The Science of Knives

"A kitchen without a knife is not a kitchen."Masaharu Morimoto

Here's What Goes Into Making a Great Knife

Before you drop serious cash on a knife, bone up on what distinguishes a good knife from a great one. Different metals, shaping techniques, and manufacturing technologies all influence how a knife sharpens, dulls, feels in your hand, and holds up over the long haul.

Looking for specific recommendations among knife brands? Check out our knife buying guide here. But first, read this article, so you know a little more about what goes into making a knife that's worth the price tag.

The Backstory: General History and Physics

The first crude knives were invented more than two and half million years ago. These tools improved our ability to survive, and, apart from our hands, they have evolved into the single most important tools in food preparation and cooking. Early knives were made of flint, but most modern kitchen blades are made of metal or ceramic. Chef’s knives may be sharp enough to cut the glaze on a dinner plate, but clam, oyster, and butter knives are made intentionally dull.

Regardless of what knife you use, cutting results from various forces working between the knife and the food. The cutting edge of a knife concentrates all of the force exerted by the user on a very narrow but long area. That force delivers a fine line of pressure that’s strong enough to sever tissues, slash through plant and animal cell walls, and even cut through bone. Serrated knives further concentrate the force into a smaller area on the serrations, making cutting more swift. Sharper knives require less pressure and make cleaner cuts. This means that sharper knives damage fewer plant and animal tissues and cell walls, releasing fewer compounds from the cells, such as the sulfur compounds in onions that make us cry. Yep. If you want to shed the least tears when chopping onions, make sure you use a sharp knife.

To keep your blades at their sharpest, avoid extreme downward pressure, and cut only on knife-friendly surfaces like wood and plastic. These materials absorb some of the knife blade and delay dulling. They also make cutting steadier, swifter, and safer. Glass, stone, and metal surfaces will dull your blades quickly. Sharpen your knives whenever they are too dull to cut cleanly through the skin of a tomato without squashing the tomato. Click here for a guide to knife sharpeners.

Most knives, especially wood-handled ones, are best washed by hand to avoid discoloring the blade and damaging the handle. You should also store your knives in slots, in racks, or on a magnetic strip to protect the cutting edges from damage and dulling. A kitchen drawer full of other knives and gadgets is the best place to dull your knives in a hurry.

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Kanehiro VG10 nickel damascus black finish gyuto chef's knife 210mm

Knife Materials and Cutting Qualities

A knife’s cutting qualities are determined primarily by the material and weight of the blade, the way the blade is shaped and ground, and how the knife is constructed.

Carbon steel: Among the first metals used for making knives, carbon steel is an alloy of iron with about 0.45 to 0.5% carbon. It's inexpensive and soft enough to be easily honed to a razor-sharp edge. However, because it is soft, it tends to lose that edge more quickly than harder stainless steel. Carbon steel is also somewhat brittle and can snap under stress. Another drawback: the iron in carbon steel can discolor from acidic foods and transfer iron-like metallic flavors to foods. Carbon steel rusts easily from oxidation, so it must be kept bone dry, and it is often lubricated like cast-iron cookware to prevent rust. But carbon steel blades, eventually develop a protective patina (similar to the “seasoning” on cast-iron cookware) that helps prevent rusting and reduces the metallic flavors transferred to food. Many chefs prefer carbon steel blades because they sharpen easily.

High-carbon stainless steel: To make steel knives harder and resistant to stains, iron is alloyed with 0.45 to 0.5% carbon (as for carbon steel blades) but with the addition of 13 to 14% chromium. A 1% combination of molybdenum and vanadium is often included to improve the blade’s strength, its ability to retain an edge, and the fineness of the metal grain. It can be more difficult to get a sharp edge on a stainless steel bladebut it may last longer than that of a carbon blade.

Ultra high carbon steel: All steel that includes at least 0.5% carbon is considered “high carbon,” but very high carbon blades include more. The more carbon, the harder the metal can be made, and the finer the cutting edge can be sharpened. Very high-end chef’s knives include up to 2% carbon to help develop a razor-sharp cutting edge. There's a lot of variation among high-end knife steels, and signature alloys goes by various names, especially in Japan. White steel is so named because it lacks contaminates in the iron, resulting in a high-gloss blade preferred by many sashimi chefs. White steel #1 has the most carbon and knives made with it hold their edge the longest. But it's also the most brittle, so many chefs use white steel #2 because the knives are more durable. Blue steel is similar to white steel but also includes 2 to 2.5% tungsten and 0.2 to 0.5% chromium, which make it easier to temper the knife, produce a dense grain structure, and help the knife retain its sharp edge. As with white steel, blue steel #1 has more carbon than blue steel #2. Super blue steel adds vanadium, which helps the blade retain its edge even longer. In general, white steels can be sharpened more easily and to a finer edge, but they don't retain that edge as long as blue steels. VG10 refers to a high grade of steel that contains approximately 1% carbon, 15% chromium, 1% molybdenum, 0.2% vanadium, 1.5% cobalt, and 0.5% manganese. Aogami super steel is another high quality steel that contains about 1.5% carbon, 2.5% tungsten, 0.5% vanadium, 0.5% chromium, 0.5% molybdenum, 0.3% manganese, 0.25% phosphorus, 0.004% sulfur, and 0.2% silicon. Both VG10 and Aogami super steel are highly sought after by chefs and knife enthusiasts. The high percentage of carbon in these steels helps a knife hold its edge longer and makes it more durable. Steel hardness is measured on what's known as the Rockwell scale (named for two brothers from Connecticut) by pressing a diamond a precisely measured distance into the steel. Good high-carbon steel knives can be hardened to a Rockwell hardness in the mid 50s, and great ultra high carbon steel knives can be hardened to the mid 60s.

Laminated steel: This type of steel, sometimes called Damascus steel, combines the advantages of two or more alloys by heating, hammering, and folding several layers into a single blade, creating beautiful wavy lines. The perceived advantage of laminated or “pattern-welded” steel is that it can be made harder through intense heat treatment, but the net carbon content is lower than if you used high-carbon steel alone. Some makers of laminated steel knives and swords use only high-carbon steel at the edge of the blade for hardness and lower-carbon steel in the spine and body of the blade for flexibility.

Titanium: Compared to steel, titanium is lighter and more flexible but not as hard, so it can’t be sharpened to as fine an edge. It’s also quite expensive.

Ceramic: Made from zirconium oxide, ceramic knives are extremely hard, sharp, lighter than steel, noncorrosive, and nonreactive, and hold an edge longer than most other materials (sometimes months or years without sharpening or honing). Ceramic is very expensive and best sharpened on a special silicon carbide or diamond wheel by a professional knife sharpener. Ceramic blades can also chip or break with sudden extreme pressure, twisting, or dropping.

Plastic: Some knife blades are made of hard plastic that can be re-sharpened and used for easily cutting foods like lettuce. They’re often serrated and cheap enough to be considered disposable.

Manufacturing Methods

Even the best knife material can be ruined if it’s poorly manufactured. Among metals, forged knives tend to be the strongest and most durable because they are heated at extremely high temperatures (upwards of 1,400ºF/760ºC) and hammered into shape. Forged knives are typically heavy and thick, two advantages for tough chopping jobs but potential disadvantages for fine slicing. Stamping is a modern alternative to forging. Simply cut out of a sheet of metal, stamped blades tend to be thinner and often lack a weight-balancing bolster. While less expensive knives tend to be stamped rather than forged, when made with superior cold rolled steel, a well-made, high-quality stamped knife may actually be stronger and more durable than a low-quality forged knife.

After forging or stamping, most knives are heat-tempered to improve their strength, then ground to create the cutting edge. Taper-ground (a.k.a. flat-ground) blades are ground from the spine down to the cutting edge in a straight or convex line to form a smooth, tapered blade with no obvious beveling. Taper-ground blades are heavier, more durable, and work best in cleavers, chef’s knives, and other knives needed for heavy-duty chopping. Hollow-ground blades are ground from about the middle of the blade down to the cutting edge in a concave line that forms a beveled or fluted edge. Hollow-ground blades are typically thinner, sharper, and lighter, and work best for precision slicing and dicing of easily cut foods.

The cutting edge on a kitchen knife may be curved, flat, or serrated. Curved blades allow you to rock the blade from the tip to the heel for faster chopping and mincing. Flat blades allow you to slice across food faster because the cutting edge never curves away from the food. Serrated knives have a wavy or toothed cutting edge that helps the blade saw through foods that are stiff on the outside and soft on the inside, like bread and tomatoes. Serrated knives work well even when dull, but cutting straight down with a serrated blade will not make a clean cut.

Some knives are ground with oval-shaped recesses (also called kullens or granton edges) hollowed out of the side of the blade from the cutting edge about halfway up the blade. Often found on meat-carving knives and some Western versions of Japanese santoku knives, these recesses provide an air pocket between the blade and the food, reducing friction and improving the speed of slicing very sticky foods. Santokus tend to be slightly shorter and lighter in weight than chef's knives and are particularly well suited to slicing, chopping and mincing vegetables.

The cutting edge on most European and North American knives is ground to an angle of 18 to 22 degrees, and most are double-beveled or angled on both sides. Many Chinese and Japanese knives are made of harder tempered steel, allowing the edge to be ground to a more acute cutting angle of 10 to 16 degrees. Some Japanese knives such as usuba knives are also ground to an edge on only one side (beveled inwards on one side only) and sold in left-handed and right-handed models.

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Once the blade is shaped and ground, its opposite end, the tang, is incorporated into a handle. A full tang that’s as wide as the blade and extends all the way to the opposite end of the handle creates a more durable knife that’s well suited to heavy work such as hacking through bones. A tang that extends only three-quarters of the way through the handle or that is thinner and narrower than the blade (a rat-tail tang) makes the knife less durable and more difficult to balance. The point where the blade meets the handle is called the bolster, and thicker bolsters help to balance the knife and make it steadier and more durable. The closeup below shows two different types of bolsters: the top knife (wooden handle) has a full bolster extending from the top to the bottom of the blade. The bottom knife has a bolster only at the top of the blade.  

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The handle can be made of the same metal as the blade or of stone, bone, ivory, leather, wood, resin-impregnated wood, rubber, or plastic. Rosewood is very traditional and popular because its density and fine grain are soft on the hands, provide good grip, and help prevent the wood from splitting or cracking. Woods impregnated with resin (black composite handles) improve durability and make the handle easier to keep clean. If the handle is riveted to the tang, the rivets should be flush with the surface of the handle to eliminate nooks and crannies where bacteria can grow. Plastic (polypropylene) handles are permanently molded around the tang with no seam and are often preferred (or required by law in some places) in busy professional kitchens because they are lightweight, can be easily sanitized, and don’t absorb microorganisms as readily as other handles. Metal handles are the most durable and heaviest; they’re often textured with dimples or ridges to provide better grip. The handle is a personal choice but an important one because it's where you interface with the knife.

Once you've decided on your preferred metals and manufacturing methods, visit a cookware store and pick up a few different knives. Pay attention to the handle materials and shapes until you find a knife that feels good in your hand. When the handle feels comfortable, the knife feels balanced overall, and the blade feels invincible, you will know you've found the right knife for you. For more detailed recommendations on particular knives and brands, check out our knife buying guide here.

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This article has been adapted with permission from The Science of Good Food: The Ultimate Reference on How Cooking Works by David Joachim and Andrew Schloss (Robert Rose, 2008). Click here to check prices on Amazon.

takeda aogami super steel knife on cutting board

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