Decomposition and primary crystallization in undercooled Zr41.2Ti13.8Cu12.5Ni10.0Be22.5 melts

Busch, Ralf; Schneider, S.; Peker, A.; Johnson, William L.

doi:10.1063/1.114487

Cited by 239 publications

(127 citation statements)

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“…15,16,4 These concentration modulations partially shift the composition towards the composition of the primarily solidified phase, which causes an increase of the nucleation probability. The resulting high nucleation rate would also lead to a faster crystallization process upon reheating.…”

Section: ͑2͒mentioning

confidence: 99%

“…In a complex system like Vit 1 an adequate description of the nucleation process will certainly have to go beyond the concept of steady-state nucleation. 5 Further influences such as, for example, decomposition processes, have to be considered [15][16][17] to explain the fine microstructures of Vit 1. 5 At this point, however, to discuss the different growth kinetics on crystallization the simplified approach of steady-state nucleation serves as a sufficient model.…”

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Pronounced asymmetry in the crystallization behavior during constant heating and cooling of a bulk metallic glass-forming liquid

et al. 1999

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The crystallization behavior of the supercooled bulk metallic glass-forming Zr 41 Ti 14 Cu 12 Ni 10 Be 23 liquid was studied with different heating and cooling rates. A rate of about 1 K/s is sufficient to suppress crystallization of the melt upon cooling from the equilibrium liquid. Upon heating, in contrast, a rate of about 200 K/s is necessary to avoid crystallization. The difference between the critical heating and cooling rate is discussed with respect to diffusion-limited growth taking classical nucleation into account. The calculated asymmetry of the critical heating and cooling rate can be explained by the fact that nuclei formed during cooling and heating are exposed to different growth rates. ͓S0163-1829͑99͒07441-X͔The ability to form a glass by cooling from the equilibrium liquid is equivalent to suppressing crystallization within the supercooled ͑undercooled͒ liquid. One of the central quantities in theoretical and experimental studies of glass formation is the critical cooling rate R c to bypass crystallization upon cooling from the stable melt. 1 Critical cooling rates of monoatomic metallic systems are typically of the order of 10 12 K/s. In contrast, R c of recently discovered multicomponent bulk metallic glass-forming alloys 2,3 is of the order of a few K/s. This excellent glass-forming ability enables investigations of crystallization, 4,5 viscosity, 6 and diffusion 7,8 as well as relaxation 9 in the supercooled liquid region. The critical cooling rate of Zr 41 Ti 14 Cu 12 Ni 10 Be 23 ͑Vit 1͒, studied in this work, is about 1 K/s. 10 In contrast, crystallization of amorphous Vit 1, previously investigated by differential scanning calorimetry ͑DSC͒ upon heating 11 could not be avoided up to the maximum heating rate of the DSC of 5 K/s and the critical heating rate has not been determined yet. The critical heating rate R h , the counterpart of the critical cooling rate upon heating, is the lowest rate an amorphous sample can be heated through the entire supercooled liquid region without crystallization.In this paper, the onset temperature of crystallization is investigated during cooling from the stable melt and heating amorphous Vit 1 as a function of cooling and heating rate, respectively. For this purpose we designed an experimental setup that permits maximum heating rates of 350 K/s and maximum cooling rates of 40 K/s. We will show that an asymmetry of R c and R h results from the fact that nuclei formed during cooling and heating are exposed to different growth rates, which is likely to be a general feature for metallic systems.The investigations were performed in high-purity graphite crucibles since heterogeneous surface nucleation at the container walls does not effect the crystallization of the bulk Vit 1 sample. 12 The samples were mounted into the graphite crucibles and inductively heated in vacuum of 10 Ϫ6 mbar or in a titanium-gettered argon atmosphere. The temperature was measured using a thermocouple ͑type K͒ with an accuracy better than Ϯ2 K. Details of the experimental setup can b...

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Section: ͑2͒mentioning

confidence: 99%

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Pronounced asymmetry in the crystallization behavior during constant heating and cooling of a bulk metallic glass-forming liquid

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“…Based on DSC experiments, AP/FIM results, 10 and transmission electron microscopy and small angle neutron scattering studies, 11 we believe that for these undercoolings a phase separation ͑event I͒ into Be-poor and Be-rich regions precedes the nucleation of crystals. According to Schneider et al, 11 the primary crystallization ͑event II͒ can be attributed to the formation of a nanocrystalline Be-poor and Tirich f.c.c.…”

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“…9 This phase separation was confirmed by atom probe field ion microscopy ͑AP/FIM͒ measurements on samples cooled with a rate of approximately 10 K/s. 10 The schedule of the construction of the TTT diagram is added in Fig. 1, indicating the isothermal experiments to determine the time required to reach the onset of crystallization at dif- ferent isothermal temperatures.…”

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Experimental determination of a time–temperature-transformation diagram of the undercooled Zr41.2Ti13.8Cu12.5Ni10.0Be22.5 alloy using the containerless electrostatic levitation processing technique

Kim

Busch

Johnson

et al. 1996

Applied Physics Letters

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High temperature high vacuum electrostatic levitation was used to determine the complete timetemperature-transformation ͑TTT͒ diagram of the Zr 41.2 Ti 13.8 Cu 12.5 Ni 10.0 Be 22.5 bulk metallic glass forming alloy in the undercooled liquid state. This is the first report of experimental data on the crystallization kinetics of a metallic system covering the entire temperature range of the undercooled melt down to the glass transition temperature. The measured TTT diagram exhibits the expected ''C'' shape. Existing models that assume polymorphic crystallization cannot satisfactorily explain the experimentally obtained TTT diagram. This originates from the complex crystallization mechanisms that occur in this bulk glass-forming system, involving large composition fluctuations prior to crystallization as well as phase separation in the undercooled liquid state below 800 K. © 1996 American Institute of Physics. ͓S0003-6951͑96͒03308-8͔The synthesis of bulk metallic glasses using low cooling rates was first achieved in the Ni-Pd-P alloy system. 1,2 Recently, after the discovery of several families of multicomponent alloys such as La-Al-Ni, 3 Zr-Al-Cu-Ni, 4 and Zr-Ti-Cu-Ni-Be, 5 bulk glass formation became a common phenomena. The undercooled liquid state of the latter alloy possesses an extremely high thermal stability with respect to crystallization. This lends the material to experimental study of its undercooling and solidification behavior. The containerless high-temperature high-vacuum electrostatic levitation ͑HTHVESL͒ processing technique 6 permits comprehensive studies of thermophysical properties in deeply undercooled liquid metals. By applying the HVHTESL technique to the Zr 41.2 Ti 13.8 Cu 12.5 Ni 10.0 Be 22.5 alloy, for example, the authors found that proper thermal treatment during solification results in the ''self-fluxing'' of the melt, allowing it to successfully undercool down to the glass transition with cooling rates of about 1 K/s. 7 Detailed thermodynamic studies were made to explain the stability of the undercooled liquid. 8 Thermophysical properties, such as specific heat capacity and total hemispherical emissivity, over the whole range of the undercooled liquid have been determined. 9 Due to the limited glass-forming ability of earlier alloys, the acquisition of basic data on crystallization kinetics in the deeply undercooled melts has not been previously possible. However, the application of the HVHTESL technique to the Zr 41.2 Ti 13.8 Cu 12.5 Ni 10.0 Be 22.5 alloy offers a new opportunity to study the crystallization kinetics in the entire undercooled melt down to the glass transition. In this letter, we report the experimental of the TTT diagram, which describes the occurrence of the crystallization events as a function of isothermal annealing time and temperature in the undercooled liquid. For the first time, we experimentally define the complete TTT diagram for the crystallization of an alloy for the whole range of the undercooled liquid, i.e., from the melting point down to the glass trans...

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“…In addition, crystallization mechanisms can be delineated in great detail in these systems. In a number of multicomponent metallic-glass-forming systems such as La-Al-Ni, 2 Zr-Y-Ni-Al, 3 and Zr-Ti-Cu-Ni-Be, [4][5][6] phase separation in the amorphous or supercooled liquid states has been observed and identified to be closely related to the primary crystallization process. Studies of phase separation therefore become important in understanding the thermal stability and the crystallization processes in metallic glasses.…”

Section: Introductionmentioning

confidence: 99%

Small-angle x-ray-scattering study of phase separation and crystallization in the bulk amorphousMg62Cu25
Liu
¹
,
Johnson
²
,
Schneider
³

et al. 1999
Phys. Rev. B
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We report on a small-angle x-ray-scattering ͑SAXS͒ and differential scanning calorimetry study of phase separation and crystallization in rapidly quenched amorphous Mg 62 Cu 25 Y 10 Li 3 alloy samples. Differential scanning calorimetry demonstrates the occurrence of crystallization and grain growth upon isothermal annealing of these samples at 135°C. The SAXS studies show the presence of large inhomogeneities even in the rapidly quenched as-prepared Mg 62 Cu 25 Y 10 Li 3 alloy that is attributed to phase separation in the undercooled liquid during the cooling process. After isothermal annealing at 135°C for longer than 30 min the samples exhibit a strong SAXS intensity that monotonically increases with increasing annealing time. During heat treatment, crystallization and growth of a nanocrystalline bcc-Mg 7 Li 3 phase occurs in the Y-poor and MgLirich domains. The initially rough boundaries of the nanocrystals become sharper with increasing annealing time. Anomalous small-angle x-ray-scattering investigations near the Cu K edge indicate that while Cu is distributed homogeneously in the as-prepared sample, a Cu composition gradient develops between the matrix and the bcc-Mg 7 Li 3 nanocrystals in the annealed sample. ͓S0163-1829͑99͒01018-8͔

show abstract

Decomposition and primary crystallization in undercooled Zr41.2Ti13.8Cu12.5Ni10.0Be22.5 melts

Cited by 239 publications

References 11 publications

Pronounced asymmetry in the crystallization behavior during constant heating and cooling of a bulk metallic glass-forming liquid

Pronounced asymmetry in the crystallization behavior during constant heating and cooling of a bulk metallic glass-forming liquid

Experimental determination of a time–temperature-transformation diagram of the undercooled Zr41.2Ti13.8Cu12.5Ni10.0Be22.5 alloy using the containerless electrostatic levitation processing technique

Small-angle x-ray-scattering study of phase separation and crystallization in the bulk amorphousMg62Cu25
Liu
¹
,
Johnson
²
,
Schneider
³

et al. 1999
Phys. Rev. B
Self Cite

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Decomposition and primary crystallization in undercooled Zr41.2Ti13.8Cu12.5Ni10.0Be22.5 melts

Cited by 239 publications

References 11 publications

Pronounced asymmetry in the crystallization behavior during constant heating and cooling of a bulk metallic glass-forming liquid

Pronounced asymmetry in the crystallization behavior during constant heating and cooling of a bulk metallic glass-forming liquid

Experimental determination of a time–temperature-transformation diagram of the undercooled Zr41.2Ti13.8Cu12.5Ni10.0Be22.5 alloy using the containerless electrostatic levitation processing technique

Small-angle x-ray-scattering study of phase separation and crystallization in the bulk amorphousMg62Cu25Liu1, Johnson2, Schneider3 et al. 1999Phys. Rev. BSelf Cite

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Small-angle x-ray-scattering study of phase separation and crystallization in the bulk amorphousMg62Cu25
Liu
¹
,
Johnson
²
,
Schneider
³

et al. 1999
Phys. Rev. B
Self Cite