fbpx
Wikipedia

Amorphous metal

January 01, 1970

An amorphous metal (also known as metallic glass, glassy metal, or shiny metal) is a solid metallic material, usually an alloy, with disordered atomic-scale structure. Most metals are crystalline in their solid state, which means they have a highly ordered arrangement of atoms. Amorphous metals are non-crystalline, and have a glass-like structure. But unlike common glasses, such as window glass, which are typically electrical insulators, amorphous metals have good electrical conductivity and can show metallic luster.

Samples of amorphous metal, with millimeter scale

There are several ways in which amorphous metals can be produced, including extremely rapid cooling, physical vapor deposition, solid-state reaction, ion irradiation, and mechanical alloying.[1][2] Previously, small batches of amorphous metals had been produced through a variety of quick-cooling methods, such as amorphous metal ribbons which had been produced by sputtering molten metal onto a spinning metal disk (melt spinning). The rapid cooling (in the order of millions of degrees Celsius a second) is too fast for crystals to form and the material is "locked" in a glassy state.[3] Currently, a number of alloys with critical cooling rates low enough to allow formation of amorphous structure in thick layers (over 1 millimetre or 0.039 inches) have been produced; these are known as bulk metallic glasses. More recently, batches of amorphous steel with three times the strength of conventional steel alloys have been produced. New techniques as 3D printing, also characterised by their high cooling rates, are an active research topic for manufacturing bulk metallic glasses.[4]

History edit

The first reported metallic glass was an alloy (Au75Si25) produced at Caltech by W. Klement (Jr.), Willens and Duwez in 1960.[5] This and other early glass-forming alloys had to be cooled extremely rapidly (on the order of one megakelvin per second, 106 K/s) to avoid crystallization. An important consequence of this was that metallic glasses could only be produced in a limited number of forms (typically ribbons, foils, or wires) in which one dimension was small so that heat could be extracted quickly enough to achieve the necessary cooling rate. As a result, metallic glass specimens (with a few exceptions) were limited to thicknesses of less than one hundred micrometers.

In 1969, an alloy of 77.5% palladium, 6% copper, and 16.5% silicon was found to have critical cooling rate between 100 and 1000 K/s.

In 1976, H. Liebermann and C. Graham developed a new method of manufacturing thin ribbons of amorphous metal on a supercooled fast-spinning wheel.[6] This was an alloy of iron, nickel, and boron. The material, known as Metglas, was commercialized in the early 1980s and is used for low-loss power distribution transformers (amorphous metal transformer). Metglas-2605 is composed of 80% iron and 20% boron, has a Curie temperature of 646 K (373 °C; 703 °F) and a room temperature saturation magnetization of 1.56 teslas.[7]

In the early 1980s, glassy ingots with a diameter of 5 mm (0.20 in) were produced from the alloy of 55% palladium, 22.5% lead, and 22.5% antimony, by surface etching followed with heating-cooling cycles. Using boron oxide flux, the achievable thickness was increased to a centimeter.[clarification needed]

In 1982, a study on amorphous metal structural relaxation indicated a relationship between the specific heat and temperature of (Fe0.5Ni0.5)83P17. As the material was heated up, the properties developed a negative relationship starting at 375 K, which was due to the change in relaxed amorphous states. When the material was annealed for periods from 1 to 48 hours , the properties developed a positive relationship starting at 475 K for all annealing periods, since the annealing induced structure disappears at that temperature.[8] In this study, amorphous alloys demonstrated glass transition and a super cooled liquid region. Between 1988 and 1992, more studies found more glass-type alloys with glass transition and a super cooled liquid region. From those studies, bulk glass alloys were made of La, Mg, and Zr, and these alloys demonstrated plasticity even when their ribbon thickness was increased from 20 μm to 50 μm. The plasticity was a stark difference to past amorphous metals that became brittle at those thicknesses.[8][9][10][11]

In 1988, alloys of lanthanum, aluminium, and copper ore were found to be highly glass-forming. Al-based metallic glasses containing Scandium exhibited a record-type tensile mechanical strength of about 1,500 MPa (220 ksi).[12]

Before new techniques were found in 1990, bulk amorphous alloys of several millimeters in thickness were rare, except for a few exceptions, Pd-based amorphous alloys had been formed into rods with a 2 mm (0.079 in) diameter by quenching,[13] and spheres with a 10 mm (0.39 in) diameter were formed by repetition flux melting with B2O3 and quenching.[14]

In the 1990s new alloys were developed that form glasses at cooling rates as low as one kelvin per second. These cooling rates can be achieved by simple casting into metallic molds. These "bulk" amorphous alloys can be cast into parts of up to several centimeters in thickness (the maximum thickness depending on the alloy) while retaining an amorphous structure. The best glass-forming alloys are based on zirconium and palladium, but alloys based on iron, titanium, copper, magnesium, and other metals are also known. Many amorphous alloys are formed by exploiting a phenomenon called the "confusion" effect. Such alloys contain so many different elements (often four or more) that upon cooling at sufficiently fast rates, the constituent atoms simply cannot coordinate themselves into the equilibrium crystalline state before their mobility is stopped. In this way, the random disordered state of the atoms is "locked in".

In 1992, the commercial amorphous alloy, Vitreloy 1 (41.2% Zr, 13.8% Ti, 12.5% Cu, 10% Ni, and 22.5% Be), was developed at Caltech, as a part of Department of Energy and NASA research of new aerospace materials.[15]

By 2000, research in Tohoku University[16] and Caltech yielded multicomponent alloys based on lanthanum, magnesium, zirconium, palladium, iron, copper, and titanium, with critical cooling rate between 1 K/s and 100 K/s, comparable to oxide glasses.[clarification needed]

In 2004, bulk amorphous steel was successfully produced by two groups: one at Oak Ridge National Laboratory, who refers to their product as "glassy steel", and the other at the University of Virginia, calling theirs "DARVA-Glass 101".[17][18] The product is non-magnetic at room temperature and significantly stronger than conventional steel, though a long research and development process remains before the introduction of the material into public or military use.[19][20]

In 2018 a team at SLAC National Accelerator Laboratory, the National Institute of Standards and Technology (NIST) and Northwestern University reported the use of artificial intelligence to predict and evaluate samples of 20,000 different likely metallic glass alloys in a year. Their methods promise to speed up research and time to market for new amorphous metals alloys.[21][22]

Properties edit

Amorphous metal is usually an alloy rather than a pure metal. The alloys contain atoms of significantly different sizes, leading to low free volume (and therefore up to orders of magnitude higher viscosity than other metals and alloys) in molten state. The viscosity prevents the atoms moving enough to form an ordered lattice. The material structure also results in low shrinkage during cooling, and resistance to plastic deformation. The absence of grain boundaries, the weak spots of crystalline materials, leads to better resistance to wear[23] and corrosion. Amorphous metals, while technically glasses, are also much tougher and less brittle than oxide glasses and ceramics. Amorphous metals can be grouped in two categories, as either non-ferromagnetic, if they are composed of Ln, Mg, Zr, Ti, Pd, Ca, Cu, Pt and Au, or ferromagnetic alloys, if they are composed of Fe, Co, and Ni.[24]

Thermal conductivity of amorphous materials is lower than that of crystalline metal. As formation of amorphous structure relies on fast cooling, this limits the maximum achievable thickness of amorphous structures. To achieve formation of amorphous structure even during slower cooling, the alloy has to be made of three or more components, leading to complex crystal units with higher potential energy and lower chance of formation.[25] The atomic radius of the components has to be significantly different (over 12%), to achieve high packing density and low free volume. The combination of components should have negative heat of mixing, inhibiting crystal nucleation and prolonging the time the molten metal stays in supercooled state.

As temperatures change, the electrical resistivity of amorphous metals behaves very different than that of regular metals. While the resistivity in regular metals generally increases with temperature, following the Matthiessen's rule, the resistivity in a large number of amorphous metals is found to decrease with increasing temperature. This is effect can be observed in amorphous metals of high resistivities between 150 and 300 microohm-centimeters.[26] In these metals, the scattering events causing the resistivity of the metal can no longer be considered statistically independent, thus explaining the breakdown of the Matthiessen's rule. The fact that the thermal change of the resistivity in amorphous metals can be negative over a large range of temperatures and correlated to their absolute resistivity values was first observed by Mooij in 1973, hence coining the term "Mooij-rule".[27][28]

The alloys of boron, silicon, phosphorus, and other glass formers with magnetic metals (iron, cobalt, nickel) have high magnetic susceptibility, with low coercivity and high electrical resistance. Usually the electrical conductivity of a metallic glass is of the same low order of magnitude as of a molten metal just above the melting point. The high resistance leads to low losses by eddy currents when subjected to alternating magnetic fields, a property useful for e.g. transformer magnetic cores. Their low coercivity also contributes to low loss.

The superconductivity of amorphous metal thin films was discovered experimentally in the early 1950s by Buckel and Hilsch.[29] For certain metallic elements the superconducting critical temperature Tc can be higher in the amorphous state (e.g. upon alloying) than in the crystalline state, and in several cases Tc increases upon increasing the structural disorder. This behavior can be understood and rationalized by considering the effect of structural disorder on the electron-phonon coupling.[30]

Amorphous metals have higher tensile yield strengths and higher elastic strain limits than polycrystalline metal alloys, but their ductilities and fatigue strengths are lower.[31] Amorphous alloys have a variety of potentially useful properties. In particular, they tend to be stronger than crystalline alloys of similar chemical composition, and they can sustain larger reversible ("elastic") deformations than crystalline alloys. Amorphous metals derive their strength directly from their non-crystalline structure, which does not have any of the defects (such as dislocations) that limit the strength of crystalline alloys. One modern amorphous metal, known as Vitreloy, has a tensile strength that is almost twice that of high-grade titanium. However, metallic glasses at room temperature are not ductile and tend to fail suddenly when loaded in tension, which limits the material applicability in reliability-critical applications, as the impending failure is not evident. Therefore, there is considerable interest in producing metal matrix composites consisting of a ductile crystalline metal matrix containing dendritic particles or fibers of a amorphous glass metal.

Perhaps the most useful property of bulk amorphous alloys is that they are true glasses, which means that they soften and flow upon heating. This allows for easy processing, such as by injection molding, in much the same way as polymers. As a result, amorphous alloys have been commercialized for use in sports equipment,[32] medical devices, and as cases for electronic equipment.[33]

Thin films of amorphous metals can be deposited via high velocity oxygen fuel technique as protective coatings.

Applications edit

Commercial edit

Currently the most important application is due to the special magnetic properties of some ferromagnetic metallic glasses. The low magnetization loss is used in high efficiency transformers (amorphous metal transformer) at line frequency and some higher frequency transformers. Amorphous steel is a very brittle material which makes it difficult to punch into motor laminations.[34] Also electronic article surveillance (such as theft control passive ID tags,) often uses metallic glasses because of these magnetic properties.

A commercial amorphous alloy, Vitreloy 1 (41.2% Zr, 13.8% Ti, 12.5% Cu, 10% Ni, and 22.5% Be), was developed at Caltech, as a part of Department of Energy and NASA research of new aerospace materials.[15]

Ti-based metallic glass, when made into thin pipes, have a high tensile strength of 2,100 MPa (300 ksi), elastic elongation of 2% and high corrosion resistance.[35] Using these properties, a Ti–Zr–Cu–Ni–Sn metallic glass was used to improve the sensitivity of a Coriolis flow meter. This flow meter is about 28-53 times more sensitive than conventional meters,[36] which can be applied in fossil-fuel, chemical, environmental, semiconductor and medical science industry.

Zr-Al-Ni-Cu based metallic glass can be shaped into 2.2 to 5 by 4 mm (0.087 to 0.197 by 0.157 in) pressure sensors for automobile and other industries, and these sensors are smaller, more sensitive, and possess greater pressure endurance compared to conventional stainless steel made from cold working. Additionally, this alloy was used to make the world's smallest geared motor with diameter 1.5 and 9.9 mm (0.059 and 0.390 in) to be produced and sold at the time.[37]

Potential edit

Amorphous metals exhibit unique softening behavior above their glass transition and this softening has been increasingly explored for thermoplastic forming of metallic glasses.[38] Such low softening temperature allows for developing simple methods for making composites of nanoparticles (e.g. carbon nanotubes) and bulk metallic glasses. It has been shown that metallic glasses can be patterned on extremely small length scales ranging from 10 nm to several millimeters.[39] This may solve the problems of nanoimprint lithography where expensive nano-molds made of silicon break easily. Nano-molds made from metallic glasses are easy to fabricate and more durable than silicon molds. The superior electronic, thermal and mechanical properties of bulk metallic glasses compared to polymers make them a good option for developing nanocomposites for electronic application such as field electron emission devices.[40]

Ti40Cu36Pd14Zr10 is believed to be noncarcinogenic, is about three times stronger than titanium, and its elastic modulus nearly matches bones. It has a high wear resistance and does not produce abrasion powder. The alloy does not undergo shrinkage on solidification. A surface structure can be generated that is biologically attachable by surface modification using laser pulses, allowing better joining with bone.[41]

Mg60Zn35Ca5, rapidly cooled to achieve amorphous structure, is being investigated at Lehigh University as a biomaterial for implantation into bones as screws, pins, or plates, to fix fractures. Unlike traditional steel or titanium, this material dissolves in organisms at a rate of roughly 1 millimeter per month and is replaced with bone tissue. This speed can be adjusted by varying the content of zinc.[42]

Bulk metallic glasses also seem to exhibit superior properties like SAM2X5-630 which has the highest recorded elastic limit for any steel alloy, according to the researcher, essentially it has the highest threshold limit at which a material can withstand an impact without deforming permanently(plasticity). The alloy can withstand pressure and stress of up to 12.5 GPa (123,000 atm) without undergoing any permanent deformation, this is the highest impact resistance of any bulk metallic glass ever recorded (as of 2016) .This makes it as an attractive option for Armour material and other applications which requires high stress tolerance.[43][44][45]

Additive manufacturing edit

One challenge when synthesising a metallic glass is that the techniques often only produce very small samples, due to the need for high cooling rates. 3D-printing methods have been suggested as a method to create larger bulk samples. Selective laser melting (SLM) is one example of an additive manufacturing method that has been used to make iron based metallic glasses.[46][47] Laser foil printing (LFP) is another method where foils of the amorphous metals are stacked and welded together, layer by layer.[48]

Modeling and theory edit

Bulk metallic glasses have been modeled using atomic scale simulations (within the density functional theory framework) in a similar manner to high entropy alloys.[49][50] This has allowed predictions to be made about their behavior, stability and many more properties. As such, new bulk metallic glass systems can be tested and tailored for a specific purpose (e.g. bone replacement or aero-engine component) without as much empirical searching of the phase space or experimental trial and error. Ab-initio molecular dynamics (MD) simulation confirmed that the atomic surface structure of a Ni-Nb metallic glass observed by scanning tunneling microscopy is a kind of spectroscopy. At negative applied bias it visualizes only one soft of atoms (Ni) owing to the structure of electronic density of states calculated using ab-initio MD simulation.[51]

One common way to try and understand the electronic properties of amorphous metals is by comparing them to liquid metals, which are similarly disordered, and for which established theoretical frameworks exist. For simple amorphous metals, good estimations can be reached by semi-classical modelling of the movement of individual electrons using the Boltzmann equation and approximating the scattering potential as the superposition of the electronic potential of each nucleus in the surrounding metal. To simplify the calculations, the electronic potentials of the atomic nuclei can be truncated to give a muffin-tin pseudopotential. In this theory, there are two main effects that govern the change of resistivity with increasing temperatures. Both are based on the induction of vibrations of the atomic nuclei of the metal as temperatures increase. One is, that the atomic structure gets increasingly smeared out as the exact positions of the atomic nuclei get less and less well defined. The other is the introduction of phonons. While the smearing out generally decreases the resistivity of the metal, the introduction of phonons generally adds scattering sites and therefore increases resistivity. Together, they can explain the anomalous decrease of resistivity in amorphous metals, as the first part outweighs the second. In contrast to regular crystalline metals, the phonon contribution in an amorphous metal does not get frozen out at low temperatures. Due to the lack of a defined crystal structure, there are always some phonon wavelengths that can be excited.[52][53] While this semi-classical approach holds well for many amorphous metals, it generally breaks down under more extreme conditions. At very low temperatures, the quantum nature of the electrons leads to long range interference effects of the electrons with each other in what is called "weak localization effects".[26] In very strongly disordered metals, impurities in the atomic structure can induce bound electronic states in what is called "Anderson localization", effectively binding the electrons and inhibiting their movement.[54]

See also edit

References edit

  1. ^ Some scientists only consider amorphous metals produced by rapid cooling from a liquid state to be glasses. Materials scientists commonly consider a glass to be any solid non-crystalline material, regardless of how it is produced.
  2. ^ Ojovan, M. I.; Lee, W. B. E. (2010). "Connectivity and glass transition in disordered oxide systems". Journal of Non-Crystalline Solids. 356 (44–49): 2534. Bibcode:2010JNCS..356.2534O. doi:10.1016/j.jnoncrysol.2010.05.012.
  3. ^ Luborski, F E (1983). Amorphous Metallic Alloys. Butterworths. pp. 3–7. ISBN 0408110309.
  4. ^ Zhang, Cheng; Ouyang, Di; Pauly, Simon; Liu, Lin (2021-07-01). "3D printing of bulk metallic glasses". Materials Science and Engineering: R: Reports. 145: 100625. doi:10.1016/j.mser.2021.100625. ISSN 0927-796X. S2CID 236233658.
  5. ^ Klement, W.; Willens, R. H.; Duwez, POL (1960). "Non-crystalline Structure in Solidified Gold-Silicon Alloys". Nature. 187 (4740): 869–870. Bibcode:1960Natur.187..869K. doi:10.1038/187869b0. S2CID 4203025.
  6. ^ Libermann H. & Graham C. (1976). "Production Of Amorphous Alloy Ribbons And Effects Of Apparatus Parameters On Ribbon Dimensions". IEEE Transactions on Magnetics. 12 (6): 921. Bibcode:1976ITM....12..921L. doi:10.1109/TMAG.1976.1059201.
  7. ^ Roya, R & Majumdara, A.K. (1981). "Thermomagnetic and transport properties of metglas 2605 SC and 2605". Journal of Magnetism and Magnetic Materials. 25 (1): 83–89. Bibcode:1981JMMM...25...83R. doi:10.1016/0304-8853(81)90150-5.
  8. ^ a b Chen, H. S.; Inoue, A.; Masumoto, T. (July 1985). "Two-stage enthalpy relaxation behaviour of (Fe0.5Ni0.5)83P17 and (Fe0.5Ni0.5)83B17 amorphous alloys upon annealing". Journal of Materials Science. 20 (7): 2417–2438. Bibcode:1985JMatS..20.2417C. doi:10.1007/BF00556071. S2CID 136986230.
  9. ^ Yokoyama, Yoshihiko; Inoue, Akihisa (2007). "Compositional Dependence of Thermal and Mechanical Properties of Quaternary Zr-Cu-Ni-Al Bulk Glassy Alloys". Materials Transactions. 48 (6): 1282–1287. doi:10.2320/matertrans.MF200622.
  10. ^ Inoue, Akihisa; Zhang, Tao (1996). "Fabrication of Bulk Glassy Zr55Al10Ni5Cu30 Alloy of 30 mm in Diameter by a Suction Casting Method". Materials Transactions, JIM. 37 (2): 185–187. doi:10.2320/matertrans1989.37.185.
  11. ^ Qin, C.L.; Zhang, W.; Zhang, Q.S.; Asami, K.; Inoue, A. (31 January 2011). "Chemical characteristics of the passive surface films formed on newly developed Cu–Zr–Ag–Al bulk metallic glasses". Journal of Materials Research. 23 (8): 2091–2098. doi:10.1557/JMR.2008.0284. S2CID 136849540.
  12. ^ Inoue, A.; Sobu, S.; Louzguine, D. V.; Kimura, H.; Sasamori, K. (2011). "Ultrahigh strength Al-based amorphous alloys containing Sc". Journal of Materials Research. 19 (5): 1539. Bibcode:2004JMatR..19.1539I. doi:10.1557/JMR.2004.0206. S2CID 136853150.
  13. ^ Chen, H.S; Turnbull, D (August 1969). "Formation, stability and structure of palladium-silicon based alloy glasses". Acta Metallurgica. 17 (8): 1021–1031. doi:10.1016/0001-6160(69)90048-0.
  14. ^ Kui, H. W.; Greer, A. L.; Turnbull, D. (15 September 1984). "Formation of bulk metallic glass by fluxing". Applied Physics Letters. 45 (6): 615–616. Bibcode:1984ApPhL..45..615K. doi:10.1063/1.95330.
  15. ^ a b Peker, A.; Johnson, W. L. (25 October 1993). "A highly processable metallic glass: Zr41.2Ti13.8Cu12.5Ni10.0Be22.5" (PDF). Applied Physics Letters. 63 (17): 2342–2344. Bibcode:1993ApPhL..63.2342P. doi:10.1063/1.110520.
  16. ^ Inoue, A. (2000). "Stabilization of metallic supercooled liquid and bulk amorphous alloys". Acta Materialia. 48 (1): 279–306. Bibcode:2000AcMat..48..279I. CiteSeerX 10.1.1.590.5472. doi:10.1016/S1359-6454(99)00300-6.
  17. ^ U.Va. News Service, "University Of Virginia Scientists Discover Amorphous Steel Material is three times stronger than conventional steel and non-magnetic" 2014-10-30 at the Wayback Machine, U.Va. News Services, 7/2/2004
  18. ^ Google Patents listing for Patent WO 2006091875 A2, "Patent WO 2006091875 A2 - Amorphous steel composites with enhanced strengths, elastic properties and ductilities (Also published as US20090025834, WO2006091875A3)", Joseph S Poon, Gary J Shiflet, Univ Virginia, 8/31/2006
  19. ^ . ORNL Review. 38 (1). 2005. Archived from the original on 2005-04-08. Retrieved 2005-12-26.
  20. ^ Ponnambalam, V.; Poon, S. J.; Shiflet, G. J. (2011). "Fe-based bulk metallic glasses with diameter thickness larger than one centimeter". Journal of Materials Research. 19 (5): 1320. Bibcode:2004JMatR..19.1320P. doi:10.1557/JMR.2004.0176. S2CID 138846816.
  21. ^ "Artificial intelligence accelerates discovery of metallic glass". Physorg. April 13, 2018. Retrieved 2018-04-14.
  22. ^ Ren, Fang; Ward, Logan; Williams, Travis; Laws, Kevin J.; Wolverton, Christopher; Hattrick-Simpers, Jason; Mehta, Apurva (13 April 2018). "Accelerated discovery of metallic glasses through iteration of machine learning and high-throughput experiments". Science Advances. 4 (4): eaaq1566. Bibcode:2018SciA....4.1566R. doi:10.1126/sciadv.aaq1566. PMC 5898831. PMID 29662953.
  23. ^ Gloriant, Thierry (2003). "Microhardness and abrasive wear resistance of metallic glasses and nanostructured composite materials". Journal of Non-Crystalline Solids. 316 (1): 96–103. Bibcode:2003JNCS..316...96G. doi:10.1016/s0022-3093(02)01941-5.
  24. ^ Inoue, A.; Takeuchi, A. (April 2011). "Recent development and application products of bulk glassy alloys☆". Acta Materialia. 59 (6): 2243–2267. Bibcode:2011AcMat..59.2243I. doi:10.1016/j.actamat.2010.11.027.
  25. ^ Suryanarayana, C.; Inoue, A. (2011-06-03). Bulk Metallic Glasses. CRC Press. ISBN 978-1-4398-5969-8.[page needed]
  26. ^ a b Gantmakher, V. F. (December 2011). "Mooij rule and weak localization". JETP Letters. 94 (8): 626–628. arXiv:1112.0429. doi:10.1134/S0021364011200033. ISSN 0021-3640. S2CID 119258416.
  27. ^ Mooij, J. H. (1973). "Electrical conduction in concentrated disordered transition metal alloys". Physica Status Solidi A. 17 (2): 521–530. Bibcode:1973PSSAR..17..521M. doi:10.1002/pssa.2210170217. ISSN 1521-396X. S2CID 96960303.
  28. ^ Ciuchi, Sergio; Di Sante, Domenico; Dobrosavljević, Vladimir; Fratini, Simone (December 2018). "The origin of Mooij correlations in disordered metals". npj Quantum Materials. 3 (1): 44. arXiv:1802.00065. Bibcode:2018npjQM...3...44C. doi:10.1038/s41535-018-0119-y. ISSN 2397-4648. S2CID 55811938.
  29. ^ Buckel, W.; Hilsch, R. (1956). "Supraleitung und elektrischer Widerstand neuartiger Zinn-Wismut-Legierungen". Z. Phys. 146 (1): 27–38. Bibcode:1956ZPhy..146...27B. doi:10.1007/BF01326000. S2CID 119405703.
  30. ^ Baggioli, Matteo; Setty, Chandan; Zaccone, Alessio (2020). "Effective theory of superconductivity in strongly coupled amorphous materials". Physical Review B. 101 (21): 214502. arXiv:2001.00404. Bibcode:2020PhRvB.101u4502B. doi:10.1103/PhysRevB.101.214502. S2CID 209531947.
  31. ^ Russell, Alan & Lee, Kok Loong (2005). Structure-Property Relations in Nonferrous Metals. John Wiley & Sons. p. 92. Bibcode:2005srnm.book.....R. ISBN 978-0-471-70853-7.
  32. ^ "Amorphous Alloy Surpasses Steel And Titanium". NASA. Retrieved 2018-09-19.
  33. ^ Telford, Mark (2004). "The case for bulk metallic glass". Materials Today. 7 (3): 36–43. doi:10.1016/S1369-7021(04)00124-5.
  34. ^ Ning, S. R.; Gao, J.; Wang, Y. G. (2010). "Review on Applications of Low Loss Amorphous Metals in Motors". Advanced Materials Research. 129–131: 1366–1371. doi:10.4028/www.scientific.net/AMR.129-131.1366. S2CID 138234876.
  35. ^ Nishiyama, Nobuyuki; Amiya, Kenji; Inoue, Akihisa (October 2007). "Novel applications of bulk metallic glass for industrial products". Journal of Non-Crystalline Solids. 353 (32–40): 3615–3621. Bibcode:2007JNCS..353.3615N. doi:10.1016/j.jnoncrysol.2007.05.170.
  36. ^ Nishiyama, N.; Amiya, K.; Inoue, A. (March 2007). "Recent progress of bulk metallic glasses for strain-sensing devices". Materials Science and Engineering: A. 449–451: 79–83. doi:10.1016/j.msea.2006.02.384.
  37. ^ Inoue, A.; Wang, X.M.; Zhang, W. (2008). "Developments and applications of bulk metal glasses". Reviews on Advanced Materials Science. 18 (1): 1–9. CiteSeerX 10.1.1.455.4625.
  38. ^ Saotome, Y.; Iwazaki, H. (2000). "Superplastic extrusion of microgear shaft of 10 μm in module". Microsystem Technologies. 6 (4): 126. doi:10.1007/s005420050180. S2CID 137549527.
  39. ^ Kumar, G.; Tang, H. X.; Schroers, J. (2009). "Nanomoulding with amorphous metals". Nature. 457 (7231): 868–872. Bibcode:2009Natur.457..868K. doi:10.1038/nature07718. PMID 19212407. S2CID 4337794.
  40. ^ Hojati-Talemi, Pejman (2011). "High performance bulk metallic glass/carbon nanotube composite cathodes for electron field emission". Applied Physics Letters. 99 (19): 194104. Bibcode:2011ApPhL..99s4104H. doi:10.1063/1.3659898.
  41. ^ Maruyama, Masaaki (June 11, 2009). "Japanese Universities Develop Ti-based Metallic Glass for Artificial Finger Joint". Tech-on.
  42. ^ "Fixing bones with dissolvable glass". Institute of Physics. October 1, 2009.
  43. ^ "Engineers Develop Record-Breaking Steel". Engineering.com. Retrieved 2022-06-24.
  44. ^ "Record-breaking steel could be used for body armor, shields for satellites". jacobsschool.ucsd.edu. Retrieved 2022-06-24.
  45. ^ "SAM2X5-630: The steel industry fights back! | Writing about cars". writingaboutcars.com. Retrieved 2022-06-24.
  46. ^ Pauly, Simon; Löber, Lukas; Petters, Romy; Stoica, Mihai; Scudino, Sergio; Kühn, Uta; Eckert, Jürgen (2013-01-01). "Processing metallic glasses by selective laser melting". Materials Today. 16 (1–2): 37–41. doi:10.1016/j.mattod.2013.01.018. ISSN 1369-7021.
  47. ^ Jung, Hyo Yun; Choi, Su Ji; Prashanth, Konda G.; Stoica, Mihai; Scudino, Sergio; Yi, Seonghoon; Kühn, Uta; Kim, Do Hyang; Kim, Ki Buem; Eckert, Jürgen (2015-12-05). "Fabrication of Fe-based bulk metallic glass by selective laser melting: A parameter study". Materials & Design. 86: 703–708. doi:10.1016/j.matdes.2015.07.145. ISSN 0264-1275.
  48. ^ Shen, Yiyu; Li, Yingqi; Chen, Chen; Tsai, Hai-Lung (2017-03-05). "3D printing of large, complex metallic glass structures". Materials & Design. 117: 213–222. doi:10.1016/j.matdes.2016.12.087. ISSN 0264-1275.
  49. ^ King, D.M.; Middleburgh, S.C.; Liu, A.C.Y.; Tahini, H.A.; Lumpkin, G.R.; Cortie, M. (January 2014). "Formation and structure of V–Zr amorphous alloy thin films" (PDF). Acta Materialia. 83: 269–275. Bibcode:2015AcMat..83..269K. doi:10.1016/j.actamat.2014.10.016. hdl:10453/41214.
  50. ^ Middleburgh, S.C.; Burr, P.A.; King, D.M.; Edwards, L.; Lumpkin, G.R.; Grimes, R.W. (November 2015). "Structural stability and fission product behaviour in U3Si". Journal of Nuclear Materials. 466: 739–744. Bibcode:2015JNuM..466..739M. doi:10.1016/j.jnucmat.2015.04.052.
  51. ^ Belosludov, R (2020), "The atomic structure of a bulk metallic glass resolved by scanning tunneling microscopy and ab-initio", Journal of Alloys and Compounds, 816, p. 152680, doi:10.1016/j.jallcom.2019.152680, S2CID 210756852
  52. ^ Ziman, J. M. (1961-08-01). "A theory of the electrical properties of liquid metals. I: The monovalent metals". The Philosophical Magazine. 6 (68): 1013–1034. Bibcode:1961PMag....6.1013Z. doi:10.1080/14786436108243361. ISSN 0031-8086.
  53. ^ Nagel, S. R. (1977-08-15). "Temperature dependence of the resistivity in metallic glasses". Physical Review B. 16 (4): 1694–1698. Bibcode:1977PhRvB..16.1694N. doi:10.1103/PhysRevB.16.1694.
  54. ^ Anderson, P. W. (1958-03-01). "Absence of Diffusion in Certain Random Lattices". Physical Review. 109 (5): 1492–1505. Bibcode:1958PhRv..109.1492A. doi:10.1103/PhysRev.109.1492.

Further reading edit

  • Duarte, M. J.; Bruna, P.; Pineda, E.; Crespo, D.; Garbarino, G.; Verbeni, R.; Zhao, K.; Wang, W. H.; Romero, A. H.; Serrano, J. (2011). "Polyamorphic transitions in Ce-based metallic glasses by synchrotron radiation". Physical Review B. 84 (22): 224116. doi:10.1103/PhysRevB.84.224116. ISSN 1098-0121.
  • Liu, Chaoren; Pineda, Eloi; Crespo, Daniel (2015). "Mechanical Relaxation of Metallic Glasses: An Overview of Experimental Data and Theoretical Models". Metals. 5 (2): 1073–1111. doi:10.3390/met5021073. ISSN 2075-4701.

External links edit

  • "Metallic glass: a drop of the hard stuff" at New Scientist
  • Glass-Like Metal Performs Better Under Stress Physical Review Focus, June 9, 2005
  • "Overview of metallic glasses"
  • New Computational Method Developed By Carnegie Mellon University Physicist Could Speed Design and Testing of Metallic Glass (2004) (the alloy database developed by Marek Mihalkovic, Michael Widom, and others)
  • Telford, Mark (March 2004). "The case for bulk metallic glass". Materials Today. 7 (3): 36–43. doi:10.1016/S1369-7021(04)00124-5.
  • New tungsten-tantalum-copper amorphous alloy developed at the Korea Advanced Institute of Science and Technology
  • Kumar, Golden; Neibecker, Pascal; Liu, Yan Hui; Schroers, Jan (26 February 2013). "Critical fictive temperature for plasticity in metallic glasses". Nature Communications. 4 (1): 1536. Bibcode:2013NatCo...4.1536K. doi:10.1038/ncomms2546. PMC 3586724. PMID 23443564.
  • "New metallic glass material created by starving it of nuclei". newatlas.com. 8 December 2017. Retrieved 2017-12-09.
  • Metallic glasses and those composites, Materials Research Forum LLC, Millersville, PA, USA, (2018), p. 336 "Metallic Glasses and Their Composites". www.mrforum.com.

January 01, 1970
amorphous, metal, amorphous, metal, also, known, metallic, glass, glassy, metal, shiny, metal, solid, metallic, material, usually, alloy, with, disordered, atomic, scale, structure, most, metals, crystalline, their, solid, state, which, means, they, have, high. An amorphous metal also known as metallic glass glassy metal or shiny metal is a solid metallic material usually an alloy with disordered atomic scale structure Most metals are crystalline in their solid state which means they have a highly ordered arrangement of atoms Amorphous metals are non crystalline and have a glass like structure But unlike common glasses such as window glass which are typically electrical insulators amorphous metals have good electrical conductivity and can show metallic luster Samples of amorphous metal with millimeter scale There are several ways in which amorphous metals can be produced including extremely rapid cooling physical vapor deposition solid state reaction ion irradiation and mechanical alloying 1 2 Previously small batches of amorphous metals had been produced through a variety of quick cooling methods such as amorphous metal ribbons which had been produced by sputtering molten metal onto a spinning metal disk melt spinning The rapid cooling in the order of millions of degrees Celsius a second is too fast for crystals to form and the material is locked in a glassy state 3 Currently a number of alloys with critical cooling rates low enough to allow formation of amorphous structure in thick layers over 1 millimetre or 0 039 inches have been produced these are known as bulk metallic glasses More recently batches of amorphous steel with three times the strength of conventional steel alloys have been produced New techniques as 3D printing also characterised by their high cooling rates are an active research topic for manufacturing bulk metallic glasses 4 Contents 1 History 2 Properties 3 Applications 3 1 Commercial 3 2 Potential 4 Additive manufacturing 5 Modeling and theory 6 See also 7 References 8 Further reading 9 External linksHistory editThis article needs additional citations for verification Please help improve this article by adding citations to reliable sources Unsourced material may be challenged and removed Find sources Amorphous metal news newspapers books scholar JSTOR April 2012 Learn how and when to remove this message The first reported metallic glass was an alloy Au75Si25 produced at Caltech by W Klement Jr Willens and Duwez in 1960 5 This and other early glass forming alloys had to be cooled extremely rapidly on the order of one megakelvin per second 106 K s to avoid crystallization An important consequence of this was that metallic glasses could only be produced in a limited number of forms typically ribbons foils or wires in which one dimension was small so that heat could be extracted quickly enough to achieve the necessary cooling rate As a result metallic glass specimens with a few exceptions were limited to thicknesses of less than one hundred micrometers In 1969 an alloy of 77 5 palladium 6 copper and 16 5 silicon was found to have critical cooling rate between 100 and 1000 K s In 1976 H Liebermann and C Graham developed a new method of manufacturing thin ribbons of amorphous metal on a supercooled fast spinning wheel 6 This was an alloy of iron nickel and boron The material known as Metglas was commercialized in the early 1980s and is used for low loss power distribution transformers amorphous metal transformer Metglas 2605 is composed of 80 iron and 20 boron has a Curie temperature of 646 K 373 C 703 F and a room temperature saturation magnetization of 1 56 teslas 7 In the early 1980s glassy ingots with a diameter of 5 mm 0 20 in were produced from the alloy of 55 palladium 22 5 lead and 22 5 antimony by surface etching followed with heating cooling cycles Using boron oxide flux the achievable thickness was increased to a centimeter clarification needed In 1982 a study on amorphous metal structural relaxation indicated a relationship between the specific heat and temperature of Fe0 5Ni0 5 83P17 As the material was heated up the properties developed a negative relationship starting at 375 K which was due to the change in relaxed amorphous states When the material was annealed for periods from 1 to 48 hours the properties developed a positive relationship starting at 475 K for all annealing periods since the annealing induced structure disappears at that temperature 8 In this study amorphous alloys demonstrated glass transition and a super cooled liquid region Between 1988 and 1992 more studies found more glass type alloys with glass transition and a super cooled liquid region From those studies bulk glass alloys were made of La Mg and Zr and these alloys demonstrated plasticity even when their ribbon thickness was increased from 20 mm to 50 mm The plasticity was a stark difference to past amorphous metals that became brittle at those thicknesses 8 9 10 11 In 1988 alloys of lanthanum aluminium and copper ore were found to be highly glass forming Al based metallic glasses containing Scandium exhibited a record type tensile mechanical strength of about 1 500 MPa 220 ksi 12 Before new techniques were found in 1990 bulk amorphous alloys of several millimeters in thickness were rare except for a few exceptions Pd based amorphous alloys had been formed into rods with a 2 mm 0 079 in diameter by quenching 13 and spheres with a 10 mm 0 39 in diameter were formed by repetition flux melting with B2O3 and quenching 14 In the 1990s new alloys were developed that form glasses at cooling rates as low as one kelvin per second These cooling rates can be achieved by simple casting into metallic molds These bulk amorphous alloys can be cast into parts of up to several centimeters in thickness the maximum thickness depending on the alloy while retaining an amorphous structure The best glass forming alloys are based on zirconium and palladium but alloys based on iron titanium copper magnesium and other metals are also known Many amorphous alloys are formed by exploiting a phenomenon called the confusion effect Such alloys contain so many different elements often four or more that upon cooling at sufficiently fast rates the constituent atoms simply cannot coordinate themselves into the equilibrium crystalline state before their mobility is stopped In this way the random disordered state of the atoms is locked in In 1992 the commercial amorphous alloy Vitreloy 1 41 2 Zr 13 8 Ti 12 5 Cu 10 Ni and 22 5 Be was developed at Caltech as a part of Department of Energy and NASA research of new aerospace materials 15 By 2000 research in Tohoku University 16 and Caltech yielded multicomponent alloys based on lanthanum magnesium zirconium palladium iron copper and titanium with critical cooling rate between 1 K s and 100 K s comparable to oxide glasses clarification needed In 2004 bulk amorphous steel was successfully produced by two groups one at Oak Ridge National Laboratory who refers to their product as glassy steel and the other at the University of Virginia calling theirs DARVA Glass 101 17 18 The product is non magnetic at room temperature and significantly stronger than conventional steel though a long research and development process remains before the introduction of the material into public or military use 19 20 In 2018 a team at SLAC National Accelerator Laboratory the National Institute of Standards and Technology NIST and Northwestern University reported the use of artificial intelligence to predict and evaluate samples of 20 000 different likely metallic glass alloys in a year Their methods promise to speed up research and time to market for new amorphous metals alloys 21 22 Properties editThis section needs additional citations for verification Please help improve this article by adding citations to reliable sources in this section Unsourced material may be challenged and removed March 2019 Learn how and when to remove this message Amorphous metal is usually an alloy rather than a pure metal The alloys contain atoms of significantly different sizes leading to low free volume and therefore up to orders of magnitude higher viscosity than other metals and alloys in molten state The viscosity prevents the atoms moving enough to form an ordered lattice The material structure also results in low shrinkage during cooling and resistance to plastic deformation The absence of grain boundaries the weak spots of crystalline materials leads to better resistance to wear 23 and corrosion Amorphous metals while technically glasses are also much tougher and less brittle than oxide glasses and ceramics Amorphous metals can be grouped in two categories as either non ferromagnetic if they are composed of Ln Mg Zr Ti Pd Ca Cu Pt and Au or ferromagnetic alloys if they are composed of Fe Co and Ni 24 Thermal conductivity of amorphous materials is lower than that of crystalline metal As formation of amorphous structure relies on fast cooling this limits the maximum achievable thickness of amorphous structures To achieve formation of amorphous structure even during slower cooling the alloy has to be made of three or more components leading to complex crystal units with higher potential energy and lower chance of formation 25 The atomic radius of the components has to be significantly different over 12 to achieve high packing density and low free volume The combination of components should have negative heat of mixing inhibiting crystal nucleation and prolonging the time the molten metal stays in supercooled state As temperatures change the electrical resistivity of amorphous metals behaves very different than that of regular metals While the resistivity in regular metals generally increases with temperature following the Matthiessen s rule the resistivity in a large number of amorphous metals is found to decrease with increasing temperature This is effect can be observed in amorphous metals of high resistivities between 150 and 300 microohm centimeters 26 In these metals the scattering events causing the resistivity of the metal can no longer be considered statistically independent thus explaining the breakdown of the Matthiessen s rule The fact that the thermal change of the resistivity in amorphous metals can be negative over a large range of temperatures and correlated to their absolute resistivity values was first observed by Mooij in 1973 hence coining the term Mooij rule 27 28 The alloys of boron silicon phosphorus and other glass formers with magnetic metals iron cobalt nickel have high magnetic susceptibility with low coercivity and high electrical resistance Usually the electrical conductivity of a metallic glass is of the same low order of magnitude as of a molten metal just above the melting point The high resistance leads to low losses by eddy currents when subjected to alternating magnetic fields a property useful for e g transformer magnetic cores Their low coercivity also contributes to low loss The superconductivity of amorphous metal thin films was discovered experimentally in the early 1950s by Buckel and Hilsch 29 For certain metallic elements the superconducting critical temperature Tc can be higher in the amorphous state e g upon alloying than in the crystalline state and in several cases Tc increases upon increasing the structural disorder This behavior can be understood and rationalized by considering the effect of structural disorder on the electron phonon coupling 30 Amorphous metals have higher tensile yield strengths and higher elastic strain limits than polycrystalline metal alloys but their ductilities and fatigue strengths are lower 31 Amorphous alloys have a variety of potentially useful properties In particular they tend to be stronger than crystalline alloys of similar chemical composition and they can sustain larger reversible elastic deformations than crystalline alloys Amorphous metals derive their strength directly from their non crystalline structure which does not have any of the defects such as dislocations that limit the strength of crystalline alloys One modern amorphous metal known as Vitreloy has a tensile strength that is almost twice that of high grade titanium However metallic glasses at room temperature are not ductile and tend to fail suddenly when loaded in tension which limits the material applicability in reliability critical applications as the impending failure is not evident Therefore there is considerable interest in producing metal matrix composites consisting of a ductile crystalline metal matrix containing dendritic particles or fibers of a amorphous glass metal Perhaps the most useful property of bulk amorphous alloys is that they are true glasses which means that they soften and flow upon heating This allows for easy processing such as by injection molding in much the same way as polymers As a result amorphous alloys have been commercialized for use in sports equipment 32 medical devices and as cases for electronic equipment 33 Thin films of amorphous metals can be deposited via high velocity oxygen fuel technique as protective coatings Applications editCommercial edit Currently the most important application is due to the special magnetic properties of some ferromagnetic metallic glasses The low magnetization loss is used in high efficiency transformers amorphous metal transformer at line frequency and some higher frequency transformers Amorphous steel is a very brittle material which makes it difficult to punch into motor laminations 34 Also electronic article surveillance such as theft control passive ID tags often uses metallic glasses because of these magnetic properties A commercial amorphous alloy Vitreloy 1 41 2 Zr 13 8 Ti 12 5 Cu 10 Ni and 22 5 Be was developed at Caltech as a part of Department of Energy and NASA research of new aerospace materials 15 Ti based metallic glass when made into thin pipes have a high tensile strength of 2 100 MPa 300 ksi elastic elongation of 2 and high corrosion resistance 35 Using these properties a Ti Zr Cu Ni Sn metallic glass was used to improve the sensitivity of a Coriolis flow meter This flow meter is about 28 53 times more sensitive than conventional meters 36 which can be applied in fossil fuel chemical environmental semiconductor and medical science industry Zr Al Ni Cu based metallic glass can be shaped into 2 2 to 5 by 4 mm 0 087 to 0 197 by 0 157 in pressure sensors for automobile and other industries and these sensors are smaller more sensitive and possess greater pressure endurance compared to conventional stainless steel made from cold working Additionally this alloy was used to make the world s smallest geared motor with diameter 1 5 and 9 9 mm 0 059 and 0 390 in to be produced and sold at the time 37 Potential edit Amorphous metals exhibit unique softening behavior above their glass transition and this softening has been increasingly explored for thermoplastic forming of metallic glasses 38 Such low softening temperature allows for developing simple methods for making composites of nanoparticles e g carbon nanotubes and bulk metallic glasses It has been shown that metallic glasses can be patterned on extremely small length scales ranging from 10 nm to several millimeters 39 This may solve the problems of nanoimprint lithography where expensive nano molds made of silicon break easily Nano molds made from metallic glasses are easy to fabricate and more durable than silicon molds The superior electronic thermal and mechanical properties of bulk metallic glasses compared to polymers make them a good option for developing nanocomposites for electronic application such as field electron emission devices 40 Ti40Cu36Pd14Zr10 is believed to be noncarcinogenic is about three times stronger than titanium and its elastic modulus nearly matches bones It has a high wear resistance and does not produce abrasion powder The alloy does not undergo shrinkage on solidification A surface structure can be generated that is biologically attachable by surface modification using laser pulses allowing better joining with bone 41 Mg60Zn35Ca5 rapidly cooled to achieve amorphous structure is being investigated at Lehigh University as a biomaterial for implantation into bones as screws pins or plates to fix fractures Unlike traditional steel or titanium this material dissolves in organisms at a rate of roughly 1 millimeter per month and is replaced with bone tissue This speed can be adjusted by varying the content of zinc 42 Bulk metallic glasses also seem to exhibit superior properties like SAM2X5 630 which has the highest recorded elastic limit for any steel alloy according to the researcher essentially it has the highest threshold limit at which a material can withstand an impact without deforming permanently plasticity The alloy can withstand pressure and stress of up to 12 5 GPa 123 000 atm without undergoing any permanent deformation this is the highest impact resistance of any bulk metallic glass ever recorded as of 2016 This makes it as an attractive option for Armour material and other applications which requires high stress tolerance 43 44 45 Additive manufacturing editOne challenge when synthesising a metallic glass is that the techniques often only produce very small samples due to the need for high cooling rates 3D printing methods have been suggested as a method to create larger bulk samples Selective laser melting SLM is one example of an additive manufacturing method that has been used to make iron based metallic glasses 46 47 Laser foil printing LFP is another method where foils of the amorphous metals are stacked and welded together layer by layer 48 Modeling and theory editBulk metallic glasses have been modeled using atomic scale simulations within the density functional theory framework in a similar manner to high entropy alloys 49 50 This has allowed predictions to be made about their behavior stability and many more properties As such new bulk metallic glass systems can be tested and tailored for a specific purpose e g bone replacement or aero engine component without as much empirical searching of the phase space or experimental trial and error Ab initio molecular dynamics MD simulation confirmed that the atomic surface structure of a Ni Nb metallic glass observed by scanning tunneling microscopy is a kind of spectroscopy At negative applied bias it visualizes only one soft of atoms Ni owing to the structure of electronic density of states calculated using ab initio MD simulation 51 One common way to try and understand the electronic properties of amorphous metals is by comparing them to liquid metals which are similarly disordered and for which established theoretical frameworks exist For simple amorphous metals good estimations can be reached by semi classical modelling of the movement of individual electrons using the Boltzmann equation and approximating the scattering potential as the superposition of the electronic potential of each nucleus in the surrounding metal To simplify the calculations the electronic potentials of the atomic nuclei can be truncated to give a muffin tin pseudopotential In this theory there are two main effects that govern the change of resistivity with increasing temperatures Both are based on the induction of vibrations of the atomic nuclei of the metal as temperatures increase One is that the atomic structure gets increasingly smeared out as the exact positions of the atomic nuclei get less and less well defined The other is the introduction of phonons While the smearing out generally decreases the resistivity of the metal the introduction of phonons generally adds scattering sites and therefore increases resistivity Together they can explain the anomalous decrease of resistivity in amorphous metals as the first part outweighs the second In contrast to regular crystalline metals the phonon contribution in an amorphous metal does not get frozen out at low temperatures Due to the lack of a defined crystal structure there are always some phonon wavelengths that can be excited 52 53 While this semi classical approach holds well for many amorphous metals it generally breaks down under more extreme conditions At very low temperatures the quantum nature of the electrons leads to long range interference effects of the electrons with each other in what is called weak localization effects 26 In very strongly disordered metals impurities in the atomic structure can induce bound electronic states in what is called Anderson localization effectively binding the electrons and inhibiting their movement 54 See also editBioabsorbable metallic glass Glass ceramic to metal seals Liquidmetal Materials science Structure of liquids and glasses Amorphous brazing foilReferences edit Some scientists only consider amorphous metals produced by rapid cooling from a liquid state to be glasses Materials scientists commonly consider a glass to be any solid non crystalline material regardless of how it is produced Ojovan M I Lee W B E 2010 Connectivity and glass transition in disordered oxide systems Journal of Non Crystalline Solids 356 44 49 2534 Bibcode 2010JNCS 356 2534O doi 10 1016 j jnoncrysol 2010 05 012 Luborski F E 1983 Amorphous Metallic Alloys Butterworths pp 3 7 ISBN 0408110309 Zhang Cheng Ouyang Di Pauly Simon Liu Lin 2021 07 01 3D printing of bulk metallic glasses Materials Science and Engineering R Reports 145 100625 doi 10 1016 j mser 2021 100625 ISSN 0927 796X S2CID 236233658 Klement W Willens R H Duwez POL 1960 Non crystalline Structure in Solidified Gold Silicon Alloys Nature 187 4740 869 870 Bibcode 1960Natur 187 869K doi 10 1038 187869b0 S2CID 4203025 Libermann H amp Graham C 1976 Production Of Amorphous Alloy Ribbons And Effects Of Apparatus Parameters On Ribbon Dimensions IEEE Transactions on Magnetics 12 6 921 Bibcode 1976ITM 12 921L doi 10 1109 TMAG 1976 1059201 Roya R amp Majumdara A K 1981 Thermomagnetic and transport properties of metglas 2605 SC and 2605 Journal of Magnetism and Magnetic Materials 25 1 83 89 Bibcode 1981JMMM 25 83R doi 10 1016 0304 8853 81 90150 5 a b Chen H S Inoue A Masumoto T July 1985 Two stage enthalpy relaxation behaviour of Fe0 5Ni0 5 83P17 and Fe0 5Ni0 5 83B17 amorphous alloys upon annealing Journal of Materials Science 20 7 2417 2438 Bibcode 1985JMatS 20 2417C doi 10 1007 BF00556071 S2CID 136986230 Yokoyama Yoshihiko Inoue Akihisa 2007 Compositional Dependence of Thermal and Mechanical Properties of Quaternary Zr Cu Ni Al Bulk Glassy Alloys Materials Transactions 48 6 1282 1287 doi 10 2320 matertrans MF200622 Inoue Akihisa Zhang Tao 1996 Fabrication of Bulk Glassy Zr55Al10Ni5Cu30 Alloy of 30 mm in Diameter by a Suction Casting Method Materials Transactions JIM 37 2 185 187 doi 10 2320 matertrans1989 37 185 Qin C L Zhang W Zhang Q S Asami K Inoue A 31 January 2011 Chemical characteristics of the passive surface films formed on newly developed Cu Zr Ag Al bulk metallic glasses Journal of Materials Research 23 8 2091 2098 doi 10 1557 JMR 2008 0284 S2CID 136849540 Inoue A Sobu S Louzguine D V Kimura H Sasamori K 2011 Ultrahigh strength Al based amorphous alloys containing Sc Journal of Materials Research 19 5 1539 Bibcode 2004JMatR 19 1539I doi 10 1557 JMR 2004 0206 S2CID 136853150 Chen H S Turnbull D August 1969 Formation stability and structure of palladium silicon based alloy glasses Acta Metallurgica 17 8 1021 1031 doi 10 1016 0001 6160 69 90048 0 Kui H W Greer A L Turnbull D 15 September 1984 Formation of bulk metallic glass by fluxing Applied Physics Letters 45 6 615 616 Bibcode 1984ApPhL 45 615K doi 10 1063 1 95330 a b Peker A Johnson W L 25 October 1993 A highly processable metallic glass Zr41 2Ti13 8Cu12 5Ni10 0Be22 5 PDF Applied Physics Letters 63 17 2342 2344 Bibcode 1993ApPhL 63 2342P doi 10 1063 1 110520 Inoue A 2000 Stabilization of metallic supercooled liquid and bulk amorphous alloys Acta Materialia 48 1 279 306 Bibcode 2000AcMat 48 279I CiteSeerX 10 1 1 590 5472 doi 10 1016 S1359 6454 99 00300 6 U Va News Service University Of Virginia Scientists Discover Amorphous Steel Material is three times stronger than conventional steel and non magnetic Archived 2014 10 30 at the Wayback Machine U Va News Services 7 2 2004 Google Patents listing for Patent WO 2006091875 A2 Patent WO 2006091875 A2 Amorphous steel composites with enhanced strengths elastic properties and ductilities Also published as US20090025834 WO2006091875A3 Joseph S Poon Gary J Shiflet Univ Virginia 8 31 2006 Glassy Steel ORNL Review 38 1 2005 Archived from the original on 2005 04 08 Retrieved 2005 12 26 Ponnambalam V Poon S J Shiflet G J 2011 Fe based bulk metallic glasses with diameter thickness larger than one centimeter Journal of Materials Research 19 5 1320 Bibcode 2004JMatR 19 1320P doi 10 1557 JMR 2004 0176 S2CID 138846816 Artificial intelligence accelerates discovery of metallic glass Physorg April 13 2018 Retrieved 2018 04 14 Ren Fang Ward Logan Williams Travis Laws Kevin J Wolverton Christopher Hattrick Simpers Jason Mehta Apurva 13 April 2018 Accelerated discovery of metallic glasses through iteration of machine learning and high throughput experiments Science Advances 4 4 eaaq1566 Bibcode 2018SciA 4 1566R doi 10 1126 sciadv aaq1566 PMC 5898831 PMID 29662953 Gloriant Thierry 2003 Microhardness and abrasive wear resistance of metallic glasses and nanostructured composite materials Journal of Non Crystalline Solids 316 1 96 103 Bibcode 2003JNCS 316 96G doi 10 1016 s0022 3093 02 01941 5 Inoue A Takeuchi A April 2011 Recent development and application products of bulk glassy alloys Acta Materialia 59 6 2243 2267 Bibcode 2011AcMat 59 2243I doi 10 1016 j actamat 2010 11 027 Suryanarayana C Inoue A 2011 06 03 Bulk Metallic Glasses CRC Press ISBN 978 1 4398 5969 8 page needed a b Gantmakher V F December 2011 Mooij rule and weak localization JETP Letters 94 8 626 628 arXiv 1112 0429 doi 10 1134 S0021364011200033 ISSN 0021 3640 S2CID 119258416 Mooij J H 1973 Electrical conduction in concentrated disordered transition metal alloys Physica Status Solidi A 17 2 521 530 Bibcode 1973PSSAR 17 521M doi 10 1002 pssa 2210170217 ISSN 1521 396X S2CID 96960303 Ciuchi Sergio Di Sante Domenico Dobrosavljevic Vladimir Fratini Simone December 2018 The origin of Mooij correlations in disordered metals npj Quantum Materials 3 1 44 arXiv 1802 00065 Bibcode 2018npjQM 3 44C doi 10 1038 s41535 018 0119 y ISSN 2397 4648 S2CID 55811938 Buckel W Hilsch R 1956 Supraleitung und elektrischer Widerstand neuartiger Zinn Wismut Legierungen Z Phys 146 1 27 38 Bibcode 1956ZPhy 146 27B doi 10 1007 BF01326000 S2CID 119405703 Baggioli Matteo Setty Chandan Zaccone Alessio 2020 Effective theory of superconductivity in strongly coupled amorphous materials Physical Review B 101 21 214502 arXiv 2001 00404 Bibcode 2020PhRvB 101u4502B doi 10 1103 PhysRevB 101 214502 S2CID 209531947 Russell Alan amp Lee Kok Loong 2005 Structure Property Relations in Nonferrous Metals John Wiley amp Sons p 92 Bibcode 2005srnm book R ISBN 978 0 471 70853 7 Amorphous Alloy Surpasses Steel And Titanium NASA Retrieved 2018 09 19 Telford Mark 2004 The case for bulk metallic glass Materials Today 7 3 36 43 doi 10 1016 S1369 7021 04 00124 5 Ning S R Gao J Wang Y G 2010 Review on Applications of Low Loss Amorphous Metals in Motors Advanced Materials Research 129 131 1366 1371 doi 10 4028 www scientific net AMR 129 131 1366 S2CID 138234876 Nishiyama Nobuyuki Amiya Kenji Inoue Akihisa October 2007 Novel applications of bulk metallic glass for industrial products Journal of Non Crystalline Solids 353 32 40 3615 3621 Bibcode 2007JNCS 353 3615N doi 10 1016 j jnoncrysol 2007 05 170 Nishiyama N Amiya K Inoue A March 2007 Recent progress of bulk metallic glasses for strain sensing devices Materials Science and Engineering A 449 451 79 83 doi 10 1016 j msea 2006 02 384 Inoue A Wang X M Zhang W 2008 Developments and applications of bulk metal glasses Reviews on Advanced Materials Science 18 1 1 9 CiteSeerX 10 1 1 455 4625 Saotome Y Iwazaki H 2000 Superplastic extrusion of microgear shaft of 10 mm in module Microsystem Technologies 6 4 126 doi 10 1007 s005420050180 S2CID 137549527 Kumar G Tang H X Schroers J 2009 Nanomoulding with amorphous metals Nature 457 7231 868 872 Bibcode 2009Natur 457 868K doi 10 1038 nature07718 PMID 19212407 S2CID 4337794 Hojati Talemi Pejman 2011 High performance bulk metallic glass carbon nanotube composite cathodes for electron field emission Applied Physics Letters 99 19 194104 Bibcode 2011ApPhL 99s4104H doi 10 1063 1 3659898 Maruyama Masaaki June 11 2009 Japanese Universities Develop Ti based Metallic Glass for Artificial Finger Joint Tech on Fixing bones with dissolvable glass Institute of Physics October 1 2009 Engineers Develop Record Breaking Steel Engineering com Retrieved 2022 06 24 Record breaking steel could be used for body armor shields for satellites jacobsschool ucsd edu Retrieved 2022 06 24 SAM2X5 630 The steel industry fights back Writing about cars writingaboutcars com Retrieved 2022 06 24 Pauly Simon Lober Lukas Petters Romy Stoica Mihai Scudino Sergio Kuhn Uta Eckert Jurgen 2013 01 01 Processing metallic glasses by selective laser melting Materials Today 16 1 2 37 41 doi 10 1016 j mattod 2013 01 018 ISSN 1369 7021 Jung Hyo Yun Choi Su Ji Prashanth Konda G Stoica Mihai Scudino Sergio Yi Seonghoon Kuhn Uta Kim Do Hyang Kim Ki Buem Eckert Jurgen 2015 12 05 Fabrication of Fe based bulk metallic glass by selective laser melting A parameter study Materials amp Design 86 703 708 doi 10 1016 j matdes 2015 07 145 ISSN 0264 1275 Shen Yiyu Li Yingqi Chen Chen Tsai Hai Lung 2017 03 05 3D printing of large complex metallic glass structures Materials amp Design 117 213 222 doi 10 1016 j matdes 2016 12 087 ISSN 0264 1275 King D M Middleburgh S C Liu A C Y Tahini H A Lumpkin G R Cortie M January 2014 Formation and structure of V Zr amorphous alloy thin films PDF Acta Materialia 83 269 275 Bibcode 2015AcMat 83 269K doi 10 1016 j actamat 2014 10 016 hdl 10453 41214 Middleburgh S C Burr P A King D M Edwards L Lumpkin G R Grimes R W November 2015 Structural stability and fission product behaviour in U3Si Journal of Nuclear Materials 466 739 744 Bibcode 2015JNuM 466 739M doi 10 1016 j jnucmat 2015 04 052 Belosludov R 2020 The atomic structure of a bulk metallic glass resolved by scanning tunneling microscopy and ab initio Journal of Alloys and Compounds 816 p 152680 doi 10 1016 j jallcom 2019 152680 S2CID 210756852 Ziman J M 1961 08 01 A theory of the electrical properties of liquid metals I The monovalent metals The Philosophical Magazine 6 68 1013 1034 Bibcode 1961PMag 6 1013Z doi 10 1080 14786436108243361 ISSN 0031 8086 Nagel S R 1977 08 15 Temperature dependence of the resistivity in metallic glasses Physical Review B 16 4 1694 1698 Bibcode 1977PhRvB 16 1694N doi 10 1103 PhysRevB 16 1694 Anderson P W 1958 03 01 Absence of Diffusion in Certain Random Lattices Physical Review 109 5 1492 1505 Bibcode 1958PhRv 109 1492A doi 10 1103 PhysRev 109 1492 Further reading editDuarte M J Bruna P Pineda E Crespo D Garbarino G Verbeni R Zhao K Wang W H Romero A H Serrano J 2011 Polyamorphic transitions in Ce based metallic glasses by synchrotron radiation Physical Review B 84 22 224116 doi 10 1103 PhysRevB 84 224116 ISSN 1098 0121 Liu Chaoren Pineda Eloi Crespo Daniel 2015 Mechanical Relaxation of Metallic Glasses An Overview of Experimental Data and Theoretical Models Metals 5 2 1073 1111 doi 10 3390 met5021073 ISSN 2075 4701 External links editLiquidmetal Design Guide Metallic glass a drop of the hard stuff at New Scientist Glass Like Metal Performs Better Under Stress Physical Review Focus June 9 2005 Overview of metallic glasses New Computational Method Developed By Carnegie Mellon University Physicist Could Speed Design and Testing of Metallic Glass 2004 the alloy database developed by Marek Mihalkovic Michael Widom and others Telford Mark March 2004 The case for bulk metallic glass Materials Today 7 3 36 43 doi 10 1016 S1369 7021 04 00124 5 New tungsten tantalum copper amorphous alloy developed at the Korea Advanced Institute of Science and Technology Digital Chosunilbo English Edition Daily News in English About Korea Amorphous Metals in Electric Power Distribution Applications Amorphous and Nanocrystalline Soft Magnets Kumar Golden Neibecker Pascal Liu Yan Hui Schroers Jan 26 February 2013 Critical fictive temperature for plasticity in metallic glasses Nature Communications 4 1 1536 Bibcode 2013NatCo 4 1536K doi 10 1038 ncomms2546 PMC 3586724 PMID 23443564 New metallic glass material created by starving it of nuclei newatlas com 8 December 2017 Retrieved 2017 12 09 Metallic glasses and those composites Materials Research Forum LLC Millersville PA USA 2018 p 336 Metallic Glasses and Their Composites www mrforum com Retrieved from https en wikipedia org w index php title Amorphous metal amp oldid 1226789578, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.