Metallic Glass Unleashed: A New Era of Strength and Versatility

What is Metallic Glass?

Introduction to Metallic Glass

Metallic glasses, also known as amorphous alloys, are a unique class of materials characterized by a disordered atomic structure with no long-range order, unlike conventional crystalline metals. This distinctive structure results in remarkable properties that set them apart from their crystalline counterparts.

Structural Characteristics

Metallic glasses exhibit short-range order, where atoms are arranged in a non-periodic manner, but lack the long-range periodicity found in crystalline materials. This disordered structure leads to the absence of defects such as grain boundaries and dislocations, contributing to their exceptional mechanical and chemical properties.

Properties of Metallic Glass

• Mechanical Properties: Metallic glasses exhibit high strength (≈2.0 GPa tensile strength), high elastic limit (up to 2% elastic strain), and good fracture toughness (10-50 MPa√m). They can be twice as strong as steel and more elastic than ceramics.
• Corrosion and Wear Resistance: The absence of grain boundaries and crystalline defects imparts superior corrosion and wear resistance to metallic glasses compared to crystalline alloys.
• Thermal and Rheological Properties: Metallic glasses have a glass transition temperature (Tg) above which they soften and flow, allowing thermoplastic forming and processing. They exhibit superplastic behavior in the supercooled liquid region (between Tg and crystallization temperature Tx) .

Types of Metallic Glass

Early Transition Metal-Based Metallic Glasses

• Zr-based: Zr-Al-TM (TM = transition metal), Zr-Cu-Ni-Al
• Ti-based: Ti-Zr-Be, Ti-Cu-Ni
• Compositions with high glass-forming ability (GFA) and thermal stability

Late Transition Metal-Based Metallic Glasses

• Fe-based: Fe-P-C, Fe-P-B, Fe-Si-B, Fe-Zr-B, Fe-Ga-P-B-C
• Co-based: Co-Fe-Ni-TM-B (TM = Ti, Zr, Nb, etc.)
• Ni-based: Ni-Nb-Zr, Ni-Zr-Ti-Si-Sn
• High saturation magnetization and good soft magnetic properties

Precious Metal-Based Metallic Glasses

• Pd-based: Pd-Ni-Cu-P, Pd-Pt-Ag-Au-Si-P (Ni/Cu-free)
• Pt-based: Pt-Cu-Ni-P
• Biomedical applications due to noble metal character and good corrosion resistance

Metalloid-Containing Metallic Glasses

• Mg-based: Mg-Ca-Au, Mg-Ca-Au-Yb (metalloid-free)
• Ln-based (Ln = lanthanide): Ln-Al-TM, Mg-Ln-TM
• Containing metalloids like B, C, and Si for improved GFA and properties

Applications of Metallic Glass

Structural Applications

Metallic glasses exhibit high strength, high elastic limit, and excellent wear resistance, making them ideal for structural applications. They are used in the manufacturing of springs, diaphragms, membranes, knife blades, electromagnetic wave shields, optical mirrors, power inductors, Coriolis flow meters, and sporting goods.

Magnetic and Sensing Applications

Certain metallic glass compositions, such as Fe-, Co-, and Ni-based alloys, possess excellent soft magnetic properties and are employed in magnetic sensing devices, transformers, and magnetic shielding applications.

Corrosion-Resistant Coatings

Metallic glass coatings exhibit superior corrosion resistance and wear resistance compared to their crystalline counterparts. They are applied as protective coatings on various components to extend their service life and reduce material consumption.

Biomedical Applications

The biocompatibility and corrosion resistance of some metallic glasses makes them suitable for biomedical applications, such as surgical instruments, implants, and prosthetic devices.

Catalytic Applications

Recent research has explored the potential of metallic glasses as electrocatalysts for water-splitting reactions (hydrogen evolution reaction and oxygen evolution reaction), fuel cell reactions (oxygen reduction reaction), and alcohol oxidation reactions. Their unique amorphous structure and tunable compositions offer promising catalytic properties.

Hydrogen Storage and Separation

Certain metallic glass compositions exhibit high hydrogen permeability and are being investigated for applications in hydrogen storage, separation membranes, and hydrogen sensors.

Functional Applications

The tunable compositions and amorphous structure of metallic glasses enable the development of materials with tailored properties for specific functional applications, such as photoelectrochemical water splitting, solder-corrosion resistance, and electronic devices.

Application Cases

Product/Project	Technical Outcomes	Application Scenarios
Bulk Metallic Glasses (BMGs)	High strength, excellent wear resistance, and corrosion resistance.	Structural applications such as springs, diaphragms, membranes, knife blades, electromagnetic wave shields, optical mirrors, and power inductors.
Metallic Glass Nanostructures	High potential for catalytic applications, including electrocatalytic water splitting reactions and fuel cell reactions.	Catalytic applications such as HER, OER, ORR, MOR, EOR, and degradation of harmful organic dyes from industrial effluents.
Metallic Glass Coatings	Superior corrosion resistance and wear resistance, effectively improving the life of materials and saving raw materials.	Protective coatings for various components in industries to extend service life and reduce material costs.
Bulk Metallic Glass	High strength, excellent wear resistance, and corrosion resistance.	Applications in structural materials, magnetic sensing devices, and protective coatings.
Ti-Cu-Ni-Sn Metallic Glass	Homogeneous nucleation of oxides and uniform formation of various metal oxides.	Photoelectrochemical (PEC) solar water splitting and other functional applications.

Latest Innovations in Metallic Glass

Metallic Glass Coatings and Surface Engineering

Metallic glass coatings have gained significant attention due to their superior corrosion resistance and wear resistance, enabling protection and repair of critical components, extending material life, and reducing raw material consumption. Recent progress focuses on optimizing microstructure, enhancing corrosion and wear resistance, and addressing challenges like limited coating thickness and adhesion issues. Strategies include nanostructuring, compositional tuning, and surface engineering techniques like laser or shot pinning.

Additive Manufacturing and Novel Processing

Advancements in additive manufacturing (AM) techniques like powder bed fusion and directed energy deposition have enabled the fabrication of bulk metallic glass components with complex geometries. Machine learning algorithms are being leveraged for alloy design, composition screening, and process optimization. Other novel processing routes include thermoplastic forming, hot-pulling of metallic glass arrays for high-aspect-ratio nanostructures, and the development of metallic glass composites and foams for improved toughness.

Fundamental Research and Future Outlook

Ongoing research aims to elucidate the atomic-scale structure, glass-forming ability, and unique properties of metallic glasses, facilitated by advanced characterization techniques and simulations . Future developments are expected to focus on microstructural design, toughening mechanisms, and expanding the range of applications leveraging the exceptional properties of metallic glasses and their derivatives.

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