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1. Double-tough and ultra-strong ceramics: leveraging multiscale toughening mechanisms through Bayesian Optimization

Author

Aiello, Francesco, Zhang, Jian, Brouwer, Johannes C., Salazar, Mauro, and Giuntini, Diletta

Subjects
Physics - Applied Physics
Abstract

We present an optimization-driven approach to creating a double-tough ceramic material with a brick-and-mortar microstructure, where the mortar is itself transformation-toughened, engineered with the goal of simultaneously achieving high strength and fracture toughness levels. Specifically, we design a material where high-strength alumina bricks are interconnected via a ceria-stabilized zirconia mortar. As the design of such a material, driven by multiscale toughening mechanisms, requires a laborious trial-and-error approach, we propose a Bayesian optimization framework as an integral part of our methodology to streamline and accelerate the design process. We use a Gaussian process to emulate the material's mechanical response and implement a cost-aware batch Bayesian optimization to efficiently identify optimal design process parameters, accounting for the cost of experimentally varying them. This approach expedites the optimization of the material's mechanical properties. As a result, we develop a bio-inspired all-ceramic composite that exhibits an exceptional balance between bending strength (704 MPa), and fracture toughness (13.6 MPa m^0.5).

Published
2024

2. Nanoindentation creep of supercrystalline nanocomposites

Author

Yan, Cong, Bor, Büsra, Plunkett, Alexander, Domènech, Berta, Maier-Kiener, Verena, and Giuntini, Diletta

Subjects
Condensed Matter - Materials Science
Abstract

Supercrystalline nanocomposites (SCNCs) are inorganic-organic hybrid materials with a unique periodic nanostructure, and as such they have been gaining growing attention for their intriguing functional properties and parallelisms with hierarchical biomaterials. Their mechanical behavior remains, however, poorly understood, even though its understanding and control are of paramount importance to allow SCNCs implementation into devices. An important aspect that has not been tackled yet is their time-dependent deformation behavior, which is nevertheless expected to play an important role in materials containing such a distribution of organic phase. Hereby, we report on the creep of ceramic-organic SCNCs with varying degrees of organic crosslinking, as assessed via nanoindentation. Creep strains and their partial recoverability are observed, hinting at the co-presence of viscoelasticity and viscoplasticity, and a clear effect of crosslinking in decreasing the overall material deformability. We rationalize our experimental observations with the analysis of stress exponent and activation volume, resulting in a power-law breakdown behavior and governing deformation mechanisms occurring at the organic sub-nm interfaces scale, in terms of organic ligands rearrangement. The set of results is reinforced by the evaluation of the strain rate sensitivity via strain rate jump tests, and the assessment of the effect of oscillations during continuous stiffness measurement mode.

Published
2022

7. Nanofatigue of supercrystalline nanocomposites

Author

Yan, Cong, Giuntini, Diletta, Yan, Cong, and Giuntini, Diletta

Abstract

Supercrystalline nanocomposites (SCNCs) are a new category of hybrid materials consisting of inorganic nanoparticles surface-functionalized with organic ligands and with periodic nanostructures, featuring multi-functionality and able to reach exceptional mechanical properties. Although efforts have been made to explore their mechanical behavior, their response to cyclic loading remains to be unveiled. Here, the fatigue behavior of SCNCs with different degrees of organic crosslinking is investigated via nanoindentation. The nanocomposites’ fatigue life is assessed, and it emerges that SCNCs without crosslinking are more efficient in dissipating energy under cyclic loading and thus feature a longer fatigue life. Chipping is identified as the main fatigue failure mechanism, whereas different mechanisms, intrinsic or extrinsic, dominate in the indentation depth propagation, again depending on crosslinking.

Published
2024

8. Modeling of time-dependent mechanical behavior of oleic acid nanocomposites using nanoindentation

Author

Kolli, Vasu, Scheider, Ingo, Ovri, Henry, Giuntini, Diletta, Cyron, Christian J., Kolli, Vasu, Scheider, Ingo, Ovri, Henry, Giuntini, Diletta, and Cyron, Christian J.

Abstract

Supercrystalline nanocomposites are a burgeoning class of hybrid inorganic–organic materials. Studies showed that self-assembly of iron oxide particles surface-functionalized with organic (e.g. oleic acid) ligands produces a supercrystalline nanocomposite with exceptional mechanical properties. Consequently, significant research has been conducted on these materials to experimentally characterize the mechanical properties of such materials. However, so far all modeling studies used time and rate independent elastoplastic material models. In the light of new experimental results, we propose to extent this view and use time-dependent models to capture viscoelastic behavior. To this end, we quantified this behavior using nanoindentation creep experiments and modeled it using a rheological network model with several parallel Maxwell branches and an additional elasto-plastic branch. We demonstrate how the parameters of such a model can be found using inverse analysis. With the calibrated material model, a good agreement of the time dependent behavior between simulation and experimental results is achieved. Thus, a method is provided to model time dependent behavior using complex non-classical experiments like nanoindentation.

Published
2024

14. Solvent controlled 2D structures of bottom-up fabricated nanoparticle superlattices

Author

Beck, E. Erik, Weimer, Agnes, Feld, Artur, Vonk, Vedran, Noei, Heshmat, Lott, Dieter, Jeromin, Arno, Kulkarni, Satishkumar, Giuntini, Diletta, Plunkett, Alexander, Domènech, Berta, Schneider, Gerold A., Vossmeyer, Tobias, Weller, Horst, Keller, Thomas F., Stierle, Andreas, Beck, E. Erik, Weimer, Agnes, Feld, Artur, Vonk, Vedran, Noei, Heshmat, Lott, Dieter, Jeromin, Arno, Kulkarni, Satishkumar, Giuntini, Diletta, Plunkett, Alexander, Domènech, Berta, Schneider, Gerold A., Vossmeyer, Tobias, Weller, Horst, Keller, Thomas F., and Stierle, Andreas

Abstract

We demonstrate that oleyl phosphate ligand-stabilized iron oxide nanocubes as building blocks can be assembled into 2D supercrystalline mono- and multilayers on flat YSZ substrates within a few minutes using a simple spin-coating process. As a bottom-up process, the growth takes place in a layer-by-layer mode and therefore by tuning the spin-coating parameters, the exact number of deposited monolayers can be controlled. Furthermore, ex situ scanning electron and atomic force microscopy as well as X-ray reflectivity measurements give evidence that the choice of solvent allows the control of the lattice type of the final supercrystalline monolayers. This observation can be assigned to the different Hansen solubilities of the solvents used for the nanoparticle dispersion because it determines the size and morphology of the ligand shell surrounding the nanoparticle core. Here, by using toluene and chloroform as solvents, it can be controlled whether the resulting monolayers are ordered in a square or hexagonal supercrystalline lattice.

Published
2023

15. Solvent controlled 2D structures of bottom-up fabricated nanoparticle superlattices

Author

Beck, Esko Erik, Weimer, Agnes, Feld, Artur, Vonk, Vedran, Noei, Heshmat, Lott, Dieter, Jeromin, Arno, Kulkarni, Satishkumar, Giuntini, Diletta, Plunkett, Alexander, Domènech Garcia, Berta, Schneider, Gerold A., Vossmeyer, Tobias, Weller, Horst, Keller, Thomas F., Stierle, Andreas, Beck, Esko Erik, Weimer, Agnes, Feld, Artur, Vonk, Vedran, Noei, Heshmat, Lott, Dieter, Jeromin, Arno, Kulkarni, Satishkumar, Giuntini, Diletta, Plunkett, Alexander, Domènech Garcia, Berta, Schneider, Gerold A., Vossmeyer, Tobias, Weller, Horst, Keller, Thomas F., and Stierle, Andreas

Abstract

We demonstrate that oleyl phosphate ligand-stabilized iron oxide nanocubes as building blocks can be assembled into 2D supercrystalline mono- and multilayers on flat YSZ substrates within a few minutes using a simple spin-coating process. As a bottom-up process, the growth takes place in a layer-by-layer mode and therefore by tuning the spin-coating parameters, the exact number of deposited monolayers can be controlled. Furthermore, ex situ scanning electron and atomic force microscopy as well as X-ray reflectivity measurements give evidence that the choice of solvent allows the control of the lattice type of the final supercrystalline monolayers. This observation can be assigned to the different Hansen solubilities of the solvents used for the nanoparticle dispersion because it determines the size and morphology of the ligand shell surrounding the nanoparticle core. Here, by using toluene and chloroform as solvents, it can be controlled whether the resulting monolayers are ordered in a square or hexagonal supercrystalline lattice.

Published
2023

17. Solvent controlled 2D structures of bottom-up fabricated nanoparticle superlattices

Author

Erik Beck, E., primary, Weimer, Agnes, additional, Feld, Artur, additional, Vonk, Vedran, additional, Noei, Heshmat, additional, Lott, Dieter, additional, Jeromin, Arno, additional, Kulkarni, Satishkumar, additional, Giuntini, Diletta, additional, Plunkett, Alexander, additional, Domènech, Berta, additional, Schneider, Gerold A., additional, Vossmeyer, Tobias, additional, Weller, Horst, additional, Keller, Thomas F., additional, and Stierle, Andreas, additional

Published
2023
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19. Strengthening Engineered Nanocrystal Three-Dimensional Superlattices via Ligand Conformation and Reactivity

Author

Plunkett, Alexander, primary, Kampferbeck, Michael, additional, Bor, Büsra, additional, Sazama, Uta, additional, Krekeler, Tobias, additional, Bekaert, Lieven, additional, Noei, Heshmat, additional, Giuntini, Diletta, additional, Fröba, Michael, additional, Stierle, Andreas, additional, Weller, Horst, additional, Vossmeyer, Tobias, additional, Schneider, Gerold A., additional, and Domènech, Berta, additional

Published
2022
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21. Strengthening engineered nanocrystalt three-dimensional superlattices via ligand conformation and reactivity

Author

Plunkett, Alexander, Kampferbeck, Michael, Bor, Büsra, Sazama, Uta, Krekeler, Tobias, Bekaert, Lieven, Noei, Heshmat, Giuntini, Diletta, Fröba, Michael, Stierle, Andreas, Weller, Horst, Vossmeyer, Tobias, Schneider, Gerold A., Domènech Garcia, Berta, Plunkett, Alexander, Kampferbeck, Michael, Bor, Büsra, Sazama, Uta, Krekeler, Tobias, Bekaert, Lieven, Noei, Heshmat, Giuntini, Diletta, Fröba, Michael, Stierle, Andreas, Weller, Horst, Vossmeyer, Tobias, Schneider, Gerold A., and Domènech Garcia, Berta

Abstract

Nanocrystal assembly into ordered structures provides mesostructural functional materials with a precise control that starts at the atomic scale. However, the lack of understanding on the self-assembly itself plus the poor structural integrity of the resulting supercrystalline materials still limits their application into engineered materials and devices. Surface functionalization of the nanobuilding blocks with organic ligands can be used not only as a means to control the interparticle interactions during self-assembly but also as a reactive platform to further strengthen the final material via ligand cross-linking. Here, we explore the influence of the ligands on superlattice formation and during cross-linking via thermal annealing. We elucidate the effect of the surface functionalization on the nanostructure during self-assembly and show how the ligand-promoted superlattice changes subsequently alter the cross-linking behavior. By gaining further insights on the chemical species derived from the thermally activated cross-linking and its effect in the overall mechanical response, we identify an oxidative radical polymerization as the main mechanism responsible for the ligand cross-linking. In the cascade of reactions occurring during the surface-ligands polymerization, the nanocrystal core material plays a catalytic role, being strongly affected by the anchoring group of the surface ligands. Ultimately, we demonstrate how the found mechanistic insights can be used to adjust the mechanical and nanostructural properties of the obtained nanocomposites. These results enable engineering supercrystalline nanocomposites with improved cohesion while preserving their characteristic nanostructure, which is required to achieve the collective properties for broad functional applications.

Published
2022

22. An analytical review on Spark Plasma Sintering of metals and alloys: from processing window, phase transformation, and property perspective.

Author

Abedi, Mohammad, Sovizi, Saeed, Azarniya, Abolfazl, Giuntini, Diletta, Seraji, Melica Esmaeeli, Hosseini, Hamid Reza Madaah, Amutha, Chinappan, Ramakrishna, Seeram, and Mukasyan, Alexander

Subjects
PHASE transitions, SINTERING, SPECIFIC gravity, BENDING strength, ELASTIC modulus, POWDERS
Abstract

The need for fully dense material with well-engineered microstructures has led to the promising emergence of innovative sintering technologies among which the Spark Plasma Sintering (SPS) is one of the most favorite. Unlike the conventional sintering processes, SPS takes advantage of a current flow passing through the sintering die and metallic powders by which fast densification with minimal grain growth and enhanced physicomechanical properties can be obtained. Albeit there is a growing interest in the exploitation of SPS in producing sufficiently consolidated metallic parts, no analytical review has been released over the effects of SPS parameters on the densification behavior, microstructure evolution, and resultant physicomechanical properties of metallic parts and their alloys. In the present review, recent developments and ongoing challenges in modeling the SPS of metallic systems are thoroughly explored. Then, the effects of main SPS parameters including sintering temperature, dwell time, heating rate, and pressure on the microstructure and physicomechanical properties of metals and alloys are comprehensively investigated. These properties are categorized into two groups: (i) physical properties including relative density, electrical and thermal conductivities; (ii) mechanical properties with a systematic focus on hardness, elastic modulus, and tensile, compressive, and bending strengths. In each section, the general trends along which SPS parameters grow to affect each corresponding property are comprehensively discussed. Additionally, various microstructural phenomena being more likely to occur at the given metallic systems are fully addressed. The present work seeks to elaborate on the aforementioned issues and provide an overview of the unresolved challenges and proposed solutions to them. [ABSTRACT FROM AUTHOR]

Published
2023
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24. Optimization of Spark-Plasma Sintering Efficiency: Tailoring Material Structure and Advanced Tooling Design

Author

Giuntini, Diletta

Subjects
Materials Science, Mechanical engineering, Agglomeration, Finite Element Methods, Modeling, Spark Plasma Sintering, Tooling
Abstract

The efficiency of Spark Plasma Sintering (SPS) is optimized by means of a temperature-based procedure. The correlations between temperature, porous material structure and tooling geometry are explored. The issue of agglomeration, cause of the formation of hierarchical porous structures in the powder compact, is addressed with an analytical and numerical approach. Densification kinetics, sintering stress, bulk and shear moduli of agglomerated compacts are modeled as functions of the hierarchy characterizing the porosity and the nonlinear viscous rheology of the material. The material nonlinearity is expressed by the strain rate sensitivity parameter, which in turn is dependent on temperature. An empirically-based explicit formulation of strain rate sensitivity as a function of temperature is provided. A subsequent tuning of the strain rate sensitivity allows the optimization of the thermal regime in order to obtain in situ deagglomeration of the SPS specimen or the production of tailored material structures. In order to guarantee that the optimized thermal conditions are experienced by the entire specimen, we study the geometry of the SPS tooling setup. The tooling influence on temperature distributions is assessed in both the radial and the axial directions by means of a combined experimental and finite-element study. The phenomena underlying the presence of thermal gradients are individuated and controlled by tailoring the design of the tooling setup. Novel geometries are proposed for the components of the tooling, capable to annihilate the temperature disparities and thus complete the optimization of the SPS procedure. A comprehensive finite-element framework, in which both agglomerated powder compacts and tooling setup can be reconstructed and improved, is therefore developed.

Published
2016

26. Constitutive and fracture behavior of ultra-strong supercrystalline nanocomposites

Author

Bor, B��sra, Giuntini, Diletta, Dom��nech Garcia, Berta, Plunkett, Alexander, Kampferbeck, Michael, Vossmeyer, Tobias, Weller, Horst, Scheider, Ingo, Schneider, Gerold A., Publica, Mechanics of Materials, ICMS Affiliated, and EIRES Eng. for Sustainable Energy Systems

Subjects
530: Physik, ddc:530, Physik [530]
Abstract

Applied physics reviews 8(3), 031414 (2021). doi:10.1063/5.0056616, Supercrystalline nanocomposites are a new class of hybrid and nanostructured materials that can reach exceptional mechanical strength and can be fabricated at low temperatures. Hierarchically arranged, they bridge the gap from the nano- to the macro-scale. Even though their mechanical properties are starting to be characterized, their constitutive behavior is still largely unexplored. Here, the mechanical behavior of supercrystalline nanocomposites of iron oxide nanoparticles, surface-functionalized with oleic acid and oleyl phosphate ligands, is investigated in both bending and compression, with loading���unloading tests. A new bar geometry is implemented to better detect deformation prior to unstable crack propagation, and notched bending bars are tested to evaluate fracture toughness. Micro-mechanical tests result in the values of strength and elastic modulus that are extremely high for supercrystals, reaching record-high numbers in the oleic acid-based nanocomposites, which also show a significant tension���compression asymmetry. The constitutive behavior of both materials is predominantly linear elastic, with some more marked nonlinearities arising in the oleyl phosphate-based nanocomposites. The fracture toughness of both types of nanocomposites, ���0.3 MPa���m, suggests that extrinsic toughening, associated with both material composition and nanostructure, plays an important role. Fractographic observations reveal analogies with shear and cleavage in atomic crystals. The influence of material composition, nanostructure, and processing method on the mechanical behavior of the nanocomposites is analyzed., Published by AIP, New York, NY

Published
2021

27. Hierarchical supercrystalline nanocomposites through the self-assembly of organically-modified ceramic nanoparticles

Author

Dom��nech Garcia, Berta, Kampferbeck, Michael, Larsson, Emanuel, Krekeler, Tobias, Bor, B��sra, Giuntini, Diletta, Blankenburg, Malte, Ritter, Martin, M��ller, Martin, Vossmeyer, Tobias, Weller, Horst, Schneider, Gerold A., and Publica

Subjects
600: Technik, lcsh:R, lcsh:Medicine, Ingenieurwissenschaften [620], Article, 620: Ingenieurwissenschaften, lcsh:Q, ddc:620, lcsh:Science, ddc:600, Technik [600]
Abstract

Scientific reports 9(1), 3435 (2019). doi:10.1038/s41598-019-39934-4, Biomaterials often display outstanding combinations of mechanical properties thanks to theirhierarchical structuring, which occurs through a dynamically and biologically controlled growth andself-assembly of their main constituents, typically mineral and protein. However, it is still challenging toobtain this ordered multiscale structural organization in synthetic 3D-nanocomposite materials. Herein,we report a new bottom-up approach for the synthesis of macroscale hierarchical nanocompositematerials in a single step. By controlling the content of organic phase during the self-assembly ofmonodisperse organically-modified nanoparticles (iron oxide with oleyl phosphate), either purelysupercrystalline or hierarchically structured supercrystalline nanocomposite materials are obtained.Beyond a critical concentration of organic phase, a hierarchical material is consistently formed. In sucha hierarchical material, individual organically-modified ceramic nanoparticles (Level 0) self-assembleinto supercrystals in face-centered cubic superlattices (Level 1), which in turn form granules of up tohundreds of micrometers (Level 2). These micrometric granules are the constituents of the final mmsizedmaterial. This approach demonstrates that the local concentration of organic phase and nanobuildingblocks during self-assembly controls the final material’s microstructure, and thus enables thefine-tuning of inorganic-organic nanocomposites’ mechanical behavior, paving the way towards thedesign of novel high-performance structural materials., Published by Springer Nature, London

Published
2019

28. Deformation behavior of cross-linked supercrystalline nanocomposites: an in situ SAXS/WAXS study during uniaxial compression

Author

Giuntini, Diletta, Davydok, Anton, Blankenburg, Malte, Domènech, Berta, Bor, Büsra, Li, Mingjing, Scheider, Ingo, Krywka, Christina, Müller, Martin, and Schneider, Gerold A.

Subjects
Mechanical Behavior, Letter, Supercrystals, ddc:660, Cross-Linking, ddc:600, X-ray Scattering, Technik [600], Nanocrystal Superlattice, Nanocomposites
Abstract

Nano letters 21(7), 2891 - 2897 (2021). doi:10.1021/acs.nanolett.0c05041, With the ever-expanding functional applications of supercrystalline nanocomposites (a relatively new category of materials consisting of organically functionalized nanoparticles arranged into periodic structures), it becomes necessary to ensure their structural stability and understand their deformation and failure mechanisms. Inducing the cross-linking of the functionalizing organic ligands, for instance, leads to a remarkable enhancement of the nanocomposites’ mechanical properties. It is however still unknown how the cross-linked organic phase redistributes applied loads, how the supercrystalline lattice accommodates the imposed deformations, and thus in general what phenomena govern the overall material’s mechanical response. This work elucidates these aspects for cross-linked supercrystalline nanocomposites through an in situ small- and wide-angle X-ray scattering study combined with uniaxial pressing. Because of this loading condition, it emerges that the cross-linked ligands effectively carry and distribute loads homogeneously throughout the nanocomposites, while the superlattice deforms via rotation, slip, and local defects generation., Published by ACS Publ., Washington, DC

Published
2021

29. Constitutive and fracture behavior of ultra-strong supercrystalline nanocomposites

Author

Bor, Büsra, Giuntini, Diletta, Domènech, Berta, Plunkett, Alexander, Kampferbeck, Michael, Vossmeyer, Tobias, Weller, Horst, Scheider, Ingo, Schneider, Gerold A., Bor, Büsra, Giuntini, Diletta, Domènech, Berta, Plunkett, Alexander, Kampferbeck, Michael, Vossmeyer, Tobias, Weller, Horst, Scheider, Ingo, and Schneider, Gerold A.

Abstract

Supercrystalline nanocomposites are a new class of hybrid and nanostructured materials that can reach exceptional mechanical strength and can be fabricated at low temperatures. Hierarchically arranged, they bridge the gap from the nano- to the macro-scale. Even though their mechanical properties are starting to be characterized, their constitutive behavior is still largely unexplored. Here, the mechanical behavior of supercrystalline nanocomposites of iron oxide nanoparticles, surface-functionalized with oleic acid and oleyl phosphate ligands, is investigated in both bending and compression, with loading-unloading tests. A new bar geometry is implemented to better detect deformation prior to unstable crack propagation, and notched bending bars are tested to evaluate fracture toughness. Micro-mechanical tests result in the values of strength and elastic modulus that are extremely high for supercrystals, reaching record-high numbers in the oleic acid-based nanocomposites, which also show a significant tension-compression asymmetry. The constitutive behavior of both materials is predominantly linear elastic, with some more marked nonlinearities arising in the oleyl phosphate-based nanocomposites. The fracture toughness of both types of nanocomposites, ∼0.3 MPa√m, suggests that extrinsic toughening, associated with both material composition and nanostructure, plays an important role. Fractographic observations reveal analogies with shear and cleavage in atomic crystals. The influence of material composition, nanostructure, and processing method on the mechanical behavior of the nanocomposites is analyzed.

Published
2021

30. Defects and plasticity in ultrastrong supercrystalline nanocomposites

Author

Giuntini, Diletta, Zhao, Shiteng, Krekeler, Tobias, Li, Mingjing, Blankenburg, Malte, Bor, Büsra, Schaan, Gunnar, Domènech Garcia, Berta, Müller, Martin, Scheider, Ingo, Ritter, Martin, Schneider, Gerold A., Giuntini, Diletta, Zhao, Shiteng, Krekeler, Tobias, Li, Mingjing, Blankenburg, Malte, Bor, Büsra, Schaan, Gunnar, Domènech Garcia, Berta, Müller, Martin, Scheider, Ingo, Ritter, Martin, and Schneider, Gerold A.

Abstract

Supercrystalline nanocomposites are nanoarchitected materials with a growing range of applications but unexplored in their structural behavior. They typically consist of organically functionalized inorganic nanoparticles arranged into periodic structures analogous to crystalline lattices, including superlattice imperfections induced by processing or mechanical loading. Although featuring a variety of promising functional properties, their lack of mechanical robustness and unknown deformation mechanisms hamper their implementation into devices. We show that supercrystalline materials react to indentation with the same deformation patterns encountered in single crystals. Supercrystals accommodate plastic deformation in the form of pile-ups, dislocations, and slip bands. These phenomena occur, at least partially, also after cross-linking of the organic ligands, which leads to a multifold strengthening of the nanocomposites. The classic shear theories of crystalline materials are found to describe well the behavior of supercrystalline nanocomposites, which result to feature an elastoplastic behavior, accompanied by compaction.

Published
2021

31. Mapping the Mechanical Properties of Hierarchical Supercrystalline Ceramic-Organic Nanocomposites

Author

Bor, Büsra, Heilmann, Lydia, Domènech, Berta, Kampferbeck, Michael, Vossmeyer, Tobias, Weller, Horst, Schneider, Gerold A., and Giuntini, Diletta

Subjects
hierarchical material, Ceramics, nanocomposite, nanoindentation, Chemie [540], Temperature, Ingenieurwissenschaften [620], supercrystalline material, Article, fracture toughness, Nanocomposites, lcsh:QD241-441, lcsh:Organic chemistry, Hardness, Elastic Modulus, ddc:540, Materials Testing, mechanical behavior, Zirconium, ddc:620, ddc:600, Technik [600], Mechanical Phenomena
Abstract

Multiscale ceramic-organic supercrystalline nanocomposites with two levels of hierarchy have been developed via self-assembly with tailored content of the organic phase. These nanocomposites consist of organically functionalized ceramic nanoparticles forming supercrystalline micron-sized grains, which are in turn embedded in an organic-rich matrix. By applying an additional heat treatment step at mild temperatures (250&ndash, 350 &deg, C), the mechanical properties of the hierarchical nanocomposites are here enhanced. The heat treatment leads to partial removal and crosslinking of the organic phase, minimizing the volume occupied by the nanocomposites&rsquo, soft phase and triggering the formation of covalent bonds through the organic ligands interfacing the ceramic nanoparticles. Elastic modulus and hardness up to 45 and 2.5 GPa are attained, while the hierarchical microstructure is preserved. The presence of an organic phase between the supercrystalline grains provides a toughening effect, by curbing indentation-induced cracks. A mapping of the nanocomposites&rsquo, mechanical properties reveals the presence of multiple microstructural features and how they evolve with heat treatment temperature. A comparison with non-hierarchical, homogeneous supercrystalline nanocomposites with lower organic content confirms how the hierarchy-inducing organic excess results in toughening, while maintaining the beneficial effects of crosslinking on the materials&rsquo, stiffness and hardness.

Published
2020

32. Modulating the Mechanical Properties of Supercrystalline Nanocomposite Materials via Solvent-Ligand Interactions

Author

Domènech, Berta, Plunkett, Alexander, Kampferbeck, Michael, Blankenburg, Malte, Bor, Büsra, Giuntini, Diletta, Krekeler, Tobias, Wagstaffe, Michael, Noei, Heshmat, Stierle, Andreas, Ritter, Martin, Müller, Martin, Vossmeyer, Tobias, Weller, Horst, Schneider, Gerold A., and Publica

Abstract

Supercrystalline nanocomposite materials with micromechanical properties approaching those of nacre or similar structural biomaterials can be produced by self-assembly of organically modified nanoparticles and further strengthened by cross-linking. The strengthening of these nanocomposites is controlled via thermal treatment, which promotes the formation of covalent bonds between interdigitated ligands on the nanoparticle surface. In this work, it is shown how the extent of the mechanical properties enhancement can be controlled by the solvent used during the self-assembly step. We find that the resulting mechanical properties correlate with the Hansen solubility parameters of the solvents and ligands used for the supercrystal assembly: the hardness and elastic modulus decrease as the Hansen solubility parameter of the solvent approaches the Hansen solubility parameter of the ligands that stabilize the nanoparticles. Moreover, it is shown that self-assembled supercrystals that are subsequently uniaxially pressed can deform up to 6 %. The extent of this deformation is also closely related to the solvent used during the self-assembly step. These results indicate that the conformation and arrangement of the organic ligands on the nanoparticle surface not only control the self-assembly itself but also influence the mechanical properties of the resulting supercrystalline material. The Hansen solubility parameters may therefore serve as a tool to predict what solvents and ligands should be used to obtain supercrystalline materials with good mechanical properties.

Published
2019

33. Iron oxide-based nanostructured ceramics with tailored magnetic and mechanical properties: Development of mechanically robust, bulk superparamagnetic materials

Author

Giuntini, Diletta, Torresani, Elisa, Chan, Kyle T., Blankenburg, Malte, Saviot, Lucien, Bor, Büsra, Domènech Garcia, Berta, Shachar, Meir, Müller, Martin, Olevsky, Eugene A., Garay, Javier E., Schneider, Gerold A., Giuntini, Diletta, Torresani, Elisa, Chan, Kyle T., Blankenburg, Malte, Saviot, Lucien, Bor, Büsra, Domènech Garcia, Berta, Shachar, Meir, Müller, Martin, Olevsky, Eugene A., Garay, Javier E., and Schneider, Gerold A.

Abstract

Nanostructured iron-oxide based materials with tailored mechanical and magnetic behavior are produced in bulk form. By applying ultra-fast heating routines via spark plasma sintering (SPS) to supercrystalline pellets, materials with an enhanced combination of elastic modulus, hardness and saturation magnetization are achieved. Supercrystallinity-namely the arrangement of the constituent nanoparticles into periodic structures-is achieved through self-assembly of the organically-functionalized iron oxide nanoparticles. The optimization of the following SPS regime allows the control of organics' removal, necking, iron oxide phase transformations and nano-grain size retention, and thus the fine-tuning of both mechanical properties and magnetic response, up until the production of bulk mm-size superparamagnetic materials.

Published
2019

34. Hierarchical supercrystalline nanocomposites through the self-assembly of organically-modified ceramic nanoparticles

Author

Domènech Garcia, Berta, Kampferbeck, Michael, Larsson, Emanuel, Krekeler, Tobias, Bor, Büsra, Giuntini, Diletta, Blankenburg, Malte, Ritter, Martin, Müller, Martin, Vossmeyer, Tobias, Weller, Horst, Schneider, Gerold A., Domènech Garcia, Berta, Kampferbeck, Michael, Larsson, Emanuel, Krekeler, Tobias, Bor, Büsra, Giuntini, Diletta, Blankenburg, Malte, Ritter, Martin, Müller, Martin, Vossmeyer, Tobias, Weller, Horst, and Schneider, Gerold A.

Abstract

Biomaterials often display outstanding combinations of mechanical properties thanks to their hierarchical structuring, which occurs through a dynamically and biologically controlled growth and self-assembly of their main constituents, typically mineral and protein. However, it is still challenging to obtain this ordered multiscale structural organization in synthetic 3D-nanocomposite materials. Herein, we report a new bottom-up approach for the synthesis of macroscale hierarchical nanocomposite materials in a single step. By controlling the content of organic phase during the self-assembly of monodisperse organically-modified nanoparticles (iron oxide with oleyl phosphate), either purely supercrystalline or hierarchically structured supercrystalline nanocomposite materials are obtained. Beyond a critical concentration of organic phase, a hierarchical material is consistently formed. In such a hierarchical material, individual organically-modified ceramic nanoparticles (Level 0) self-assemble into supercrystals in face-centered cubic superlattices (Level 1), which in turn form granules of up to hundreds of micrometers (Level 2). These micrometric granules are the constituents of the final mm-sized material. This approach demonstrates that the local concentration of organic phase and nano-building blocks during self-assembly controls the final material's microstructure, and thus enables the fine-tuning of inorganic-organic nanocomposites' mechanical behavior, paving the way towards the design of novel high-performance structural materials.

Published
2019

36. Modulating the Mechanical Properties of Supercrystalline Nanocomposite Materials via Solvent–Ligand Interactions

Author

Domènech, Berta, primary, Plunkett, Alexander, additional, Kampferbeck, Michael, additional, Blankenburg, Malte, additional, Bor, Büsra, additional, Giuntini, Diletta, additional, Krekeler, Tobias, additional, Wagstaffe, Michael, additional, Noei, Heshmat, additional, Stierle, Andreas, additional, Ritter, Martin, additional, Müller, Martin, additional, Vossmeyer, Tobias, additional, Weller, Horst, additional, and Schneider, Gerold A., additional

Published
2019
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37. Iron oxide-based nanostructured ceramics with tailored magnetic and mechanical properties: development of mechanically robust, bulk superparamagnetic materials

Author

Giuntini, Diletta, primary, Torresani, Elisa, additional, Chan, Kyle T., additional, Blankenburg, Malte, additional, Saviot, Lucien, additional, Bor, Büsra, additional, Domènech, Berta, additional, Shachar, Meir, additional, Müller, Martin, additional, Olevsky, Eugene A., additional, Garay, Javier E., additional, and Schneider, Gerold A., additional

Published
2019
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39. Feasibility of in situ de‐agglomeration during powder consolidation.

Author

Giuntini, Diletta, Bordia, Rajendra K., and Olevsky, Eugene A.

Subjects
*METAL powders, *AGGLOMERATION (Materials), *POTENTIAL theory (Physics), *POROUS materials, *FEASIBILITY studies
Abstract

Consolidation of nano‐sized powders is a growing area in manufacturing of advanced materials, thanks to the reduced processing times, enhanced mechanical properties and high potential for the introduction of multi‐functionality enabled by such reduced particle sizes. Nanopowders, however, are particularly prone to the agglomeration phenomena, and thus to the formation of hierarchical porous structures. The presence of pores differing up to several orders of magnitude in size leads to undesired differential shrinkage and localized grain growth. In order to avoid such issues, strategies for in situ de‐agglomeration are proposed here. These optimization strategies are based on the development of an analytical model for shrinkage kinetics and mechanical properties of a hierarchical porous structure, containing both small‐size intra‐agglomerate pores and large‐size inter‐agglomerate ones. The modeling approach is an expansion of the continuum theory of sintering to the case of biporous materials presenting nonlinear viscous rheology, as expected for nano‐sized crystalline powders. Considering the nonlinear viscous constitutive behavior of the solid phase also allows assessing the influence of the temperature on the microstructural evolution during processing, due to the dependence of the creep characteristic parameter, strain‐rate sensitivity, on the thermal history. Material structure optimization strategies, aimed at de‐agglomeration or at the design of tailored porous structures, become then possible and are here explored. [ABSTRACT FROM AUTHOR]

Published
2019
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45. Deformation Behavior of Cross-Linked Supercrystalline Nanocomposites: An in Situ SAXS/WAXS Study during Uniaxial Compression.

Author

Giuntini D, Davydok A, Blankenburg M, Domènech B, Bor B, Li M, Scheider I, Krywka C, Müller M, and Schneider GA

Abstract

With the ever-expanding functional applications of supercrystalline nanocomposites (a relatively new category of materials consisting of organically functionalized nanoparticles arranged into periodic structures), it becomes necessary to ensure their structural stability and understand their deformation and failure mechanisms. Inducing the cross-linking of the functionalizing organic ligands, for instance, leads to a remarkable enhancement of the nanocomposites' mechanical properties. It is however still unknown how the cross-linked organic phase redistributes applied loads, how the supercrystalline lattice accommodates the imposed deformations, and thus in general what phenomena govern the overall material's mechanical response. This work elucidates these aspects for cross-linked supercrystalline nanocomposites through an in situ small- and wide-angle X-ray scattering study combined with uniaxial pressing. Because of this loading condition, it emerges that the cross-linked ligands effectively carry and distribute loads homogeneously throughout the nanocomposites, while the superlattice deforms via rotation, slip, and local defects generation.

Published
2021
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