Aluminium–lithium alloys

Alloying with lithium reduces structural mass by three effects:

; Displacement : A lithium atom is lighter than an aluminium atom; each lithium atom then displaces one aluminium atom from the crystal lattice while maintaining the lattice structure. Every 1% by mass of lithium added to aluminium reduces the density of the resulting alloy by 3% and increases the stiffness by 5%. This effect works up to the solubility limit of lithium in aluminium, which is 4.2%.

; Strain hardening: Introducing another type of atom into the crystal strains the lattice, which helps block dislocations. The resulting material is thus stronger, which allows less of it to be used.{{citation needed|date=January 2011}}

; Precipitation hardening: When properly aged, lithium forms a metastable Al₃Li phase (δ') with a coherent crystal structure. These precipitates strengthen the metal by impeding dislocation motion during deformation. The precipitates are not stable, however, and care must be taken to prevent overaging with the formation of the stable AlLi (β) phase. This also produces precipitate free zones (PFZs) typically at grain boundaries and can reduce the corrosion resistance of the alloy.

The crystal structure for Al₃Li and Al–Li, while based on the FCC crystal system, are very different. Al₃Li shows almost the same-size lattice structure as pure aluminium, except that lithium atoms are present in the corners of the unit cell. The Al₃Li structure is known as the AuCu₃, L1₂, or Pm{{overbar|3}}m and has a lattice parameter of 4.01 Å. The Al–Li structure is known as the NaTl, B32, or Fd{{overbar|3}}m structure, which is made of both lithium and aluminium assuming diamond structures and has a lattice parameter of 6.37 Å. The interatomic spacing for Al–Li (3.19 Å) is smaller than either pure lithium or aluminium.

Al–Li alloys are primarily of interest to the aerospace industry for their weight advantage. On narrow-body airliners, Arconic (formerly Alcoa) claims up to 10% weight reduction compared to composites, leading to up to 20% better fuel efficiency, at a lower cost than titanium or composites. Aluminium–lithium alloys were first used in the wings and horizontal stabilizer of the North American A-5 Vigilante military aircraft. Other Al–Li alloys have been employed in the lower wing skins of the Airbus A380, the inner wing structure of the Airbus A350, the fuselage of the Bombardier CSeries (where the alloys make up 24% of the fuselage), the cargo floor of the Boeing 777X, and the fan blades of the Pratt & Whitney PurePower geared turbofan aircraft engine. They are also used in the fuel and oxidizer tanks in the SpaceX Falcon 9 launch vehicle, Formula One brake calipers, and the AgustaWestland EH101 helicopter.

The third and final version of the US Space Shuttle's external tank was principally made of Al–Li 2195 alloy. In addition, Al–Li alloys are also used in the Centaur Forward Adapter in the Atlas V rocket, in the Orion Spacecraft, and were to be used in the planned Ares I and Ares V rockets (part of the cancelled Constellation program).

Al–Li alloys are generally joined by friction stir welding. Some Al–Li alloys, such as Weldalite 049, can be welded conventionally; however, this property comes at the price of density; Weldalite 049 has about the same density as 2024 aluminium and 5% higher elastic modulus.{{citation needed|date=December 2013}} Al–Li is also produced in rolls as wide as {{convert|220|in|ft m|abbr=off}}, which can reduce the number of joins.

Although aluminium–lithium alloys are generally superior to aluminium–copper or aluminium–zinc alloys in ultimate strength-to-weight ratio, their poor fatigue strength under compression remains a problem, which is only partially solved as of 2016. Also, high costs (around 3 times or more than for conventional aluminium alloys), poor corrosion resistance, and strong anisotropy of mechanical properties of rolled aluminium–lithium products has resulted in a paucity of applications.

Al-Li alloy powder is used in the production of lightweight sporting goods, including bicycles, tennis rackets, golf clubs, and baseball bats. Its high strength combined with reduced weight significantly enhances performance, speed, and maneuverability.{{cite book |last=Chen |first=J |year=2010 |title=Surface Engineering of Light Alloys |publisher=Woodhead Publishing |editor-last=Dong |editor-first=Hanshan |pages=549–567 |chapter=Chapter 16 - Surface engineered light alloys for sports equipment |isbn=9781845695378}}{{cite book |author=Q. Ashton Acton |year=2013 |title=Light Metals—Advances in Research and Application: 2013 |publisher=ScholarlyEditions |page=578 |isbn=978-1481677202}} It is also used in the automobile industry as body panels, chassis parts, and suspension components.{{cite web |url=https://powder.samaterials.com/al-li-alloy-powder.html |title=Al-Li alloy powder |website=Stanford Advanced Materials |access-date=July 7, 2024}}

Aside from its formal four-digit designation derived from its element composition, an aluminium–lithium alloy is also associated with particular generations, based primarily on when it was first produced, but secondarily on its lithium content. The first generation lasted from the initial background research in the early 20th century to their first aircraft application in the middle 20th century. Consisting of alloys that were meant to replace the popular 2024 and 7075 alloys directly, the second generation of Al–Li had high lithium content of at least 2%; this characteristic produced a large reduction in density but resulted in some negative effects, particularly in fracture toughness. The third generation is the current generation of Al–Li product that is available, and it has gained wide acceptance by aircraft manufacturers, unlike the previous two generations. This generation has reduced lithium content to 0.75–1.8% to mitigate those negative characteristics while retaining some of the density reduction; third-generation Al–Li densities range from {{convert|2.63|to|2.72|g/cm3|lb/in3|abbr=off}}.

• 1424 aluminium alloy
• 1429 aluminium alloy
• 1441K aluminium alloy
• 1445 aluminium alloy
• V-1461 aluminium alloy
• V-1464 aluminium alloy
• V-1469 aluminium alloy
• V-1470 aluminium alloy
• 2094 aluminium alloy
• 2095 aluminium alloy (Weldalite 049)
• 2097 aluminium alloy
• 2197 aluminium alloy
• 8025 aluminium alloy
• 8091 aluminium alloy
• 8093 aluminium alloy
• CP 276

Key world producers of aluminium–lithium alloy products are Arconic, Constellium, and Kamensk-Uralsky Metallurgical Works.

• Arconic Technical Center (Upper Burrell, Pennsylvania, USA)
• Arconic Lafayette (Indiana, USA); annual capacity of {{convert|20000|MT|ST kg lb}} of aluminium–lithium and capable of casting round and rectangular ingot for rolled, extruded and forged applications
• Arconic Kitts Green (United Kingdom)
• Rio Tinto Alcan Dubuc Plant (Canada); capacity {{cvt|30000|MT|ST kg lb}}
• Constellium Issoire (Puy-de-Dôme), France; annual capacity of {{cvt|14000|MT|ST kg lb}}
• Kamensk-Uralsky Metallurgical Works (KUMZ)
• Aleris (Koblenz, Germany)
• FMC Corporation - FMC spun off its lithium division into Livent, which has now (2024) merged to form Arcadium (https://arcadiumlithium.com/)
• Southwest Aluminium (PRC)

• Aluminium alloy
• Magnesium–lithium alloys
• GLARE
• Carbon fiber reinforced plastic (CFRP)

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{{harvnb|Grushko|Ovsyannikov|Ovchinnokov|2016|page=9|ps= (Table 1.2: Composition of Aluminum–Lithium Alloys Registered in the United States, France, and Great Britain)}}

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}}

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• {{cite web |title=Will Aluminum-Lithium Beat Composites for Narrow Body Airliners? |url=https://airinsight.com/will-aluminum-lithium-beat-composites-for-narrow-body-airliners/ |access-date=7 March 2019 |date=18 October 2010 |publisher=GLG News |via=AirInsight Group, LLC |url-status=live |archive-date=7 March 2019 |archive-url=https://web.archive.org/web/20190307192359/https://airinsight.com/will-aluminum-lithium-beat-composites-for-narrow-body-airliners/}}

{{aluminium alloys}}

{{Lithium compounds}}

{{DEFAULTSORT:Al-Li}}

Lithium

Category:Lithium