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Video Version
Here is the video version of the following content:
Cold Treatments of the Past
I have a series of three articles about cryo where I introduced a good amount of background material about how it works:
Cryo Part 1: Maximizing Hardness
Cryo Part 2: Toughness and Strength
Cryo Part 3: Wear Resistance and Edge Retention
I also have a chapter in my book about cryogenic processing. I recommend the book to anyone who wants to learn about knife steel and heat treating, of course.
Cold Treatments and Cryo Explained
Some time ago I did some experiments with AEB-L where I compared the freezer and liquid nitrogen for AEB-L and found the following:
Using my household freezer (not a fancy freezer) led to a result that was surprisingly different than room temperature quenching alone. Common knowledge on the internet from knifemakers says that a freezer doesn’t “do anything” and that you need to have at least dry ice to have a true cold treatment for your knives. This shows a fundamental lack of understanding about what happens in cold treatments. When you quench the hot steel you are transforming from the high temperature phase, austenite, to the high hardness phase martensite. Martensite is what gives knife steel its high hardness, strength, and wear resistance. The transformation to martensite is primarily controlled by temperature, not time. So to get more martensite you need to quench below the martensite start temperatures (Ms) and as it cools down it forms more and more martensite as it approaches the martensite finish temperature (Mf) where the steel is fully martensite. If the steel does not reach the martensite finish temperature then there is some amount of austenite that remains in the steel untransformed, which is called “retained austenite.” The martensite start and finish temperatures are most greatly controlled by carbon; the more carbon is “in solution” in the austenite the lower these transformation temperatures are:
Data adapted from [1]
Other alloying elements also reduce Ms and Mf such as chromium. The higher the austenitizing temperature for a given steel the more carbide is dissolved which puts more carbon and alloy in solution for reduced martensite transformation temperature. Read about austenitizing in these articles: Part 1 and Part 2. Therefore, austenitizing higher potentially means more retained austenite because Mf can be reduced below room temperature. At the simplest level, retained austenite leads to reduced hardness, which is why the AEB-L quenched to room temperature peaked in hardness from 1925°F (~62 Rc) and then dropped with increasing austenitizing temperature, down to 59 Rc from 2000°F. Small amounts of retained austenite can lead to an improvement in toughness so it isn’t always clear whether it is desirable to further reduce retained austenite. Virtually everyone agrees, however, that beyond about 15-20% retained austenite is undesirable as it leads to reduced strength and often reduced toughness. And luckily 15-20% RA is usually found at about the peak hardness. See below for Caldie tool steel as an example where they used different austenitizing temperatures and tempered to the same approximate hardness. In a compression test they found that the “yield strength” was reduced even with the same hardness with more RA. This means that the steel deforms more easily such as edge rolling even though the hardness test would lead you to think that strength would be sufficient.
Data adapted from [2]
Another study I have talked about is an old one where they looked at different cold temperatures after quenching with T1 high speed steel. They tried different periods of delay between the quench to room temperature and then putting it in the cold bath. They found that retained austenite stabilizes while the steel sits at room temperature, and the longer you wait before cooling the steel further, the less retained austenite will transform during the cold treatment.
Image from [3]
A cryo treatment such as with liquid nitrogen (-310°F) reduced the retained austenite from 20% down to 8% when placing it in liquid nitrogen directly after quenching. This degree of transformation was basically the same even after holding the steel at room temperature for an hour prior to cryo. Beyond an hour of waiting the effect became less and less until the maximum time of 20 hours where the liquid nitrogen was having about half the effect as when going directly into liquid nitrogen. Dry ice temperatures (-100°F) had nearly the same effect as liquid nitrogen when cooling directly after quenching, but after waiting for 20 hours it transformed almost none of the retained austenite. Freezer temperatures (~0°F), had about half the effect of liquid nitrogen if going into the freezer immediately, but waiting only a few minutes led to no change in retained austenite.
Similar trends were seen with W1 tool steel which is a simple carbon steel similar to 1095. They austenitized the steel from 1450°F and 1550°F to see the differences with austenitizing temperature:
Images from [3]
With a room temperature quench from 1450°F, the steel had 5.8% retained austenite, and from 1550°F it had 12% retained austenite. This is from more carbon being in solution leading to reduced Ms/Mf. Using liquid nitrogen temperatures effectively reduced the RA to near 0, as long as the steel was cooled immediately after quenching. Following similar trends from T1, the colder the temperature the less a delay affected the cold treatment.
New Cold Treatment Studies
Recently I ordered some steaks online and the box came with dry ice in it. I wanted to test it in comparison with liquid nitrogen and the freezer such as I had done with AEB-L before. I repeated the full experiment using 1900-2025°F in 25°F increments.
There were a handful of surprises in this data. One is that dry ice looked more similar to the freezer than it did to liquid nitrogen. Perhaps the lower martensite start temperature in the AEB-L led to more separation between dry ice and liquid nitrogen. Another surprise was that this steel I tested required about 50°F higher austenitizing temperatures for the same hardness as the original steel I tested. I realized that this was because the “AEB-L” was produced by Buderus rather than Uddeholm. One of the major knife steel suppliers sells Buderus X65Cr13 as AEB-L because Buderus and Uddeholm have the same parent company and the steels have the same composition. However, there is a microstructure difference between Buderus X65Cr13 and Uddeholm AEB-L which leads to a difference in hardening response. The knife steel supplier also sells the X65Cr13 to several other knife steel suppliers as AEB-L; you need to know which you have purchased to know how to heat treat it.
Buderus X65Cr13
Uddeholm AEB-L
Tempered Steel
After tempering at 300°F or 350°F, the hardness trends were somewhat different:
The peak hardness for room temperature quenched steel was raised from 1950°F up to 1975-2000°F after tempering. The hardness was increased by “precipitation strengthing” which can be seen at either low tempering temperatures (~100-300°F) or high tempering temperatures in the case of high alloy steels with Cr, Mo, W, V, etc. (~900-1100°F). I stated earlier in the article that the steel shouldn’t be austenitized above the peak hardness temperature, but this becomes somewhat difficult when the peak was 1950°F without tempering but 1975-2000°F after tempering. This is a question that needs further exploration. Perhaps to be on the safe side I would stick with 1950°F.
Toughness Testing
I used 1925°F as the temperature from which to do toughness coupons, which I tempered at 350°F:
The hardness was increased by using the cold treatments. The freezer specimens ended up slightly harder than the dry ice specimens, just due to the natural variation between coupons. The liquid nitrogen led to the highest hardness as expected. The toughness was reduced with the increase in hardness and drop in retained austenite. However, the drop in toughness was relatively small for the amount that hardness increased, so in general I would say that the liquid nitrogen processing was worth it in this case. I also compared these toughness coupons to earlier Uddeholm AEB-L and Buderus Nitro-V. The toughness was similar to Buderus Nitro-V (a very similar composition), both slightly reduced from Uddeholm AEB-L. This is likely due to the microstructure difference between the two products.
In a study on Z-Wear/CPM-CruWear we found an increase in hardness with cryo but any change in toughness was within the statistical “noise” of the test:
In a study on 52100 we found a small decrease in toughness even after compensating for hardness:
I have seen a case or two where a significant drop in toughness was found with cold treatments. There was a study on Elmax steel where the found the toughness was dropped by more than half. I haven’t seen anything this extreme in my own testing so I don’t know if this is due to the austenitizing temperature, something specific to Elmax, or a problem in the testing of the researchers:
Image from [4]
There is definitely more research that could be done in this area. The difference in toughness with cryo on AEB-L would definitely be different with another austenitizing temperature because more retained austenite would be in the room temperature condition. And different steels may respond differently as well.
Wear Resistance and Edge Wear
I summarized the journal article studies on wear resistance changes from cryo in the Part 3 article that I linked to previously. Since that article I did a large CATRA study, and part of that study I did a cryo comparison for edge wear. There is a commonly cited study on D2 where they did cryogenic processing for different lengths of time and found that 36 hours was the optimal cryo time for maximizing edge retention. However, when I plotted the different wear tests they did against the measured hardness, the 36 hour cryo condition looked more like an outlier; all of the tests have a fairly simple trend with hardness apart from the 36 hour condition.
Data summary from journal article [5]
Journal article data summarized by me
So for my CATRA test I did two heat treatments, one which had no cryo and was tempered at 400°F, and one which had a 36 hour cryo and was tempered at 500°F. I did the two different tempering temperatures in an attempt to get the hardness of the two conditions the same, though the version that had no cryo actually ended up being slightly harder. Because of the higher hardness, the knife with no cryo ended up having higher edge retention. Whatever mechanisms the researchers thought would show superior wear resistance with a 36 hour cryo didn’t have enough effect to overcome a small hardness disadvantage. Therefore I think cryo has the potential to increase edge retention from wear from increased hardness, but we should question claims that other mechanisms are in play that can increase wear resistance in other ways.
Frequently Asked Questions
Which steels “need” cryo?
With virtually any steel, as long as you are using an austenitizing temperature at peak hardness or below, the steel is going to be fine. Beyond that there is excess retained austenite which reduces strength. This limits the hardness for some steels more than others. LC200N and Vanax, for example, top out around 60-61 Rc even with cryo, and a couple points less without it. Higher hardness is possible with cryo, of course, and in some cases you get an increase in hardness with little change in toughness as pointed out in the studies above.
Does cryo do anything to carbon steels and low alloy steels?
As shown earlier there was a hardness and toughness difference with 52100. And of course the study on W1 in the literature with different cold treatments. It changes things. Here is the full hardness chart on 52100 that we measured between using liquid nitrogen and without:
How long should the cryo treatment be?
Martensite forms basically instantly so it only needs to reach the temperature of the freezer, cold bath, etc. Some studies have recommended extended times for increased wear resistance but those studies are questionable. Usually 60 minutes is fine for cryo or cold treatment.
Should you temper before a cold treatment?
Tempering before a cold treatment reduces the chance of warping or cracking. However, it also stabilizes retained austenite and makes the cold treatment less effective, just like allowing the steel to sit at room temperature. Therefore I don’t recommend doing a temper beforehand. Think of cryo as an extension of the quench down to lower temperatures.
[1] Kobasko, Nikolai. “An explanation of possible Damascus steel manufacturing based on duration of transient nucleate boiling process.” In Proceedings of the 8th WSEAS international conference on fluid mechanics, 8th WSEAS international conference on Heat and mass transfer, pp. 81-86. World Scientific and Engineering Academy and Society (WSEAS), 2011.
[2] Rehan, Muhammad Arbab, Anna Medvedeva, Berne Högman, Lars‐Erik Svensson, and Leif Karlsson. “Effect of Austenitization and Tempering on the Microstructure and Mechanical Properties of a 5 wt% Cr Cold Work Tool Steel.” steel research international 87, no. 12 (2016): 1609-1618.
[3] Lement, Bernard S. Distortion in tool steels. American Society for Metals, 1959.
[4] Ducki, Kazimierz J., Jakub Jasiewicz, Grzegorz Junak, and Lilianna Wojtynek. “Effect of heat treatment on the microstructure and mechanical properties of sintered stainless tool steel.” Solid State Phenomena 226 (2014).
[5] Das, D., A. K. Dutta, and K. K. Ray. “Optimization of the duration of cryogenic processing to maximize wear resistance of AISI D2 steel.” Cryogenics 49, no. 5 (2009): 176-184.
Sup Larrin!
Nice article as usual. What do you think about several cryo cycles? For example LN directly after quenching, than temper and another one cryo (30 min. or 24 hours), one more temper after that. Does it makes any sense or is it just a marketing?
That is primarily recommended for high alloy steels that are being tempered at 950F or above where a significant amount of retained austenite is destabilized during tempering and therefore there is a “new” Ms where martensite forms on cooling from the RA. I measured retained austenite of AEB-L before and after tempering at 400F and there was no change in retained austenite meaning that the multiple cryo treatment wouldn’t have any benefit in that case. I recommend a low temper for most steels so it isn’t often useful.
Is Buderus X65Cr13 the NJSB stuff?
This is just a guess, but since NJSB uses Buderus to make their Nitro-V…..
How did you test for retained austenite? Do you own a machine or is it through some outside company?
Magnetic saturation. It is affected by carbides though you have to do some fancy work with tool steels.
Thanks for the article, I’ve read multiple articles ascribing magical properties to cryo treatments that always read like pyramid power to me, so it’s great to see your clear explanation for what’s going on. I don’t think you added much that you hadn’t already said before; but actually doing that 36 hour cryo wear comparison test has real value in a world that doesn’t quite get science.
Another brilliant article as always. I think your work may constitute the dawn of the “age of reason” for our craft.
Thanks! There are others who have tried to add more reason to the knife world, but I appreciate the compliment all the same.
Neat research with looking at cryo effect on steels austenite/martensite ratios. This has gotten me curious about non-steels, does cryo have any effect on the microstructure of say, aluminum alloys, bronze, brass etc., where hardness or toughness may see altering?
Larrin, there are some amazing results using cryo combined with severe plastic deformation like ECAP (Equal Channel Angular Pressing). I’ve mostly seen it applied to copper, and maybe ECAP without cryo for gold and silver hardening. With copper they usually get both increased hardness and ductility, or at least no loss of ductility. Would severe plastic deformation work well for knife steels, with or without cryo? I’m trying to visualize the geometry of the deformation process steps, where you’d output a partly shaped knife slab or similar, maybe a net near shape. ECAP has a bunch of right angle turns I think, and researchers normally work with small billets. Besides ECAP, there are other severe plastic deformation techniques, like High Pressure Torsion (HPT) and others.
Here’s a random recent paper by Volokitina, “Evolution of the Microstructure and Mechanical Properties of Copper under ECAP with Intense Cooling”: https://link.springer.com/article/10.1007/s11041-020-00544-x
I may not know enough about that process to give an intelligent answer. But the introduction says the issue they are trying to overcome is that the benefits of ECAP are more limited in pure metals and that the cryo treatment helped to improve its effectiveness. Given that tool steels are far from pure metals, the same limitation may not be there. ECAP is also reliant on “severe” plastic deformation and that is likely to lead to fracture in tool steels since they have so much carbide and therefore poor ductility. In this paper they said they used an ultrasonic technique instead which only worked on the surface: https://www.researchgate.net/publication/289170135_Development_of_D2_tool_steel_trimming_knives_with_nanoscale_microstructure
so unsm is shot peening on steroids? im not impressed by 800 mpa compressive stress. shot peening goes up to 2 gpa (out of memory) and no wonder the material work hardens if you start with 52 hrc.
question: is there any kind of recrystalisation of pags going on during the process or is “nano crystal” being missused in the sence that its simply a mechanical fragmentation of the structure?
I don’t know if there is any recrystallization.
if you want to get fancy with D2 look at friction stirr processing (catra up 80%). rapid cycling (→ induction) apparently also shows good results.
thank you for trying to provide some clarity into the puzzling world of metalurgical/tribological research. thwo thoughts.
1. the human mind strives to simplify the world around us and looking for linear relationships is a paramount example (e.g. ubiquious linear regression). vey often its a trap. even the assumption of a parabolic relationship (as rudimentary as it is) can be revealing. some property rises or falls, depending on which portion of the curve we look at. before we dismiss the 36 hours in a study like (5) as an outlier we should ponder the possibility of exactly this being the explanation for the inconsistencies and confusion. we expect linearity where nature doesnt provide it. why not suppose an optimum or several maxima/minima in such a function?
2. they say the wear rate seen for a steel is more an artefact of the test method than a real property. (the result depends on so many variables that it looses a practical meaning.) in the (5) study the astm g99 test uses a pin on a tungsten carbide coated disc. threfore its not surprizing to get an outcome different that when cutting cardboard or rope.
The study on D2 shows a linear relationship with hardness except for the 36 hour condition only. It’s an outlier.
Larrin, I just saw that Carpenter has a powder 440C. In their data sheet they advise *refrigeration* after quenching, at -100 F for one hour, then bringing it up to room temp before tempering.
(Link: https://www.carpentertechnology.com/hubfs/7407324/Material%20Saftey%20Data%20Sheets/Micro-Melt%20440C.pdf)
I’ve never heard of refrigeration treatment, and I’ve never seen you mention it. What’s your take on it? They’re saying to do it for maximum hardness – to get 61 – 62 RC vs. 60 without it.
I’ve also never heard of PM versions of 440C and other classic alloys. Is this new? Will it reset the values for those alloys?
That temperature of “refrigeration” would be similar to dry ice.
PM 440C has been around for years but has never made inroads in the knife industry. It has improved toughness when compared with the conventional version, of course.
Thank you for your time and effort. I have a hypotetical question for which I cannot find an answer and would appreciate it very much if you could help. I am wondering what could we expect to be the difference in blade performance between two AEB-L blades if one was cryogenic treated in liquid nitrogen and tempered at a higher temperature (350F for example) and the other one was cryogenic treated with dry ice and tempered at a lower temperature (300F for example). Let’s suppose that both were austenitized at the peak hardness. Thank you and God bless.
what are the recommend temps for Buderus X65Cr13