Uses, Grades, and Compositions of Stainless Steel 316

Stainless Steel 316 and 316L: Uses, Grades and Composition

Stainless Steel Grade 316 (UNS S31600) and Grade 316L (UNS S31603)

Introduction

This article offers detailed information about stainless steel 316.

You will learn:

What is Stainless Steel 316?
The Grades and Properties of Stainless Steel 316
Stainless Steel Grade 316 Compared to Other Stainless Steel Grades
Stainless Steel 316 Composition
And much more��

Stainless Steel Grade 316 Spec Sheet
316	316L
ASTM A240	ASTM A240
ASTM A666	ASTM A666
ASME SA240	ASME SA240
AMS 5524	AMS 5507

Chapter One �� What is Stainless Steel 316?

Stainless steel is a type of alloy composed of at least 10% chromium, a key element that gives it corrosion resistance. The chromium develops a protective oxide film on the metal's surface, shielding it from corrosive factors.

Among the various grades, stainless steel 316 is quite prevalent. It generally consists of 16 to 18% chromium, 10 to 14% nickel, 2 to 3% molybdenum, and traces of carbon. The inclusion of molybdenum enhances the corrosion resistance of stainless steel 316 when compared to other grades, with additional alloying improving its overall attributes.

The characteristics and advantages of stainless steel 316 make it the second most frequently used grade, right behind stainless steel 304. It is especially suitable for corrosive settings like chemical plants, refineries, and marine applications.

Graph of Metals Used to Produce Stainless Steel 316

Stainless steel 316L, a low-carbon variant, is favored in cases where sensitization could be a problem. In contrast, stainless steel 316H has an increased carbon content, offering better thermal stability and creep resistance. Another variant, stainless steel 316Ti, is stabilized for enhanced resistance to intergranular corrosion.

Stainless steel benefits significantly from passivation, a process that makes the metal "passive" or resistant to oxidation in corrosive environments and process fluids. This is accomplished by exposing the stainless steel to air, allowing the formation of a protective layer of chromium oxides on its surface.

To bolster the formation of the passive film, stainless steel is treated chemically in acidic passivation baths, which typically include nitric acid. This cleaning process eradicates impurities such as free iron or iron compounds that could compromise the passive layer.

After the acidic treatment, the metal is neutralized in a sodium hydroxide bath. Furthermore, a descaling procedure is used to remove oxide films that develop during high-temperature operations like hot-forming, welding, and heat treatment.

Chapter Two �� How do stainless steel grades compare to stainless steel 316?

Stainless steel 316 distinguishes itself by its significant molybdenum content, imparting exceptional resistance to corrosion, particularly against chlorides and harsh chemical environments. Recognized as the second most widely used austenitic stainless steel after grade 304, stainless steel 316 offers advanced performance in demanding applications such as marine, pharmaceutical, food processing, and chemical processing industries. Austenitic stainless steels, such as 304 and 316, are characterized by their high nickel or nitrogen content, which provides a unique, non-magnetic crystalline structure and remarkable durability at a range of operating temperatures.

Stainless steels are systematically grouped based on their chemical composition, mechanical properties, metallurgical structure, and their intended industrial applications. The four primary families are: ferritic, martensitic, austenitic, and duplex stainless steels. Duplex stainless steels represent a hybrid classification, combining properties of two or more parent families—such as martensitic-ferritic or austenitic-ferritic—resulting in alloys with balanced mechanical strength and corrosion resistance. Each family’s fundamental matrix structure directly influences its performance capabilities, making the selection of the proper grade crucial for specific engineering and manufacturing requirements.

Within these families, stainless steel is further subdivided into grades to precisely describe the properties and chemical makeup of each alloy. Legacy grades are assigned three-digit numbers by the Society of Automotive Engineers (SAE), while alternative classification systems—such as the six-digit ASTM/UNS system used in North America—provide additional detail. Regardless of the numeric system, each stainless steel grade must strictly comply with its specified alloy composition and regulated content of elements like chromium, nickel, carbon, and molybdenum, as these directly impact corrosion resistance, mechanical strength, and other key properties. Even minor modifications in alloying elements can cause significant changes in how a stainless steel grade performs, especially in aggressive or specialized environments.

For engineers and purchasers evaluating different types of stainless steel, understanding these grade variations is essential. Different grades offer diverse levels of corrosion resistance, tensile strength, ductility, hardness, temperature stability, and wear resistance. The primary factor influencing these characteristics is the alloy’s microstructure, visible under a microscope (often at 25x magnification). The microstructure—determined by the ratios and types of alloying elements—dictates suitability for applications such as construction, medical devices, foodservice equipment, and chemical storage tanks.

Within stainless steel 316, the refined cellular microstructure features boundaries enriched with chromium, manganese, molybdenum, and niobium. This microstructural enrichment fosters its enhanced corrosion resistance and pitting resistance, especially in acidic or chloride-rich settings like seawater, desalination plants, and chemical production. The fine distribution of chromium and molybdenum along the boundary zones has a direct impact on the alloy’s durability and performance longevity, even under continuous exposure to harsh industrial chemicals or saline environments.

Austenitic Stainless Steels: The austenitic stainless steel family stands out for its non-magnetic properties, high chromium and nickel content, excellent ductility, and low levels of carbon—making these alloys the most popular choice globally. Used extensively in sectors demanding superior corrosion resistance and weldability, such as architecture, food processing, and pharmaceuticals, the austenitic grades also maintain their strength at both elevated and cryogenic temperatures.

The hallmark of austenitic stainless steels is their face-centered cubic (FCC) crystal structure, developed through the addition of nickel and, in some cases, nitrogen. This grain structure guarantees superior impact toughness and flexibility, vital for high-stress environment use. Notably, these steels retain steady mechanical properties across a wide range, offering outstanding formability and the ability to be fabricated into complex shapes or components.

Austenitic stainless steels cannot be hardened by heat treatment; instead, they are work-hardened through cold working processes, enhancing their strength, hardness, and resistance to cracking or deformation. Their innate non-magnetic character is maintained after annealing but some cold-working may induce partial magnetism, which is a key consideration for buyers seeking non-magnetic materials for critical components.

The principal alloying element in the 300 series austenitic stainless steels—including grades 304, 304L, 316, and 316L—is nickel, which typically ranges from 6% to 20%. Grade 316, for example, is known as a Cr-Ni-Mo system because of its additional 2-3% molybdenum content. Series 200 stainless steels, in contrast, contain lower nickel and higher nitrogen, resulting in a slightly reduced corrosion resistance profile and changes in mechanical properties. The selection between 200 and 300 series should be based on required corrosion resistance, cost, and specific application environment.

Stainless Steel 300 Series:
Austenitic 300 series stainless steels, such as 304 and 316, are renowned for their excellent corrosion resistance, superior strength-to-weight ratios, weldability, and adaptability to various fabrication techniques. Their nickel-rich composition ensures stability across temperature extremes, making them ideal for applications like pressure vessels, processing equipment, piping, and kitchen appliances.
Series 304 - The most widely utilized stainless steel, series 304, delivers high tensile strength (621 MPa or 90 Ksi) and can withstand operational temperatures up to 1598°F (870°C). Frequently selected for its great corrosion resistance in mildly corrosive environments, 304 stainless is a workhorse material for food and beverage processing, chemical containers, and architectural trim.
Series 316 - The next most popular stainless steel is grade 316, offering a tensile strength of 549 MPa (84 Ksi) and a maximum service temperature of 1472°F (800°C). The addition of molybdenum dramatically improves its resistance to chlorides and marine exposure as well as acidic and caustic chemicals. For this reason, stainless steel 316 is widely used in marine applications, chemical tanks, food processing equipment exposed to salt, and medical implants.

In direct comparison, the key factor separating stainless steel 304 and 316 is series 316's molybdenum content. This not only heightens resistance to localized corrosion such as pitting (especially in the presence of chlorides, phosphoric acid, or acetic acid) but also bolsters heat and wear resistance. As a result, 316 offers greater versatility in aggressive industrial and marine environments where exposure to saltwater, bleach, or acidic solutions can jeopardize material integrity. For projects seeking both strength and corrosion resistance, particularly with exposure to harsh chemicals or seawater, 316 is often the optimal stainless steel choice.

Want to choose between stainless steel 304 vs. 316 for your next project? Consider key criteria such as corrosion risk (chloride or salt exposure), required tensile strength, fabrication methods (weldability, formability), service temperature, and budget. Suppliers and stainless steel manufacturers can help you evaluate material certifications and compliance (such as ASTM, ASME, and ISO standards) relevant to your industry.

Comparison of the Elements of Series 304 Stainless Steel and Series 316 Stainless Steel
	Type 304	Type 316
Carbon	0.08% Max	0.08% Max
Manganese	2.00% Max	2.00% Max
Phophorus	0.045% Max	0.045% Max
Sulfer	0.030% Max	0.030% Max
Silicon	1.00% Max	1.00% Max
Chromium	18.00 - 20.00	16.00 - 18.00
Nickel	8.00 - 10.50%	10.00 - 14.00
Molybdenum	-	2.00 - 3.00%

Ferritic Stainless Steels: Ferritic stainless steels exhibit a body-centered cubic (BCC) microstructure, stabilized by high chromium content with negligible amounts of nickel. This consistent ferritic phase renders them inherently magnetic and resistant to scaling at elevated temperatures, but more challenging to weld than austenitic grades due to grain growth and intermetallic precipitation at high temperatures. These alloys are typically specified under the AISI 400 series designation, and are favored in applications that require good resistance to stress corrosion and oxidation, such as automotive exhaust systems, industrial equipment, and kitchenware.
Martensitic Stainless Steels: Martensitic stainless steels are uniquely defined by higher carbon content, which allows them to be hardened through heat treatment. When rapidly cooled (quenched) from the austenitic phase, they develop a martensitic microstructure that is strong and hard but less ductile, making them excellent candidates for tools, blades, turbine components, and wear-resistant parts. Adjusting the carbon concentration enables a wide spectrum of hardness and strength profiles, though this comes at the expense of some corrosion resistance compared to other families. Like ferritic steels, martensitic stainless is commonly identified within the AISI 400 series.
Duplex Stainless Steels: Duplex stainless steels combine approximately equal proportions of austenitic and ferritic microstructures, achieved by carefully balancing chromium and nickel content—often with added molybdenum or nitrogen. This dual-phase composition offers a unique combination of higher strength and improved resistance to stress corrosion cracking, especially in chloride-rich or caustic environments. Their balanced properties make duplex grades ideal for oil and gas, desalination, chemical processing, and structural applications demanding both mechanical strength and superior corrosion resistance. The most prevalent grade is duplex 2205 stainless steel, which is widely available from global stainless steel suppliers.
Precipitation Hardening Stainless Steels: These highly specialized stainless steels are designed for further strengthening through precipitation hardening—a heat treatment process that introduces fine secondary phase particles into the metal’s structure. Elements like copper, niobium, aluminum, and titanium are used to form these precipitates, refining the alloy’s mechanical performance without sacrificing essential corrosion resistance. Precipitation hardening grades are typically employed in aerospace, nuclear, and high-performance engineering applications where a balance of strength, toughness, and corrosion resistance is paramount.

Choosing the Right Stainless Steel Grade for Your Application
When selecting between stainless steel grades—such as 304, 316, duplex 2205, or specialty alloys—consider environmental exposure, required mechanical properties, industry standards, and cost factors. Thoroughly review the alloy certifications and consult with trusted stainless steel suppliers and manufacturers to ensure compliance with regulations (like ASTM or ISO) and suitability for your specific use case. By understanding the distinct characteristics and applications of each stainless steel family and grade, purchasers and engineers can confidently source the optimal material to maximize performance, safety, and value in their projects.

Chapter Three �� Who are the Top Producers of Stainless Steel 316?

Source 21, Inc.

Source 21, Inc. is a leading stainless steel 316 supplier specializing in the distribution of stainless steel coils and strips, including both 316 and 316L stainless steel grades. Their extensive processing capabilities encompass coil cutting to length, surface polishing for aesthetic and corrosion resistance, masking for enhanced protection, as well as tempering for optimal mechanical strength. Source 21 supplies finished stainless steel products packaged in custom boxes, export crates, or specialized skid mounts, catering to the unique requirements of their clients. Major industries served include aerospace, roll forming, automotive manufacturing, and food processing equipment fabrication. By offering custom stainless steel solutions—from standard grades to premium alloys—Source 21 supports applications where durability, formability, and resistance to harsh environments are critical. Their commitment to precision processing and customer-focused service makes them a preferred partner for manufacturers seeking high-performance stainless steel 316 for structural, hygienic, and high-temperature uses.

Cleveland-Cliffs Inc.

Cleveland-Cliffs Inc. stands out as a leading producer of flat-rolled stainless steel in North America. With integrated operations that include iron ore mining in Michigan and Minnesota, the company maintains superior quality control throughout the stainless steel production chain. Cleveland-Cliffs produces all five principal types of stainless steel, including widely used 304, 304L, and high-corrosion resistance 316 stainless steel. Their products are engineered for demanding environments, making them a preferred source for automotive manufacturing, industrial fabrication, and construction. Their commitment to steel recycling, sustainability, and environmentally responsible manufacturing processes aligns with modern industry standards. Cleveland-Cliffs serves a broad clientele, offering custom specifications and material certifications that support diverse user requirements for strength, formability, and corrosion resistance, especially in sectors requiring reliable marine-grade alloys and cut-edge technology.

Allegheny Technologies (ATI)

Allegheny Technologies (ATI) is a renowned specialty metals manufacturer, producing a wide variety of stainless steel grades, including premium austenitic, ferritic, superaustenitic, and superferritic alloys. ATI's stainless steel portfolio includes high-performance materials engineered for exceptional resistance to corrosion, oxidation, and high temperatures. They utilize advanced processes such as hot rolling and precision finishing, enabling them to deliver stainless steel in a broad range of thicknesses and dimensions suitable for critical applications. ATI is recognized for rapid order fulfillment and short lead times, which is valuable for industries requiring immediate supply, like energy, chemical processing, aerospace, and heavy equipment manufacturing. Their innovative approach ensures their products are ideal for food-grade equipment, medical instruments, and architectural components, reinforcing ATI’s reputation as a solutions provider of high-quality 316 stainless steel and related alloys.

Acerinox

Acerinox S.A., headquartered in Spain, is an internationally respected manufacturer of stainless steel products for a variety of industries. With a diversified production portfolio that includes stainless steel plates, hot and cold-rolled coils, sheets, strips, and discs, Acerinox delivers to customers serving the transportation, industrial equipment, food processing, and environmental technology sectors. Their focus on innovation, material consistency, and global distribution ensures that clients can specify stainless steels—like the versatile 316 grade—in the form, finish, and tolerance that best suits sophisticated engineering and manufacturing needs. The company's advanced metallurgy, rigorous quality assurance, and strong export capabilities make it a favored supplier among businesses seeking international stainless steel sourcing solutions for applications where corrosion resistance, sanitation, and long service life are non-negotiable.

Aperam

Aperam is a globally recognized supplier of high-performance stainless steel 316 and 316L products, delivering materials to more than 40 countries. With an annual production capacity of 2.5 million tons spanning five cutting-edge facilities, Aperam manufactures coils, sheets, tubes, discs, flat bars, strips, and heavy plates that meet stringent international standards. Their Sterling Heights, Michigan service center specializes in flat stainless steel, offering tailored solutions for industries ranging from architectural construction and automotive to chemical processing and renewable energy. Aperam emphasizes sustainability through eco-conscious manufacturing and the use of recycled materials, with a notably low CO₂ footprint. Their commitment to continual innovation, technical support, and traceable product quality positions Aperam as a trusted supplier of advanced stainless steel 316 products for customers prioritizing environmentally responsible sourcing alongside high mechanical and corrosion performance.

Choosing the Right Stainless Steel 316 Supplier

When selecting a stainless steel 316 manufacturer or distributor, it is essential to consider factors such as certified quality processes (including ISO 9001 accreditation), availability of custom fabrication services, technical support, and fast delivery options. Users in industries like pharmaceutical processing, food handling, marine construction, and petrochemical applications frequently require materials traceability, specialized surface finishes, and documentation to comply with regulatory standards. Innovative suppliers also offer value-added solutions like precision slitting, laser cutting, welding, and component assembly, enabling customers to streamline production efficiency and minimize waste. To determine the best fit for your project, compare suppliers based on their range of 316 and 316L stainless steel inventory, responsiveness to inquiries, and proven track record in supporting project-specific requirements.

Leading Manufacturers and Suppliers

Chapter Four �� What are the composition and alloying elements of stainless steel 316?

As discussed earlier, stainless steel 316 is part of the austenitic family, where nickel acts as a stabilizer for the austenitic structure. The typical composition of stainless steel 316 includes 16��18% chromium, 10��14% nickel, 2��3% molybdenum, up to 2% manganese, up to 0.75% silicon, up to 0.10% nitrogen, up to 0.08% carbon, up to 0.045% phosphorus, up to 0.03% sulfur, with iron making up the remainder. Additional alloying elements like titanium and niobium may be included to produce other grades. The compositions of various stainless steel grades are summarized below.


Grade	Alloying Elements (Percent)
Grade	C	Cr	Ni	Mo	Mn	Si	N	P	S	Others
316	0.08	16-18	10-14	2-3	2.0	0.75	0.10	0.045	0.03
316L	0.03	16-18	10-14	2-3	2.0	0.75	0.10	0.045	0.03
316H	0.04 - 0.10	16-18	10-14	2-3	2.0	0.75		0.045	0.03
316Ti	0.08	16-18	10-14	2-3	2.0	0.75	0.10	0.045	0.03	�վ�¹
316Cb	0.08	16-18	10-14	2-3	2.0	0.75	0.10	0.045	0.03	��²
316N	0.03	16-18	10-14	2-3	2.0	0.75	0.10 - 0.16	0.045	0.03
316LN	0.03	16-18	10-14	2-3	2.0	0.75	0.10 - 0.16	0.045	0.03

Notes:

The minimum amount of titanium is calculated as 5 x (C + N). The maximum amount is 0.70%.
Columbium (Cb) is now known as Niobium (Nb). The minimum amount of niobium is calculated as 10 x (C + N). The maximum amount is 1.10%.

Effect of Alloying Elements

The alloying elements of stainless steel 316 and their effects on the properties of the alloy are listed below.

Carbon: This is the main alloying element of steel. Iron alone has poor mechanical properties, but when alloyed with varying amounts of carbon imparts a wide range of hardness and strength. Adding carbon makes the steel harder and stronger but more brittle. Decreasing it improves ductility. Also, adding sufficient amounts of carbon allows the steel to respond to heat treatment. However, there is a certain limit to how much carbon can be added. For austenitic stainless steels, adding too much carbon promotes sensitization. Sensitization is the precipitation of chromium carbides at the grain boundaries that consumes the chromium from the adjacent regions. This makes the stainless steel susceptible to intergranular corrosion.
Chromium: The addition of chromium makes steel become stainless steel. The minimum amount required is around 10.5%. Chromium at the surface reacts with oxygen to form a passive layer of chromium oxide which protects the metal from corrosion. Chromium has a ferrite stabilizing effect on steel. For austenitic stainless steels, the amount of chromium is balanced with other alloying elements that promote an austenitic microstructure.
Nickel: Nickel is added to stainless steel to form or retain an austenitic microstructure at room and low temperatures. The minimum amount required to stabilize an austenitic microstructure is around 8 to 9%. In austenitic stainless steels, 10 to 14% is required due to the addition of molybdenum, another ferrite former aside from chromium.
Molybdenum: Molybdenum is added to maintain the high-temperature toughness of stainless steel. The toughness of these stainless steels significantly decreases when used at temperatures around 752 to 1022°F (400 to 550°C). This phenomenon is known as temperature embrittlement. Aside from maintaining toughness, adding molybdenum increases the stainless steel‘s resistance to pitting corrosion.
Manganese: Manganese is added with nitrogen to decrease the amount of nickel required to maintain an austenitic microstructure. Substituting manganese and nitrogen for nickel reduces the impact of nickel price volatility and lowers its cost. Moreover, it reacts with sulfur forming manganese sulfide, which prevents the formation of the more unstable compound, ferrous sulfide. At the same time, manganese sulfide inclusions reduce sulfur brittleness and improve the machinability of stainless steel.
Nitrogen: Nitrogen is added with manganese to promote the formation of an austenitic microstructure. Nitrogen is more powerful in forming austenite than nickel, manganese, and even carbon. Alloying nitrogen produces effects similar to carbon but with additional benefits. Nitrogen has a lesser tendency to react with chromium. Thus, its amounts can be increased to improve the strength of the stainless steel with lesser susceptibility to sensitization. This, in turn, increases its resistance to intergranular corrosion. Moreover, when alloyed with molybdenum, it increases the stainless steel‘s resistance to pitting corrosion.
Titanium: Titanium is a stabilizer added to standard or straight 316 stainless steels to form the 316Ti variant. Titanium is a stronger carbide-former than chromium. At high temperatures, chromium tends to react with carbon and precipitate at grain boundaries. In stainless steel 316Ti, titanium reacts with carbon instead of chromium. This maintains the amount of chromium present within the austenite, resulting in the high-temperature stability of 316Ti. By lessening the formation of precipitates, intergranular corrosion resistance is improved.
Niobium (Columbium): Like titanium, niobium is a stabilizer in stainless steel, particularly the 316Cb grade. They are sometimes used in conjunction with titanium. Titanium stabilizes better while niobium ensures excellent weld strength and creep resistance.
Silicon: Silicon is a deoxidizer in steel and is present in alloys as minor residues. The presence of small amounts of silicon improves the strength of stainless steel. In high amounts, it tends to form intermetallics at elevated temperatures that cause embrittlement.
Phosphorus: Phosphorus is also a residue from the manufacture of carbon steel. High amounts of phosphorus increase vulnerability to temper embrittlement and are more detrimental than silicon.
Sulfur: Sulfur is naturally present in raw ores and slags. Like silicon and phosphorus, sulfur is present in stainless steel as residues from production. High levels can cause sulfur embrittlement and adversely affect on weldability and high-temperature performance. Moreover, it decreases resistance to corrosion, particularly pitting resistance. When added in controlled conditions, sulfur improves the machinability of stainless steel. In this case, manganese is used to counter the negative effects of sulfur.

Chapter Five �� What are the different grades of stainless steel 316, and what are their properties?

Stainless steel 316 is the second most commonly used stainless steel grade after 304. It is favored for its addition of molybdenum, which enhances its resistance to chemical attacks, particularly from chloride solutions. Beyond the role of molybdenum, many of its beneficial properties are due to its austenitic microstructure.

Characteristics of Stainless Steel 316 and 316L

General Properties

Below is a summary of the general properties of stainless steel 316 and its variants. These properties highlight its advantages compared to other types of stainless steel.

Corrosion Resistance: All stainless steel 316 grades have molybdenum as an alloying element that further improves corrosion resistance, particularly pitting corrosion. Pitting is a highly localized type of corrosion that creates shallow holes on the surface of the metal. This takes place in the presence of solutions containing chloride ions, such as seawater. High resistance to pitting corrosion makes stainless steel 316 recommended for marine applications. Molybdenum, together with chromium and nitrogen, is one of the factors in determining the pitting index or pitting resistance equivalence number.
Toughness: Because of its austenitic microstructure, stainless steel 316 can retain its toughness over a wide range of temperatures, unlike ferritic and martensitic grades. Ferritic grades tend to form intermetallic phases that contribute to embrittlement, while martensitic grades generally have high carbon content, making them intrinsically harder but more brittle.
Weldability: Austenitic stainless steels experience fewer negative effects from welding. They can retain their toughness and impact strength since they do not transform to martensite. They are less susceptible to cold cracking as encountered in martensitic stainless steels. Because of these, they are suitable for welding fillers even in welding different stainless steel groups.
Hardenability: As mentioned earlier, austenitic stainless steel is not hardenable by heat treatment. Hardness can be obtained through cold-working. Compared with ferritic stainless steels, austenitic types respond better to cold working.

Specific Properties of Grades of Stainless Steel 316

Listed below are the various grades of stainless steel 316. These grades are modified versions of the standard 316 composition, where the carbon content is reduced or stabilizing alloying elements are added. These modifications enhance or maintain mechanical properties and corrosion resistance, particularly after welding. Variants with higher carbon and nitrogen contents are utilized for their improved hardness and creep resistance.

316L: As of now, this is perhaps the most widely used variant compared to the standard and the 316Ti grade. Originally, low carbon grades were more expensive and difficult to produce until the introduction of the production process known as Argon Oxygen Decarburization (AOD). This grade of stainless steel 316 has a lower carbon content to reduce the effects of sensitization.

Lower carbon content means less formation of chromium carbide precipitates and less depletion of chromium in regions near the grain boundaries. This improves the retention of toughness and corrosion resistance of the stainless steel after welding.
316H: This grade contains higher amounts of carbon, improving its thermal stability and creep resistance. Its corrosion resistance is comparable to 316L. However, due to the high carbon content, it is prone to sensitization which makes welding joints vulnerable to corrosion.
316Ti and 316Cb: These are referred to as stabilized stainless steels. Instead of lowering the carbon content, titanium and niobium are added to reduce the effects of sensitization. Titanium and niobium are strong carbide and nitride formers, which helps prevent chromium from being consumed. Both grades have increased resistance to intergranular attack at the welded regions.
316N: This is a less popular grade of stainless steel 316 which has higher amounts of nitrogen. Nitrogen-rich stainless steels are usually considered highly alloyed, super austenitic grades in which higher amounts of chromium and molybdenum can be added. Alloying nitrogen in stainless steel 316 creates similar properties as adding more carbon, which results in improved hardness and higher strength.
316LN: This is a 316 variant with a lower carbon but higher nitrogen content. Similar to 316L, having a lower carbon content enables it to have better corrosion resistance in the welded condition. To compensate for the loss of carbon, the amount of nitrogen is increased to improve its mechanical properties.

Conclusion

Stainless steel is a type of iron alloy containing a certain percentage of chromium that imparts corrosion resistance to the metal. Its corrosion resistance is achieved by through a thin film of metal oxides that protects against corrosive materials.
The primary alloying elements of stainless steel 316 are 16��18% chromium, 10��14% nickel, and 2��3% molybdenum. The added molybdenum makes this grade more corrosion-resistant than other types.
There are five main groups of stainless steel. These are austenitic, ferritic, martensitic, duplex, and precipitation hardening.
Stainless steel 316 belongs to the austenitic group. It is the largest group of stainless steel comprising around two-thirds of all stainless steel production. Their austenitic microstructure imparts desirable characteristics such as low-temperature toughness, high-temperature stability, good formability, and weldability.
Besides carbon, chromium, nickel, and molybdenum, other elements are added to modify the properties of the alloy. This is to improve or retain its mechanical properties and corrosion resistance after welding. The high carbon and high nitrogen variants are used for their increased hardness and creep resistance.

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Stainless Steel 316 and 316L: Uses, Grades and Composition

Stainless Steel Grade 316 (UNS S31600) and Grade 316L (UNS S31603)

Introduction

Chapter One �� What is Stainless Steel 316?

Chapter Two �� How do stainless steel grades compare to stainless steel 316?