CPM REX M4 (AISI M4) is a high speed tool steel produced by Crucible using CPM process. M4 has been around long time, lately entering custom and high end production knives.
CPM REX 121, is a new high vanadium cobalt bearing tool steel designed to offer a combination of the highest wear resistance, attainable hardness, and red hardness available in a high-speed steel.
CPM REX 20 (HS) is a cobalt-free super high speed steel made by the CPM process.
CPM REX 45 (HS) is an 8% cobalt modification of M3 high speed steel made by the CPM process.
CPM REX 54 HS is a cobalt-bearing high speed steel designed to offer an improvement in the red hardness of the popular M4 grade, while maintaining wear properties equivalent to M4.
CPM REX 66 (HSS) is a super high speed steel made by the CPM process.
CPM REX 76 (HSS) is a super high speed steel made by the CPM (Crucible Particle Metallurgy) Process. It is heat treatable to HRC 68-70. Its high carbon, vanadium and cobalt contents provide abrasion resistance comparable to that of T15 and red hardness superior to that of M42.
CPM REX 86 (HSS) is a super high speed steel made by the CPM process. It has a combination of high attainable hardness capability (68-70 HRC), red hardness, and abrasive wear resistance for difficult machining applications while still maintaining good fabricating and toughness characteristics. The composition is designed to provide a balance of vanadium-rich MC and tungsten-molybdenum-rich M6C primary carbides.
CPM REX T15(HSS) is a super high speed steel made by the CPM process. It is a tungsten type high speed containing high vanadium for excellent abrasion resistance, and cobalt for good red hardness, and is used for cutting difficult to machine materials where high frictional heating is encountered.
The steels in this category have much higher resistance to elements and corrosion than conventional stainless steels. These steels are austenitic and non-magnetic. They are used in knives designed for use in aggressive, highly corrosive environments, such as saltwater, and areas with high humidity like tropical forests, swamps, etc. These steels can contain 26% to 42% chromium as well as 10% to 22% nickel and 1.5 to 10% of titanium, tantalum, vanadium, niobium, aluminum silicon, copper, or molybdenum etc., or some combination thereof.
H1, produced by Myodo Metals, Japan. Used by Spyderco in their salt water/diving knives. Benchmade used it as well, later replaced with X15TN.
X15Tn, French steel, originally designed for medical industry and jet ball bearings. Used by Benchmade in their salt water/diving knives.
N680, Bohler-Uddeholm steel, highly corrosion resistant. Used by Benchmade in their salt water/diving knives.
N690CO an Austrian stainless steel hardened to the high Rc50 range. Currently found in Spyderco's Hossom knives and the recently discontinued Italian-made Volpe. TOPS knives also used it in their C.Q.T magnum 711 knife. Also used extensively by Fox Knives Military Division, Extrema Ratio and Steel Will Knives.
Carbon steel is a popular choice for rough use knives. Carbon steel tends to be much tougher and much more durable, and easier to sharpen than stainless steel. They lack the chromium content of stainless steel, making them susceptible to corrosion.
Carbon steels have less carbon than typical stainless steels do, but it is the main alloy element. They are more homogeneous than stainless and other high alloy steels, having carbide only in very small inclusions in the iron. The bulk material is harder than stainless, allowing them to hold a sharper and more acute edge without bending over in contact with hard materials. But they dull by abrasion quicker because they lack hard inclusions to take the friction. This also makes them quicker to sharpen. Carbon steel is well known to take a sharper edge than stainless.
10xx series
The 10xx series is the most popular choice for carbon steel used in knives. They are very durable.
1095, a popular high-carbon steel for knives; it is harder but more brittle than lower carbon steels such as 1055, 1060, 1070, and 1080. It has a carbon content of 0.90-1.03% Many older pocket knives and kitchen knives were made of 1095. It is still popular with many bushcrafters and survivalists due to its toughness and ease of sharpening. With a good heat treat, the high carbon 1095 and O-1 tool steels can make excellent knives.
1084, carbon content 0.80-0.93%.
Often recommended for novice knife makers or those without more advanced heat treating equipment due to the ease of heat treating it successfully in such conditions, yet also used by many professional bladesmiths for various kinds of knives as it can make excellent knives.
1070, carbon content 0.65-0.75% Used in machetes.
1060, used in swords. It has a carbon content of 0.55-0.65%
1055, used in swords and machetes often heat-treated to a spring temper to reduce breakage. It has a carbon content of 0.48-0.55%
V-x series
V-1/V-2 Chrome is added to improve quenching performance.
V-2C, Pure carbon steel, with impure substances completely removed.
Aogami/Blue-Series
a Japanese exotic, high-end steel made by Hitachi. The "Blue" refers to, not the color of the steel itself, but the color of the paper in which the raw steel comes wrapped.
Aogami/Blue-Num-1 A steel with higher tensile strength and sharpening ability than blue-2.
Aogami/Blue-Num-2 A steel with higher toughness and wear resistance than blue-1.
Aogami/Blue-Super A steel with higher Toughness, tensile strength and edge stability than all other steels in its series.
Aogami/Super blue The same steel as Blue-Super A
Shirogami/White-series
Shirogami/White-1 Hardest among the Hitachi steels,but lacks of toughness.
Shirogami/White-2 Tougher than S/W-1 but as not much Carbon content, thus slightly less hard.
Kigami/Yellow-Series Steel
"Better" steel compared to SK series, but worse than both, Aogami and Shirogami. Used in high end tools and low/mid class kitchen knives.
Other proprietary steels
INFI, a unique steel used in Busse knives. It is a tough steel, that resists both wear and stains. It has a carbon content of 0.50%
Other carbon steel
These steels did not exist in a series.
Shiro-2, Cr and Ni are added for better quenching and ductility.
The group of these steels is unknown at this time. Please move them to their proper group and provide a description.
6150 Was used in coil springs. Perfectly good for hunting knives, etc. Tolerates less than ideal temperature control in forging and heat treating (As does 5160) Probably does not hold an edge as well as 1095, but is tough, and easy to sharpen.
4116 Krupp is a German steel used by cold steel and is cryogenically quenched during the hardening process.
Acuto 440
AL-158
A
BG-42 Slightly higher in carbon, chrome and moly than ATS-34. Must be forged and heat treated at very high and exact temperatures. Is used at very high hardness, such as RC 64-66. Not supposed to be brittle, but high alloy steels usually are. Very expensive and hard to work.
BRD4416 stainless steel
Vanax By Uddeholm. A new blade steel in which carbon is largely replaced by nitrogen.
X55CrMo14 or 1.41110 Swiss Army knife Inox blade steel used by Victorinox.
Carbon (C)
increases edge retention and raises tensile strength.
increases hardness and improves resistance to wear and abrasion.
reduces ductility as amount increases
provides hardenability.
Chromium (Cr)
increases hardness, tensile strength, and toughness.
increases resistance to corrosion, heat and wear.
more than 12% makes it "stainless", by causing an oxide coating to form.
carbide inclusions reduce wear, but bulk material is softer.
Cobalt (Co)
increases strength and hardness, and permits quenching in higher temperatures.
intensifies the individual effects of other elements in more complex steels.
increases resistance to heat and corrosion.
Copper (Cu)
increases corrosion resistance. (?)
Manganese (Mn)
increases hardenability, wear resistance, and tensile strength.
deoxidizes and degasifies to remove oxygen from molten metal.
in larger quantities, increases hardness and brittleness.
increases or decreases corrosion resistance depending on type and grade of steel or stainless steel.
Molybdenum (Mo)
increases strength, hardness, hardenability, and toughness.
improves machinability and resistance to corrosion.
Nickel (Ni)
Adds toughness.
Improves corrosion and heat resistance.
Reduces hardness.
Too much prevents hardening by heat-treatment.
Niobium (Nb)
Restricts carbide grain growth.
Increases machinability.
Creates hardest carbide.
Increases strength, heat, corrosion resistance and toughness.
Nitrogen (N)
Used in place of carbon for the steel matrix. The Nitrogen atom will function in a similar manner to the carbon atom but offers unusual advantages in corrosion resistance.
Phosphorus (P)
Improves strength, machinability, and hardness.
Creates brittleness in high concentrations.
Silicon (Si)
Increases strength, heat and corrosion resistance.
Deoxidizes and degasifies to remove oxygen from molten metal.
Sulfur (S)
Improves machinability when added in minute quantities.
Usually considered a contaminant.
Tantalum Ta
Increases corrosion and heat resistance, strength, ductility and toughness.
Tungsten (W)
Adds strength, toughness, and improves hardenability.
Retains hardness at elevated temperature.
Improves corrosion and heat resistance.
Titanium
increases strength, toughness, heat, corrosion resistance and reduces weight.
increases hardness and wear resistance if nitrogen or carbon are at the surface of the alloy.
Vanadium (V)
Increases strength, wear resistance, and increases toughness.
Improves corrosion resistance by contributing to the oxide coating.
Carbide inclusions are very hard.
Expensive.
Increases chip resistance.
Ceramics are harder than metals but more brittle. Ceramic knives can be sharpened with silicon carbide or diamond sandpaper but chip when sharpened on a hard stone or lap. Good for those who do not sharpen their own knives. Needs discussion
The harder ceramics may be used in composite form to make them workable.
Marketech AO series
AO 95, (No description available)
AO 98, (No description available)
Very hard, strong and corrosion resistant, but expensive. Used by Böker.
These materials did not fit into the aforementioned steel or ceramic types.
Stellite and Talonite
Titanium and titanium alloys are often used in diving and EOD (Explosive Ordinance Disposal) knives due to its excellent corrosion resistance and non-magnetic properties. Some titanium blades have a carbide or nitride edge attached instead of a raw titanium(alloy)edge.
Copper beryllium
Damascus steel, either pattern welded steel or the ancient crucible steel (wootz, pulad, bulat)
Obsidian, used by Native Americans for knives, spears, and arrowheads.
This natural glass chips sharper than other stones but is more brittle.
Other hard stones such as flint and chert.
Bone
Wood
Bronze
Jade
Brass
Copper
Pewter
Chromium, used by the Qin Dynasty to coat and harden weapons.
