Critical Minerals used in defence applications

New military products

Other relevant critical minerals lists

Critical Minerals in defence sector applications

Critical Minerals for radar and sonar equipment for surveillance and navigation

Rare earth elements play a vital role in advanced defence applications, including sonar transducers, radar systems, enhanced gamma-ray radiation detection devices, and multi-purpose integrated chemical agent alarms, where they amplify signals and enhance resolution for superior performance. Each of these elements contributes unique and critical functionalities, strengthening surveillance, navigation, and threat detection capabilities. Given their strategic significance, ensuring a secure and stable supply chain for these minerals is a top priority for national security interests worldwide.

• Beryllium’s stiffness-to-weight ratio and low neutron absorption make it indispensable in satellite optics, targeting sensors, and ICBM inertial navigation systems. Its role in high-precision systems includes beryllium gyroscopes and mirrors, enabling accurate tracking, surveillance, and threat interception. Beryllium's thermal and structural integrity is crucial for space-based reconnaissance and nuclear warhead components.

• Titanium is essential for high-stress, high-performance defence platforms due to its exceptional strength-to-weight ratio, corrosion resistance, and thermal stability. Titanium alloys (e.g., Ti-6Al-4V) are integral to airframes, jet engines, and naval vessels, including the F-35 Lightning II and Russia’s Severodvinsk-class submarines. Titanium also enhances missile casings and rocket motor components for hypersonic and high-temperature weapon systems. Its resistance to saltwater corrosion makes it critical in naval architecture, while its use in additive manufacturing enables the production of complex, heat-resistant aerospace parts.

• Cobalt is critical in jet engine superalloys and magnetic stealth technologies. With a melting point of 1,495°C, it supports high-temperature operations in platforms such as the F-135 engine of the F-35. Cobalt is also central to lithium-cobalt-oxide batteries used in UAVs and portable power systems, enabling silent surveillance and forward-deployed operations. Additionally, cobalt’s magnetic properties support stealth coatings and energy-resilient propulsion systems.

• Yttrium is widely used in radar, sonar, and infrared detection systems due to its role in Yttrium Iron Garnet (YIG) filters, which allow for precise radar frequency tuning, improving the resolution and sensitivity of surveillance and targeting systems. Yttrium is integral to high-performance radar systems such as the AN/SPY-6 Air and Missile Defense Radar, used on U.S. Navy destroyers, enhancing tracking of airborne and maritime threats. Additionally, yttrium-stabilised ceramics are found in jet engines and missile casings, such as those in Lockheed Martin's F-35 Lightning II, where they provide heat resistance and structural integrity in extreme combat conditions.

• Neodymium is an essential rare earth element in high-powered Neodymium-Iron-Boron (NdFeB) magnets, widely used in radar, sonar, and electronic warfare systems. These magnets generate powerful magnetic fields, enhancing submarine detection systems such as the SQQ-89 Undersea Warfare System, which improves tracking and engagement of underwater threats. Neodymium is also a key component in missile guidance and propulsion systems, such as the Tomahawk cruise missile, enabling precise and rapid manoeuvrability. Additionally, neodymium-based magnets are used in secure military communication systems, including the Joint Tactical Radio System (JTRS), ensuring reliable, interference-resistant transmission in combat environments.

• Samarium is a key component of Samarium-Cobalt (SmCo) magnets, valued for their high magnetic strength, resistance to demagnetisation, and exceptional thermal stability (-55°C to 300°C). These properties make them indispensable in radar, sonar, missile guidance, and electronic warfare systems.In radar and sonar applications, SmCo magnets are essential for signal generation and amplification, playing a critical role in navigation, threat detection, and target tracking. They are used in:

  • AN/MPQ-65 Radar (Patriot Missile Air Defense System) for air and missile threat tracking.

  • AN/APG-79 & AN/APG-81 AESA Radars (F/A-18 Super Hornet, F-15EX) for airborne fire control and targeting.

  • AN/TPS-80 & AN/TPQ-53 ground-based radars for surveillance and counter-fire detection.

• SmCo magnets are also crucial in missile guidance systems, such as the AIM-120 AMRAAM (Advanced Medium-Range Air-to-Air Missile), where they provide stable and precise flight control. Their ability to withstand extreme temperatures makes them essential in electronic warfare technologies, including the EA-18G Growler’s jamming systems, which disrupt enemy radar and communications.For sonar applications, samarium-based components enhance anti-submarine warfare (ASW) and underwater threat detection:

  • AN/SQS-53C Hull-Mounted Sonar (Arleigh Burke-class Destroyers) for ASW and torpedo detection.

  • CAPTAS-4 Towed Array Sonar (Type 23 Frigates, FREMM Ships) for deep-water passive/active ASW.

  • AN/AQS-22 Airborne Low-Frequency Sonar (MH-60R Seahawk) for dipping sonar in submarine localisation.

• Emerging applications include hypersonic threat detection, where SmCo magnets in dual-polarization radars (e.g., the Long-Range Discrimination Radar, LRDR) aid in tracking Mach 10+ glide vehicles that skim through the atmosphere, unlike traditional ballistic reentry vehicles (Mach 5+), which simply fall toward their target. Additionally, SmCo magnets are being integrated into Autonomous Underwater Vehicles (AUVs), where miniaturized magnetostrictive transducers enable compact synthetic aperture sonar (SAS) systems, enhancing underwater surveillance.

• Gadolinium is a crucial element in defence applications, particularly in sonar transducers and radiation detection systems. It has an exceptionally high neutron absorption cross-section, making it valuable for shielding in nuclear-powered submarines and other radiation-sensitive military assets. Additionally, gadolinium is used in enhanced gamma-ray detection devices, improving the ability to detect and track nuclear threats. Its magnetic and thermal properties also contribute to advanced imaging technologies, enhancing surveillance and reconnaissance capabilities.

• Lutetium plays a significant role in gamma-ray radiation detection devices, particularly in scintillator materials, which enable highly sensitive detection of nuclear and radiological materials. This makes it valuable for military counterproliferation efforts and systems such as the IdentiFINDER R440, used in radiation threat identification and monitoring. However, lutetium-doped scintillators are not typically used in electro-optical/infrared (EO/IR) targeting systems like the Sniper Advanced Targeting Pod (ATP), which relies on laser tracking and infrared sensors rather than gamma-ray detection. Additionally, lutetium is a key component in chemical agent detection alarms, such as the M4 JCAD (Joint Chemical Agent Detector), helping military forces identify hazardous substances in conflict zones.

Communication and display devices such as lasers, monitors and avionics

Rare earth elements are essential in communication and display devices, including lasers, monitors, and avionics, where they enhance performance, efficiency, and durability. These elements contribute to high-resolution displays, advanced optical systems, and robust communication technologies, which are integral to military and aerospace applications. Their strategic importance makes securing a stable supply chain crucial for national defence and technological superiority.

• Gallium is essential to the production of light-emitting diodes (LEDs) used in cockpit displays, infrared emitters, laser designators, and night vision systems. GaN LEDs offer high brightness and energy efficiency, supporting long-lasting and ruggedised lighting systems for military vehicles, avionics, and tactical equipment. 

• Germanium is used in infrared emitters and thermal imaging systems embedded in high-performance avionics and combat display technologies. It supports cockpit vision systems, optical targeting modules, and real-time battlefield monitoring by enabling longwave infrared detection, essential for situational awareness in smoke, fog, or darkness.

• Yttrium is a key element in lasers, optical systems, and display technologies, contributing to high-performance avionics and targeting systems. It is used in Yttrium Aluminium Garnet (YAG) lasers, which are widely deployed in military, industrial, and medical applications. Additionally, yttrium is found in phosphors for high-definition displays, enhancing the colour accuracy and brightness of monitors and cockpit instrumentation. Its role in ceramic components for aircraft and spacecraft also improves durability and heat resistance in extreme conditions. Additionally, its use in yttrium-based phosphors improves military display systems, such as targeting optics and vehicle HUDs (head-up displays), allowing for better situational awareness in combat.

• Praseodymium is an important rare earth element in display and optical technologies, particularly in aviation head-up displays (HUDs) and augmented reality systems. It is used in Praseodymium-doped glass to create high-quality optical lenses and laser components, ensuring enhanced visibility and accuracy in combat and reconnaissance missions. Praseodymium also plays a role in colour enhancement for display screens, improving contrast and brightness in military-grade monitors.

• Neodymium is widely used in laser technology, particularly in Neodymium-doped Yttrium Aluminium Garnet (Nd:YAG) lasers, which are critical for targeting, range-finding, and laser-guided weaponry. Nd:YAG lasers provide high-energy, precise beams, making them ideal for military and industrial applications. Neodymium is also essential in display screens and avionics, contributing to high-efficiency lighting and enhanced optical performance.

• Erbium is a key component in fibre optic communication systems, essential for secure military communications and high-speed data transfer. It is used in erbium-doped fibre amplifiers (EDFAs), which boost signals in long-distance fibre optic cables, ensuring clear and reliable communication over vast distances. Erbium is also used in solid-state lasers, particularly in infrared and medical applications, where it provides precise and controlled laser output.

• Terbium is essential for advanced display technologies due to its role in green phosphors, which are used in LEDs, LCD screens, and night-vision devices. It enhances image clarity and brightness, making it invaluable for high-performance military displays and cockpit avionics. Terbium is also used in terfenol-D, a magnetostrictive material employed in sonar and acoustic devices, as well as in precision actuators for aerospace systems.

• Dysprosium plays a critical role in high-performance magnets used in military communication systems and avionics. It enhances the thermal stability and durability of Neodymium-Iron-Boron (NdFeB) magnets, ensuring they remain effective in high-temperature environments such as aircraft and space systems. Dysprosium is also used in laser systems for targeting, guidance, and defence applications, where its unique optical properties improve precision and reliability.

• Europium is crucial for high-resolution display technologies, including military-grade monitors, avionics displays, and night-vision systems. It is used in phosphors to produce red and blue colours in LED and LCD screens, enhancing image clarity and colour accuracy. Europium’s role in X-ray and security screening equipment is also vital, as it improves the sensitivity and resolution of imaging systems used in military and aerospace applications.

Critical Minerals for mounting systems in armed vehicles and tanks

Rare earth elements play a crucial role in the mounting systems of armed vehicles and tanks, providing strength, durability, and precision in stabilisation mechanisms. These minerals contribute to shock absorption, vibration resistance, and enhanced manoeuvrability, ensuring that military vehicles can operate efficiently in harsh combat environments. Their strategic importance makes them essential for modern armoured vehicle design and defence systems.

• Germanium enables high-resolution thermal sights and target acquisition optics in armoured vehicle mounting systems. FLIR modules and thermal sights using germanium provide vehicle crews with enhanced visibility and threat detection in obscured or nighttime conditions, increasing combat effectiveness and safety in operational deployments.

• Yttrium plays a crucial role in the structural integrity, durability, and heat resistance of mounting systems in armed vehicles and tanks. It is widely used in yttrium-stabilised ceramics and high-strength alloys, which enhance the shock resistance and mechanical strength of vehicle components. These materials help mounting systems withstand extreme stress, vibrations, and temperature variations in high-impact combat environments. Yttrium is also an important component in heat-resistant coatings and wear-resistant materials, ensuring that key mechanical parts, including turret mounts and stabilisation joints, remain operational under intense battlefield conditions. 

• Neodymium is widely used in Neodymium-Iron-Boron (NdFeB) magnets, which are essential for stabilisation and guidance systems in armoured vehicles and tanks. These powerful magnets provide precision control in turret rotation, weapon targeting, and suspension systems, ensuring smooth and rapid adjustments during combat. Neodymium’s role in shock-absorbing systems also enhances the durability of mounting structures, reducing mechanical wear and improving operational longevity.

• Europium is a vital component in high-performance phosphors and advanced alloys, contributing to the strength and resilience of military vehicle mounting systems. It enhances structural integrity and durability, making it useful in combat vehicle display systems and targeting optics. Europium’s presence in anti-reflective coatings also improves visibility in low-light and high-glare conditions, ensuring effective operation in battlefield environments.

• Terbium is a key element in magnetostrictive materials, particularly Terfenol-D, which is used in active vibration dampening and stabilisation systems in tanks and armed vehicles. By minimising vibrations and enhancing control, Terbium helps improve the accuracy of mounted weapons and targeting optics. It also plays a role in high-strength alloys and advanced sensors, increasing resilience and adaptability in modern military vehicle designs.

Critical Minerals for precision-guided missiles (cruise, anti-ship, surface-to-air)

Rare earth elements and other rare metals are essential to precision-guided missile systems, enhancing navigation, propulsion, targeting, and electronic warfare capabilities. These minerals contribute to high-performance magnets, sensors, and guidance technologies, enabling cruise, anti-ship, and surface-to-air missiles to achieve exceptional accuracy, manoeuvrability, and reliability in combat. Their strategic importance makes them indispensable for modern defence, offering superior targeting precision and resilience under extreme conditions. Additionally, these materials improve structural durability and operational effectiveness, reinforcing propulsion and control systems across a wide range of missile platforms.

• Beryllium is used in gyroscopes and radar seekers, supporting long-range inertial guidance and precise target acquisition. Its optical clarity and stiffness allow for high-resolution targeting under extreme mechanical stress.

• Tungsten is utilised in kinetic energy penetrators, missile stabilisation systems, and drone-dropped munitions due to its high density and ultra-high melting point. It serves as a non-radioactive alternative to depleted uranium in armour-piercing rounds. In hypersonic systems, tungsten alloys maintain aerodynamic precision and trajectory control under extreme forces.

• Cobalt is critical to high-temperature superalloys used in missile propulsion systems and warhead components, ensuring structural integrity under intense thermal and mechanical stress. In unmanned aerial vehicles (UAVs), cobalt-based lithium-cobalt-oxide (LiCoO₂) batteries enable extended endurance and consistent power delivery, supporting long-duration surveillance and precision-guided strike capabilities.

• Germanium is vital for thermal targeting and seeker systems in guided munitions such as Javelin, TOW, and surface-to-air missiles. It enables lock-on after launch and passive homing using heat signatures, enhancing accuracy and autonomy in contested environments. Its non-recyclable use adds pressure to secure dependable supply chains.

• Praseodymium plays a key role in high-strength permanent magnets and advanced optical systems, enhancing targeting, tracking, and propulsion functions. It is used in missile laser designators and infrared sensors, improving target acquisition. Heat-resistant praseodymium alloys also reinforce structural components, ensuring stability during high-speed, high-temperature flight.

• Neodymium is widely employed in Neodymium-Iron-Boron (NdFeB) magnets, which power propulsion, fin control mechanisms, and radar seekers. These strong, lightweight magnets are integral to electromagnetic actuators and guidance systems, enabling rapid adjustments and precise targeting. Neodymium also supports advanced homing and radar systems for accurate threat interception.

• Promethium, with its low-level radioactivity, is ideal for betavoltaic batteries that provide long-lasting, maintenance-free power in missile and aerospace systems. These batteries are essential for powering guidance modules, onboard sensors, and memory units over extended periods, especially in environments where conventional power sources would fail. Promethium enables stealth operations by minimising thermal signatures and enhancing component reliability.

• Samarium is central to Samarium-Cobalt (SmCo) magnets, prized for their thermal stability and resistance to demagnetisation. These magnets are used in radar seekers, gyroscopes, and inertial navigation systems, ensuring accurate targeting and trajectory control under extreme conditions. Samarium also supports electronic warfare systems by improving signal processing and electromagnetic shielding.

• Terbium is used in stabilisation systems to enhance flight control surface precision through Terfenol-D, a magnetostrictive material. This contributes to smooth manoeuvrability during high-speed missile adjustments. Terbium also strengthens high-performance optics and sensors, improving guidance and target detection accuracy.

• Dysprosium ienhances heat-resistant magnets, particularly Neodymium-Iron-Boron (NdFeB), to maintain performance under battlefield conditions. It is essential for propulsion systems, navigation controls, and actuator components. Dysprosium also supports stabilisation systems, improving missile manoeuvrability and impact precision.

• Tantalum is incorporated into directed-energy weapons and railgun projectiles due to its high electrical conductivity and thermal stability. It is also alloyed with nickel-based superalloys in turbine blades, rocket nozzles, and combustion chambers. These properties make tantalum critical in hypersonic missile systems and spacecraft, where extreme heat resistance is required for sustained performance.

Critical Minerals for guidance systems for controlling missiles

Missile guidance systems focus on flight control, course correction, and stabilisation, ensuring a missile follows an exact trajectory to reach its target. The rare earth elements used in these systems contribute to gyroscopes, actuators, homing mechanisms, and stabilisation technologies, enhancing manoeuvrability, target tracking, and interception accuracy. These minerals are integral to high-performance magnets, sensors, and control systems, allowing missiles to maintain precise navigation, targeting, and interception capabilities. Their strategic significance makes them indispensable for modern missile defence, providing superior control, responsiveness, and resilience under extreme conditions.

• Germanium enhances thermal tracking and infrared imaging components in missile guidance systems, particularly those requiring real-time heat signature detection. Its inclusion in seeker heads and targeting sensors allows missiles to maintain precise trajectory control and engage targets with minimal external input, supporting modern fire-and-forget capabilities.

• Praseodymium enhances high-strength magnets and optical components, improving the precision and reliability of missile targeting systems. It is used in laser designators and infrared tracking sensors, which assist in target acquisition and course correction. Praseodymium also contributes to heat-resistant alloys, reinforcing missile structures and guidance hardware, ensuring long-term durability and high-speed functionality.

• Neodymium is integral to missile guidance systems, electromagnetic actuators, and homing mechanisms. Neodymium-Iron-Boron (NdFeB) magnets are essential for precision flight control, rapid manoeuvrability, and improved targeting accuracy. Neodymium also supports radar and sensor systems, ensuring that missiles can track and engage enemy threats with maximum efficiency.

• Samarium is a key component in Samarium-Cobalt (SmCo) magnets, hich provide long-term magnetic stability and resistance to demagnetisation. Samarium is crucial for inertial navigation systems, gyroscopes, and radar seekers, which are responsible for maintaining accurate flight paths and precise target engagement. It also supports electronic warfare technologies, improving signal processing and shielding against enemy jamming.

• Terbium plays a critical role in stabilisation and control systems, improving missile actuators and vibration dampening mechanisms. By enabling precise course corrections, Terbium ensures smooth flight control and increased targeting accuracy. It also enhances optical sensors and tracking systems, allowing for more effective detection of moving targets.

• Dysprosium is vital in heat-resistant magnets that reinforce missile navigation and steering mechanisms. By stabilising Neodymium-Iron-Boron (NdFeB) magnets, Dysprosium ensures accurate trajectory maintenance under high temperatures and extreme operational conditions. This mineral also enhances stabilisation components, enabling missiles to remain on their intended course despite battlefield disruptions.

Critical Minerals for high-powered electrical equipment (containing high-powered magnets)

Rare earth elements are essential in high-powered electrical equipment, where they enable stronger, more efficient magnets for advanced defence, aerospace, and industrial applications. These minerals contribute to high-performance motors, generators, and electromagnetic systems, ensuring greater power output, durability, and thermal stability. Their strategic significance makes them indispensable for cutting-edge technologies, providing enhanced efficiency, reliability, and resilience in demanding environments.

• Germanium contributes to thermal imaging modules and infrared detection systems integrated into high-powered EO/IR surveillance and targeting platforms. It supports sensor arrays in armoured vehicles, aircraft, and naval systems, enabling accurate heat-based targeting within high-electrical-load environments.

• Yttrium enhances high-temperature superconductors and ceramic materials, improving electrical conductivity and thermal resistance in powerful motors, transformers, and advanced electronic components. It is also used in yttrium-stabilised ceramics, which reinforce high-performance electrical insulators and heat-resistant coatings.

• Praseodymium enhances high-strength permanent magnets and alloy conductivity, improving the efficiency of electrical motors, generators, and high-powered actuators. It is also used in aerospace-grade components, ensuring lightweight yet durable electrical systems in defence and aviation.

• Neodymium is fundamental to Neodymium-Iron-Boron (NdFeB) magnets, the strongest known permanent magnets. These are essential in defence radar systems, high-powered motors, wind turbines, and advanced electrical propulsion units, providing maximum power efficiency in compact designs.

• Samarium is a key component in Samarium-Cobalt (SmCo) magnets, known for their exceptional thermal stability and resistance to demagnetisation. These magnets are widely used in high-performance generators, military-grade electrical systems, and space applications, where they maintain consistent power output under extreme conditions.

• Terbium is crucial in magnetostrictive materials like Terfenol-D, which enhances electrical actuators, precision sensors, and sonar systems by converting electrical energy into precise mechanical movement. It also strengthens Neodymium-Iron-Boron (NdFeB) magnets, improving performance in motors, turbines, and energy-efficient power systems.

• Dysprosium plays a vital role in heat-resistant magnets, ensuring Neodymium-Iron-Boron (NdFeB) magnets maintain stability and efficiency at high temperatures. This makes it essential for electric vehicle motors, aircraft power systems, and military-grade electromagnetic equipment, where reliability under extreme conditions is critical.

• Tantalum is preferred in military-grade capacitors over commercial equivalents due to its superior durability, shock resistance, and extended service life. These capacitors are used in radar systems, communication devices, avionics, and missile guidance systems, where reliability in harsh environments such as vibration, high temperatures, and electromagnetic interference is essential.

Night vision goggles

Rare earth elements play a crucial role in night vision technology, enhancing image clarity, low-light sensitivity, and thermal resistance. These minerals contribute to high-performance optics, phosphors, and infrared imaging systems, ensuring superior visibility in low-light and combat environments. Their strategic significance makes them indispensable for military, surveillance, and security operations, providing enhanced situational awareness and operational effectiveness.

• Germanium is critical to night vision goggles, serving as the primary material in infrared-transmitting optics that detect thermal signatures in complete darkness. Its high infrared transparency and refractive index enable compact, high-resolution lenses essential for target detection in low-visibility environments. Coated germanium optics also offer exceptional durability and resistance to abrasion and extreme temperatures, ensuring consistent performance in harsh operational conditions.

• Yttrium is essential in yttrium-based phosphors, which enhance image intensifier tubes in night vision goggles by improving light amplification and contrast. It also strengthens infrared optics and thermal imaging components, ensuring higher sensitivity and durability in extreme conditions. Additionally, yttrium-stabilised ceramics contribute to lightweight, impact-resistant goggle lenses, enhancing field performance and user comfort.

• Lanthanum is a key component in high-refractive-index glass, improving lens quality and optical clarity in night vision devices. It enhances light transmission and image sharpness, allowing for superior resolution and depth perception in low-light environments. Lanthanum-based glass is also used in infrared targeting and thermal imaging optics, ensuring precise detection and enhanced night-time visibility for military and security personnel.

Critical Minerals in Weapon Systems

Critical Minerals for powerful compact magnets for guidance and control in the electric motors

Rare earth elements are essential in high-performance compact magnets, which drive guidance and control systems in electric motors for advanced defence technologies. These minerals enable actuators, propulsion systems, and precision targeting mechanisms in weapons such as Tomahawk cruise missiles, smart bombs, Joint Attack Munitions, Joint Air-to-Ground actuators, and Predator unmanned aircraft. Their role in compact military-grade magnets ensures power, efficiency, and precision, delivering reliable performance, rapid response, and superior manoeuvrability in modern defence applications.

• Praseodymium strengthens Neodymium-Iron-Boron (NdFeB) magnets, improving their durability and efficiency in high-stress environments. It is also used in electric motor windings and control mechanisms, ensuring precise movement and rapid response in guided weapons and UAV systems. Additionally, Praseodymium-enhanced alloys contribute to structural stability in high-speed flight applications.

• Neodymium is the primary element in Neodymium-Iron-Boron (NdFeB) magnets, which provide exceptionally strong magnetic fields in a compact size. These magnets are essential in actuators, electric motor drives, and guidance control systems, ensuring precise manoeuvrability and high efficiency in missiles, UAVs, and smart munitions. Neodymium magnets also enhance power-to-weight ratios in propulsion systems, making them ideal for long-range and high-speed military applications.

• Samarium plays a vital role in Samarium-Cobalt (SmCo) magnets, known for their exceptional thermal stability and resistance to demagnetisation. These magnets are used in actuators, gyroscopes, and electric motor drives, ensuring consistent performance in extreme temperatures and high-vibration environments. Samarium magnets are particularly valuable in missiles and UAV guidance systems, where reliability under intense conditions is critical.

• Terbium is essential in magnetostrictive materials like Terfenol-D, which enhances electromagnetic actuators and vibration control systems. It is particularly useful in guidance mechanisms, targeting optics, and advanced UAV control surfaces, enabling precise adjustments and real-time flight corrections. Terbium also strengthens high-performance magnets used in compact electric motors, ensuring efficient power conversion and smooth operation in long-range missile and drone propulsion systems.

• Dysprosium enhances the thermal resistance and coercivity of Neodymium-Iron-Boron (NdFeB) magnets, allowing them to function efficiently in high-temperature environments. This is crucial for high-speed missile propulsion, advanced UAV motor systems, and precision-guided weapon actuators, where extreme heat and mechanical stress are common. Dysprosium also strengthens stabilisation mechanisms, ensuring accurate targeting and flight path control.

Critical Minerals for amplifying energy and resolution for targeting and weapons

Rare earth elements play a vital role in energy amplification and high-resolution targeting systems, enhancing laser weapons, counter-IED technologies, and photonic disruptors. These minerals contribute to laser targeting, precision-guided weaponry, and next-generation combat systems, ensuring greater accuracy, power efficiency, and operational effectiveness. Their strategic significance makes them indispensable for advanced military applications, including laser targeting, the Laser Avenger (counter-IEDs), SaberShot photonic disruptors, and Future Combat System (FCS) vehicles with laser weaponry.

• Lithium is a critical enabler of high-energy, lightweight power systems that support targeting electronics, EO/IR sensors, and portable laser weapon platforms. Lithium-ion and lithium-sulfur batteries provide compact, high-density energy storage for systems like the Laser Avenger and portable counter-IED equipment, ensuring sustained power delivery during high-intensity operations. In vehicle-mounted and airborne platforms, lithium-based energy storage supports rapid targeting, sensor activation, and real-time data transmission in electronic warfare and precision strike missions.

• Graphite, particularly in its synthetic form, is indispensable for thermal management in high-power laser weapons and advanced sensor systems. It efficiently dissipates heat from laser diodes, beam control optics, and power conversion units, maintaining stable performance under continuous operation. Directed Energy Weapons (DEWs), including the Navy’s Laser Weapon System (LaWS), rely on graphite to regulate temperature and prevent thermal distortion, preserving beam accuracy and resolution during sustained targeting engagements.

• Gallium is critical for high-frequency and high-power electronic systems due to its use in Gallium Arsenide (GaAs) and Gallium Nitride (GaN) semiconductors. These materials are foundational in active electronically scanned array (AESA) radar systems, which provide enhanced targeting accuracy, faster threat detection, and greater resistance to jamming. GaN-based components offer high thermal conductivity and voltage tolerance, making them ideal for directed energy weapons and high-power microwave systems. Gallium also plays a vital role in advanced communication systems and satellite payloads, supporting secure, high-bandwidth data transfer in combat environments. Its role in amplifying signal strength and energy output makes it indispensable for precision-guided weaponry and next-generation targeting technologies.

• Germanium is essential to advanced thermal imaging optics used in fire control systems, smart munitions, and electro-optical weapon sights. Its ability to detect heat signatures in the infrared spectrum improves targeting precision, especially in obscured or nighttime conditions. Systems such as M113 FLIR-equipped carriers and missile seeker heads depend on germanium for reliable thermal performance under combat stress. It also enhances the resolution and sensitivity of targeting systems used in precision strikes, supporting passive surveillance, laser range-finding, and EO/IR (electro-optical/infrared) targeting pods with high-fidelity heat mapping in high-temperature, high-intensity battlefield environments.

• Yttrium is essential in Yttrium Aluminium Garnet (YAG) lasers, which provide high-powered, precise beams used in laser targeting, range-finding, and directed energy weapons. Yttrium also enhances infrared optics and thermal resistance, ensuring consistent performance in high-energy laser systems deployed in combat vehicles and counter-IED operations.

• Europium plays a crucial role in high-resolution phosphors and advanced imaging systems, improving targeting clarity and laser guidance precision. It enhances optical sensors and display technologies, ensuring greater accuracy in photonic disruptors and next-generation laser weapons. Europium-based materials also contribute to energy-efficient laser emission, supporting sustained high-intensity targeting operations.

• Terbium is used in Terfenol-D, a magnetostrictive material that enhances electromagnetic actuators and vibration control systems in laser weapon platforms. It is also essential in high-performance green phosphors, which improve visual targeting systems and optical resolution in laser-guided weaponry and photonic disruptors. Terbium strengthens energy transfer mechanisms, ensuring greater stability and efficiency in high-power laser applications.

Critical Minerals for high-performance alloys and structural systems

High-performance alloys and structural systems are foundational to modern military platforms, where strength, durability, and weight efficiency directly impact operational performance. Critical minerals such as aluminium, titanium, cobalt, and platinum are indispensable in producing lightweight, heat-resistant, and corrosion-resistant materials used across air, land, and sea domains. These materials reinforce missile casings, vehicle armour, propulsion systems, and aerospace frames—ensuring structural resilience under extreme conditions while supporting advanced technologies like stealth, electronic warfare, and high-speed manoeuvrability.

• Titanium alloys, including Ti-6Al-4V, are extensively used in airframes, missile casings, and naval systems due to their exceptional strength-to-weight ratio and resistance to corrosion. Aircraft like the F-35 Lightning II rely on titanium for 30–40% of their structure, while submarines such as Russia’s Severodvinsk-class use titanium hulls to operate at extreme depths. The titanium also features in hypersonic glide vehicles and armour plating, where thermal and ballistic performance is critical.

• Cobalt is a key element in high-temperature superalloys used in jet engines, missile propulsion systems, and warhead components. It enables sustained structural performance under temperatures exceeding 1,200°C, particularly in advanced engines like the F-135 powering the F-35. Cobalt also enhances durability in aerospace-grade materials and energy systems, reinforcing the structural reliability of platforms operating in high-stress combat environments.

• Aluminium alloys such as AA 7075 are used extensively in missile systems like the Patriot missile due to their lightweight and high-strength properties. Aluminum also contributes to electromagnetic shielding, radar systems, and electronic warfare components, balancing structural integrity with mobility.

• Niobium alloys such as niobium C-103 and next-generation variants like Super C103™drive critical advancements in hypersonic missiles, aerospace propulsion systems, and nuclear infrastructure. With a melting point of 2,469°C, low density, and compatibility with additive manufacturing, niobium is indispensable for components exposed to extreme thermal and mechanical stresses.

• In hypersonic vehicles, which travel at speeds exceeding Mach 5, generate surface temperatures above 1,700°C due to atmospheric friction. Conventional materials like titanium and nickel superalloys suffer rapid oxidation and structural degradation under such conditions. In contrast, niobium C-103, an alloy of niobium, hafnium, and titanium, maintains yield strengths above 400 MPa at 1,200°C while retaining room-temperature ductility—a combination unmatched by other refractory metals. This makes it ideal for leading edges, control surfaces, and scramjet combustors, where thermal management is critical.

• Additionally, niobium C-103’s low ductile-to-brittle transition temperature (-196°C) ensures functionality across the full operational envelope of hypersonic glide vehicles. These vehicles experience cryogenic conditions at high altitudes and intense heating during descent. Systems such as Lockheed Martin’s AGM-183A ARRW and Russia’s Avangard reportedly employ niobium C-103 in aeroshells and manoeuvring fins to withstand cyclical thermal loading.

• Platinum is used in catalytic converters for Abrams tanks and other vehicles to suppress infrared signatures, reducing vulnerability to thermal imaging and heat-seeking weaponry. It also serves as a catalyst in fuel reforming systems for advanced military power units.

• Tantalum alloys enhance the penetration power of armour-piercing munitions, rivalling tungsten and depleted uranium in both density and self-sharpening capabilities. They are used in kinetic energy penetrators for tank and anti-tank rounds, as well as in explosively formed penetrators (EFPs) designed to defeat heavy armour. Tantalum’s high melting point helps prevent deformation during high-velocity impacts, ensuring maximum effectiveness on target. Additionally, tantalum coatings improve ballistic protection in military vehicles and body armour by resisting corrosion and shattering under impact. In naval applications, tantalum is also used to protect ships from saltwater degradation.

Critical sectors using strategic minerals

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