Kinetics and morphological evolution of liquid metal dealloying

McCue, Ian; Gaskey, Bernard; Geslin, Pierre-Antoine; Karma, Alain; Erlebacher, Jonah

doi:10.1016/j.actamat.2016.05.032

Cited by 117 publications

(76 citation statements)

References 29 publications

(35 reference statements)

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“…Coarsening kinetics of 3DNP HEA is drastically minimized at elevated temperatures ( Figure a,b). Using an Arrhenius‐type equation on the diffusivity and ligament size, the coarsening component, n , is determined to be 3.44–3.61, which is close to the kinetic parameter, ≈4, reflecting surface diffusion. Thus, surface diffusion governs the coarsening of the 3DNP HEA, as in the conventional porous metals .…”

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confidence: 80%

Beating Thermal Coarsening in Nanoporous Materials via High‐Entropy Design

et al. 2019

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produced by dealloying have outstanding physical properties due to their unique structure with open porous networks, [3][4][5] the undesirable coarsening phenomenon leads to degradation of physical properties over time, even at room temperature. [6][7][8] The originally proposed idea behind high-entropy alloy (HEA) with multiprinciple elements is maximizing the configuration entropy to stabilize a solid-solution alloy without undesired ordered intermetallics. [9][10][11] Many studies have suggested that HEAs uniquely possesses combined desirable properties such as a high strength and ductility paired with high fracture toughness, [12][13][14] fatigue resistance, [15] and creep resistance. [16] HEAs also show promising properties in harsh environments resisting corrosion, [17][18][19] and irradiation [20] attacks. Atomic size differences between constituting elements in HEA increase the activation energy for grain growth, and sluggish diffusion kinetics has considered as the main reason for the exceptional high strength and structural stability of HEAs at high temperatures. [21,22] The rationale behind it, the multiprinciple elements cause larger fluctuations in lattice potential energy (LPE), providing many low-LPE sites that hinder atomic diffusion. [23] Grain growth and ligament coarsening rely on the same physical background of surface diffusion. In that context, the high-entropy design in nanoporous materials has a potential for achieving an exceptional stability against the coarsening.Controlling the feature sizes of 3D bicontinuous nanoporous (3DNP) materials is essential for their advanced applications in catalysis, sensing, energy systems, etc., requiring high specific surface area. However, the intrinsic coarsening of nanoporous materials naturally reduces their surface energy leading to the deterioration of physical properties over time, even at ambient temperatures. A novel 3DNP material beating the universal relationship of thermal coarsening is reported via high-entropy alloy (HEA) design. In newly developed TiVNbMoTa 3DNP HEAs, the nanoporous structure is constructed by very fine nanoscale ligaments of a solid-solution phase due to enhanced phase stability by maximizing the configuration entropy and suppressed surface diffusion. The smallest size of 3DNP HEA synthesized at 873 K is about 10 nm, which is one order of magnitude smaller than that of conventional porous materials. More importantly, the yield strength of ligament in 3DNP HEA approaches its theoretical strength of G/2π of the corresponding HEA alloy even after thermal exposure. This finding signifies the key benefit of high-entropy design in nanoporous materials-exceptional stability of size-related physical properties. This high-entropy strategy should thus open new opportunities for developing ultrastable nanomaterials against its environment.The ORCID identification number(s) for the author(s) of this article can be found under https://doi.

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Beating Thermal Coarsening in Nanoporous Materials via High‐Entropy Design

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“…Recently, this limitation has been overcome with the development of liquid metal dealloying, that consists in using a molten metal to selectively dissolve one component out of a binary alloy [12]. This processing technique presents the advantage of being applicable to a wide range of metals including titanium [13], iron [14], niobium [15], and tantalum [16,17], or semiconductors such as silicon [18]. Also, comparable porous structures have been obtained from vapor phase dealloying that relies on the low partial pressure of one of the component of the alloy to trigger selective dissolution [19,20].…”

Section: Introductionmentioning

confidence: 99%

“…This coarsening process is important to control and limit as much as possible because it leads to a severe decrease of the specific surface area and therefore to a drop of materials properties. Common strategies consist of decreasing the surface diffusion by reducing the dealloying temperature [15,17,23] or adding impurities that reduce surface diffusivity [24,25].…”

Section: Introductionmentioning

confidence: 99%

Phase-field investigation of the coarsening of porous structures by surface diffusion

Geslin

Buchet

Wada

et al. 2019

Phys. Rev. Materials

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Nano and microporous connected structures have attracted increasing attention in the past decades due to their high surface area, presenting interesting properties for a number of applications. These structures generally coarsen by surface diffusion, leading to an enlargement of the structure characteristic length scale. We propose to study this coarsening behavior using a phase-field model for surface diffusion. In addition to reproducing the expected scaling law, our simulations enable to investigate precisely the evolution of the topological and morphological characteristics along the coarsening process. In particular, we show that after a transient regime, the coarsening is self-similar as exhibited by the evolution of both morphological and topological features. In addition, the influence of surface anisotropy is discussed and comparisons with experimental tomographic observations are presented.

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“…This phenomenon was first discovered by Harrison and Wagner in 1959 [ 16 ] and was re-introduced by Wada et al in 2011 [ 17 , 18 ]. Since then, considerable literature has been published on the kinetics of the process and the application of this technique to dealloy materials that cannot be dealloyed electrochemically [ 19 , 20 ], for instance, Ti and refractory metals, which were previously inaccessible due to their relatively low surface mobilities [ 21 ]. To date, liquid metal dealloying has been used to make bicontinuous porous structures of Nb [ 22 , 23 , 24 ], Ti [ 25 ], C [ 26 ], stainless steel [ 27 ] and Co-based alloys [ 28 , 29 ].…”

Section: Dealloyingmentioning

confidence: 99%

“…However, the dissolving element has decreased solubility in molten eutectic alloys compared to its solubility in single-element solvents, drastically slowing dealloying. McCue et al discussed how, due to this reduced solubility, they were unable to fully dealloy bulk samples using eutectic alloy baths, only reaching a dealloying depth of 150 μm after 60 min [ 19 ] The diffusion limitations in the dealloying medium through the dealloyed region became too severe. In contrast, the diameter of most AM powders is much smaller, so this issue with bulk samples can be also be avoided.…”

Section: Dealloying and Additive Manufacturingmentioning

confidence: 99%

Challenges and Opportunities for Integrating Dealloying Methods into Additive Manufacturing

Chuang

Erlebacher

2020

Materials

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The physical architecture of materials plays an integral role in determining material properties and functionality. While many processing techniques now exist for fabricating parts of any shape or size, a couple of techniques have emerged as facile and effective methods for creating unique structures: dealloying and additive manufacturing. This review discusses progress and challenges in the integration of dealloying techniques with the additive manufacturing (AM) platform to take advantage of the material processing capabilities established by each field. These methods are uniquely complementary: not only can we use AM to make nanoporous metals of complex, customized shapes—for instance, with applications in biomedical implants and microfluidics—but dealloying can occur simultaneously during AM to produce unique composite materials with nanoscale features of two interpenetrating phases. We discuss the experimental challenges of implementing these processing methods and how future efforts could be directed to address these difficulties. Our premise is that combining these synergistic techniques offers both new avenues for creating 3D functional materials and new functional materials that cannot be synthesized any other way. Dealloying and AM will continue to grow both independently and together as the materials community realizes the potential of this compelling combination.

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Kinetics and morphological evolution of liquid metal dealloying

Cited by 117 publications

References 29 publications

Beating Thermal Coarsening in Nanoporous Materials via High‐Entropy Design

Beating Thermal Coarsening in Nanoporous Materials via High‐Entropy Design

Phase-field investigation of the coarsening of porous structures by surface diffusion

Challenges and Opportunities for Integrating Dealloying Methods into Additive Manufacturing

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