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Is Aluminum Ductile or Brittle? Understanding 6061 Aluminum

It’s important to understand the ductile-to-brittle transition temperatures (DBTT) of metals when considering which materials to use for applications functioning under cryogenic environments. Some more ductile metals at room temperature may become brittle materials at low temperatures. As a result, they develop fractures, and the structure may fail. For example, the DBTT of the low-carbon steel used in the building of the Titanic may have contributed to the ship’s sinking in an environment that was just -4 °F.

However, is aluminum ductile or brittle? Is DBTT applicable to all metals, including 6061 aluminum? Below, we dive deeper into DBTT and why 6061 aluminum does not have a ductile-to-brittle transition temperature.

Understanding the Ductile-to-Brittle Transition Temperature

DBTT refers to the temperature of the material at which it enters into the brittle phase from the ductile phase. At this point, the material can no longer sustain the loading force without developing a fracture.

Pure metals tend to have a definite transition temperature, while in alloys, this transition room temperature is uniquely defined and may occur over a finite range.

In this regard, the Charpy Impact Test, also known as the Charpy V-notch test, is conducted to determine the toughness of a material. Surprisingly, pure aluminum does not have a DBTT.

Ductile-to-Brittle Transition Temperature of 6061 Aluminum

Aluminum has a face-centered cubic (FCC) structure. Face-centered cubic materials do not have any ductile-to-brittle transition; they always tend to remain ductile metals.

Why? For that, we need to understand the slip system of the material. Metals deform along the most closely packed directions on the most closely packed slip planes, also known as slip systems. The dislocation of a slip happens when a corner atom jumps to the center of the cube.

Let’s take a look at the unit cell of BCC and FCC materials, as shown below.

Face-centered cubic structure chartFCC vs. BCC lattice structure 

Link

Both structures have the same number of slip systems (12). However, unlike BCC, FCC has closely packed planes belonging to each slip system.

At elevated temperatures, both FCC and BCC structures have mobile dislocations, meaning they can go through plastic deformation without undergoing fracture. However, at a low melting point, you need a certain amount of thermal energy to activate dislocations in BCC structures, but dislocations happen in FCC independent of the surrounding temperature. As a result, FCC stays as a ductile metal even at low temperatures and displays no DBTT phenomenon.

This is why you can’t find any data regarding the ductile to brittle transition temperature of 6061 aluminum.

Unique Low-temperature Aluminum Applications

Aluminum is one of the highly ductile metals or ductile materials while being tough at low temperatures, thanks to the FCC structure of the metal. Such physical properties are an essential advantage for offshore installations in the northern hemisphere, which easily reaches -40°F. This makes ductile metals and ductile materials such as aluminum quite useful.

5000 and 6000 series aluminum alloys are considered the most suitable for cryogenic applications due to their high notch-yield ratio, which is a ratio between notch-tensile strength and tensile-yield strength for a quality control test of material against fracture testing. Additionally, these aluminum alloys offer excellent corrosion resistance and can benefit from any heat treatment to enhance their properties further.

However, it’s important to note that not all pure aluminum alloys behave the same under low temperatures. For instance, the strength of 6061 increases as the temperature is reduced, whereas that of 5456 aluminum remains almost constant.

The graph below shows the tensile yield strength at 4K (ksi) force for different aluminum alloys.

Tensile Yield Strenght Illustration

Some industries use low-temperature fluids to achieve desired working conditions. In this regard, aluminum equipment and installations can offer exceptional strength and high ductility, even at -320.8 °F.

The table below lists grades of different aluminum alloys used over a wide range of cryogenic temperatures.

TemperatureSuitable Aluminum Alloys
-45 °CAlmost all except 7075-T6 and 7178-T6
-100 °C7079-T6
-196 °C2024-T6, 7039-T6, 5456-H343
-253 °C2024-T4, 6061-T6, 2219-T87, 5052-H38, 5083-H38

While the absence of a ductile-to-brittle transition temperature of 6061 aluminum benefits industries working with cryogenic applications, its soft nature is challenging for machine operators. The low melting point of the aluminum alloy can result in gummy build-up around the tool edge.

Purchase High-Quality Aluminum From a Reputable Supplier

Industrial Metal Services has been supplying various aluminum alloys to the San Francisco Bay Area and beyond for more than two decades. We can provide 6061 aluminum plates, bars, rounds, and other aluminum alloys, including MIC-6, ALCA-5, ATP-5, and K100-S. Our inventory also stocks other metals, such as iron, copper, steel, and titanium, with new, mill-sourced materials and verified remnants available for purchase. To save you from machining challenging metals like aluminum, we also have a state-of-the-art metal sawing infrastructure that can cut even 12-inch-thick aluminum plates with ease.

Published by IMS Team

Industrial Metal Service has decades of experience and over 1.1 billion pounds of metal sold and recycled. Our founder, Jeff, has spent his life in the industry and prides himself on offering fair, efficient, trustworthy, knowledgeable, outstanding customer service. We offer metal salesmetal recycling pickup service, and other associated services, such as precise metal sawing, machinery teardown, and warehouse cleanupGive us a call and we’ll get it done.