Metal Metal pots are made from a narrow range of metals because pots and
pans need to
conduct heat well, but also need to be
chemically unreactive so that they do not alter the flavor of the food. Most materials that are conductive enough to heat evenly are too reactive to use in food preparation. In some cases (copper pots, for example), a pot may be made out of a more reactive metal, and then
tinned or clad with another. While metal pots take heat very well, they usually react poorly to rapid cooling, such as being plunged into water while hot, this will usually warp the piece over time.
Aluminium Aluminium is a lightweight metal with very good thermal conductivity. It is resistant to many forms of corrosion. Aluminium is commonly available in sheet, cast, or anodized forms, and may be physically combined with other metals (see below). Sheet aluminium is spun or stamped into form. Due to the softness of the metal, it may be alloyed with magnesium, copper, or bronze to increase its strength. Sheet aluminium is commonly used for baking sheets, pie plates, and cake or muffin pans. Deep or shallow pots may be formed from sheet aluminium. Cast aluminium can produce a thicker product than sheet aluminium, and is appropriate for irregular shapes and thicknesses. Due to the microscopic pores caused by the casting process, cast aluminium has a lower thermal conductivity than sheet aluminium. It is also more expensive. Accordingly, cast aluminium cookware has become less common. It is used, for example, to make
Dutch ovens lightweight and
bundt pans heavy duty, and used in ladles and handles and
woks to keep the sides at a lower temperature than the center.
Anodized aluminium has had the naturally occurring layer of
aluminium oxide thickened by
an electrolytic process to create a surface that is hard and non-reactive. It is used for sauté pans, stockpots, roasters, and Dutch ovens. Uncoated and un-anodized aluminium can react with acidic foods to change the taste of the food. Sauces containing egg yolks, or vegetables such as asparagus or artichokes may cause oxidation of non-anodized aluminium. Aluminium exposure has been suggested as a risk factor for
Alzheimer's disease. Of one of which its proponents is Prof.
Christopher Exley, who has published his findings. However, the Alzheimer's Association states that "studies have failed to confirm any role for aluminum in causing Alzheimer's." The link remains controversial. castle
Copper Copper provides the highest thermal conductivity among non-
noble metals and is therefore fast
heating with unparalleled heat distribution
(see: Copper in heat exchangers). Pots and pans are
cold-formed from copper sheets of various thicknesses, with those in excess of 2.5 mm considered commercial (or
extra-fort) grade. Between 1 mm and 2.5 mm wall thickness is considered utility (
fort) grade, with thicknesses below 1.5 mm often requiring
tube beading or
edge rolling for reinforcement. Less than 1mm wall thickness is generally considered decorative, with exception made for the case of .75–1 mm
planished copper, which is
hardened by hammering and therefore expresses performance and strength characteristic of thicker material. Copper thickness of less than .25 mm is, in the case of cookware, referred to as
foil and must be formed to a more structurally rigid metal to produce a serviceable vessel. Such applications of copper are purely aesthetic and do not materially contribute to cookware performance. Copper is reactive with acidic foods which can result in corrosion, the byproducts of which can foment
copper toxicity. In certain circumstances, however, unlined copper is recommended and safe, for instance in the preparation of
meringue, where copper ions prompt proteins to denature (unfold) and enable stronger protein bonds across the sulfur contained in egg whites. Unlined copper is also used in the making of preserves, jams and jellies. Copper does not store ("bank") heat, and so thermal flows reverse almost immediately upon removal from heat. This allows precise control of consistency and texture while cooking sugar and pectin-thickened preparations. Alone, fruit acid would be sufficient to cause leaching of copper byproducts, but naturally occurring fruit sugars and added preserving sugars buffer copper reactivity. Unlined pans have thereby been used safely in such applications for centuries. Lining copper pots and pans prevents copper from contact with
acidic foods. The most popular lining types are
tin,
stainless steel,
nickel and
silver. The use of tin dates back many centuries and is the original lining for copper cookware. Although the patent for
canning in sheet tin was secured in 1810 in England, legendary French chef
Auguste Escoffier experimented with a solution for provisioning the French army while in the field by adapting the tin lining techniques used for his cookware to more robust steel containers (then only lately introduced for canning) which protected the cans from corrosion and soldiers from lead solder and
botulism poisoning. Tin linings sufficiently robust for cooking are wiped onto copper by hand, producing a 35–45 μm thick lining. Decorative copper cookware, i.e., a pot or pan less than 1 mm thick and therefore unsuited to cooking, will often be
electroplate lined with tin. Should a wiped tin lining be damaged or wear out the cookware can be re-tinned, usually for much less cost than the purchase price of the pan. Tin presents a smooth crystalline structure and is therefore relatively non-stick in cooking applications. As a relatively soft metal abrasive cleansers or cleaning techniques can accelerate wear of tin linings. Wood, silicone or plastic implements are to preferred over harder stainless steel types. For a period following the Second World War, copper cookware was
electroplated with a nickel lining. Nickel is harder and more thermally efficient than tin, with a higher melting point. Despite its hardness, it wore out as fast as tin, as the plating was 20 microns thick or less, as nickel tends to plate somewhat irregularly, and requires milling to produce an even cooking surface. Nickel is also stickier than tin or silver. Copper cookware with aged or damaged nickel linings can be retinned, or possibly replating with nickel, although this is no longer widely available. Nickel linings began to fall out of favor in the 1980s owing to the isolation of nickel as an allergen. Silver is also applied to copper by means of electroplating, and provides an interior finish that is at once smooth, more durable than either tin or nickel, relatively non-stick and extremely thermally efficient. Copper and silver bond extremely well owing to their shared high
electro-conductivity. Lining thickness varies widely by maker, but averages between 7 and 10 microns. The disadvantages of silver are expense and the tendency of sulfurous foods, especially
brassicas, to discolor. Worn silver linings on copper cookware can be restored by stripping and re-electroplating. Copper cookware lined with a thin layer of stainless steel is available from most modern European manufacturers. Stainless steel is 25 times less thermally conductive than copper, and is sometimes critiqued for compromising the efficacy of the copper with which it is bonded. Among the advantages of stainless steel are its durability and corrosion resistance, and although relatively sticky and subject to food residue adhesions, stainless steel is tolerant of most abrasive cleaning techniques and metal implements. Stainless steel forms a pan's structural element when bonded to copper and is irreparable in the event of wear or damage. Using modern metal
bonding techniques, such as
cladding, copper is frequently incorporated into cookware constructed of primarily dissimilar metal, such as stainless steel, often as an enclosed diffusion layer (see
coated and composite cookware below).
Cast iron Cast-iron cookware is slow to heat, but once at temperature provides even heating. Cast iron can also withstand very high temperatures, making cast iron pans ideal for
searing. Being a reactive material, cast iron can have
chemical reactions with high acid foods such as
wine or
tomatoes. In addition, some foods (such as
spinach) cooked on bare cast iron will turn black.
Cast iron is a somewhat brittle, porous material that rusts easily. As a result, it should not be dropped or heated unevenly and it typically requires
seasoning before use. Seasoning creates a thin layer of oxidized
fat over the iron that coats and protects the surface from corrosion, and prevents sticking. Enamelled, non-decorative, cast-iron cookware first appeared in the German states, during the 1760s, became popular in the late 19th century, and its manufacture spread from Europe to North America in the last decades of the 19th century, through German immigrants founding the likes of
The Vollrath Company. In 1934, the French company
Cousances designed the enameled cast iron Doufeu to reduce excessive evaporation and scorching in cast iron Dutch ovens. Modeled on old braising pans in which glowing charcoal was heaped on the lids (to mimic two-fire ovens), the Doufeu has a deep recess in its lid which instead is filled with ice cubes. This keeps the lid at a lower temperature than the pot bottom. Further, little notches on the inside of the lid allow the moisture to collect and drop back into the food during the cooking. Preheat the pan for a few minutes before adding oil. Cast iron needs time to warm up, and a properly heated surface reduces sticking. Also, use slightly more oil during the first few uses. As the seasoning improves, food releases more easily. Cleaning and drying your pan correctly keeps the surface smooth for the next meal.Enameled cast-iron cookware, unlike uncoated cast-iron, is minimally reactive thus can be used with acidic food.
Stainless steel Stainless steel is an iron alloy containing a minimum of 11.5% chromium. Blends containing 18% chromium with either 8% nickel, called
18/8, or with 10% nickel, called 18/10, are commonly used for kitchen cookware. Stainless steel's virtues are resistance to corrosion, non-reactivity with either alkaline or acidic foods, and resistance to scratching and denting. Stainless steel's drawbacks for cooking use include its relatively poor thermal conductivity. Since the material does not adequately spread the heat itself, stainless steel cookware is generally made as a cladding of stainless steel on both sides of an aluminum or copper core to conduct the heat across all sides, thereby reducing "hot spots", or with a disk of copper or aluminum on just the base to conduct the heat across the base, with possible "hot spots" at the sides. Typical 18/10 stainless steel also has a relatively low
magnetic permeability, making it incompatible with
induction cooktops. Recent developments have allowed the production of
ferromagnetic 18/10 alloys with a higher permeability. In so-called "tri-ply" cookware, the central aluminum layer is paramagnetic, and the interior 18/10 layer may also, but the exterior layer at the base must be ferromagnetic to be compatible with induction cooktops. Stainless steel does not require seasoning to prevent rust, but it may be seasoned to create a non-stick surface.
Carbon steel Carbon-steel cookware can be rolled or hammered into relatively thin sheets of dense material, which provides robust strength and improved heat distribution. Carbon steel accommodates high, dry heat for such operations as dry searing. Carbon steel does not
conduct heat efficiently, but this may be an advantage for larger vessels, such as woks and
paella pans, where one portion of the pan is intentionally kept at a different temperature than the rest. Like cast iron, carbon steel must be
seasoned before use, usually by rubbing a fat or oil on the cooking surface and heating the cookware on the stovetop or in the oven. With proper use and care, seasoning oils polymerize on carbon steel to form a low-tack surface, well-suited to browning,
Maillard reactions and easy release of fried foods. Carbon steel will easily rust if not seasoned and thoroughly dried after cleaning, and should be stored seasoned to avoid rusting. Carbon steel is traditionally used for
crêpe and fry pans, as well as woks.
Clad aluminium or copper Cladding is a technique for fabricating pans with a layer of efficient heat conducting material, such as copper or aluminum, covered on the cooking surface by a non-reactive material such as stainless steel, and often covered on the exterior aspect of the pan ("dual-clad") as well. Some pans feature a copper or aluminum interface layer that extends over the entire pan rather than just a heat-distributing disk on the base. Generally, the thicker the interface layer, especially in the base of the pan, the more improved the heat distribution. However, claims of improved
thermal efficiency are controversial, mainly due to the limiting and heat-retaining effects of stainless steel on heat flow. Aluminum is typically clad on both the inside and the exterior pan surfaces, providing both a stainless cooking surface and a stainless surface to contact the cooktop. Copper of various thicknesses is often clad on its interior surface only, leaving the more attractive copper exposed on the outside of the pan (see Copper above). Some cookware use a dual-clad process, with a thin stainless layer on the cooking surface, a thick core of aluminum to provide structure and improved heat diffusion, and a foil layer of copper on the exterior to provide the "look" of a copper pot at a lower price.
Coating Enamel over steel Enameled cast iron cooking vessels are made of cast iron covered with a porcelain surface. This creates a piece that has the heat distribution and retention properties of cast iron combined with a non-reactive, low-stick surface. Such pots are much lighter than most other pots of similar size, are cheaper to make than stainless steel pots, and do not have the rust and reactivity issues of cast iron or carbon steel. Enamel over steel is ideal for large stockpots and for other large pans used mostly for water-based cooking. Because of its light weight and easy cleanup, enamel over steel is also popular for cookware used while camping.
Seasoning s, before seasoning (left) and after several years of use (right) requiring seasoning
Seasoning is the process of treating the surface of a cooking vessel with a dry, hard, smooth,
hydrophobic coating formed from polymerized fat or oil. When seasoned surfaces are used for cookery in conjunction with oil or fat a
stick-resistant effect is produced. Some form of post-manufacturing treatment or end-user seasoning is mandatory on
cast-iron cookware, which
rusts rapidly when heated in the presence of available oxygen, notably from water, even small quantities such as drippings from dry meat. Food tends to stick to unseasoned iron and
carbon steel cookware, both of which are seasoned for this reason as well. Other cookware surfaces such as stainless steel or cast aluminium do not require as much protection from corrosion but seasoning is still very often employed by professional chefs to avoid sticking. Seasoning of other cookware surfaces is generally discouraged. Non-stick enamels often crack under heat stress, and non-stick polymers (such as Teflon) degrade at high heat so neither type of surface should be seasoned.
Non-stick Many modern cookware items feature
PTFE-based (Teflon) or ceramic-based coatings designed to minimize food sticking and make cleanup easier. There are advantages and disadvantages to such a coating. Coated pans are easier to clean than most non-coated pans, and require little or no additional oil or fat to prevent sticking, a property that helps to produce lower fat food. On the other hand, some sticking is required to cause
sucs to form, so a non-stick pan cannot be used where a pan sauce is desired. Non-stick coatings tend to degrade over time and are susceptible to damage. Using metal implements, harsh scouring pads, or chemical abrasives can damage or destroy cooking surface. According to health experts, PTFE coatings remain stable during normal cooking but begin to degrade at around 260 °C (500 °F), potentially releasing harmful fumes associated with "polymer fume fever" or "Teflon flu" in humans—and dangerous toxins for pet birds—if overheated. While older PTFE pans contained PFOA—a now-banned chemical—modern PTFE coatings are PFOA-free and considered safe by agencies like the FDA and EFSA when used correctly at recommended temperatures. Ceramic coatings, typically derived from silica sol‑gel and free of PFAS, can tolerate higher heat thresholds (up to ~370 °C/700 °F) compared to PTFE. However, they often wear out faster and are more prone to abrasion than PTFE variants. Non-stick pans must not be overheated. The coating is stable at normal cooking temperatures, even at the
smoke point of most oils. However, if a non-stick pan is heated while empty its temperature may quickly exceed , above which the non-stick coating may begin to deteriorate, changing color and losing its non-stick properties. To maximize cookware lifespan and safety, regulators and food agencies recommend: - Avoid preheating empty non-stick pans on high heat - Use low to medium heat cooking - Ensure kitchen ventilation during use - Replace pans if the coating shows scratches, peeling, or visible wear
Diamond over carbon steel Vacuum-brazed diamond cookware is produced by bonding
diamond particles to a
carbon steel base using a high-temperature (approximately 850–950 °C) vacuum brazing process. This technique is intended to minimize
oxidation while creating a durable, scratch-resistant surface. Diamond's high
thermal conductivity (900–2320 W/mK) promotes rapid and even heat distribution, which can be advantageous for high-heat cooking methods such as
searing and
stir-frying. Hydrogen termination of the diamond particles may further enhance non-stick properties by increasing surface
hydrophobicity, and in some designs,
silicone resin fillers are used to improve coating integrity. Although it is marketed as a robust alternative to conventional
non-stick finishes, its long-term durability remains under study.
Non-metallic cookware Non-
metallic cookware can be used in both conventional and
microwave ovens. Non-metallic cookware typically can not be used on the stovetop, with the exception of glass-ceramic cookware. Rigid non metallic cookware tends to shatter on sudden cooling or uneven heating, although low expansion materials such as borosilicate glass and glass-ceramics have significant immunity.
Pottery Pottery has been used to make cookware from before dated history.
Pots and pans made with this material are durable (some could last a lifetime or more) and are inert and non-reactive. Heat is also conducted evenly in this material. They can be used for both cooking in a fire pit surrounded with coals and for baking in the oven.
Ceramics Glazed ceramics, such as
porcelain, provide a nonstick cooking surface. Historically some glazes used on
ceramic articles contained levels of
lead, which can possess health risks; although this is not a concern with the vast majority of modern ware. Some pottery can be placed on fire directly.
Glass Borosilicate glass is safe at oven temperatures. The clear glass also allows for the food to be seen during the cooking process. However, it cannot be used on a stovetop, as it cannot cope with stovetop temperatures.
Glass-ceramic Glass ceramic is used to make products such as Corningware and
Pyroflam, which have many of the best properties of both glass and ceramic cookware. While
Pyrex can shatter if taken between extremes of temperature too rapidly, glass-ceramics can be taken directly from deep freeze to the stove top. Their very low
coefficient of thermal expansion makes them less prone to
thermal shock.
Stone A natural stone can be used to diffuse heat for
indirect grilling or baking, as in a
baking stone or
pizza stone, or the French
pierrade.
Silicone to be placed in a pot of boiling water
Silicone bakeware is light, flexible and able to withstand sustained temperatures of 220 °C (428 °F). It melts around 500 °C (930 °F), depending upon the fillers used. Its flexibility is advantageous in removing baked goods from the pan. This rubbery material should not be confused with the
silicone resin used to make hard, shatterproof children's dishware, which is not suitable for baking. ==Types of cookware and bakeware==