Your search keyword '"Holtz, Megan E."' showing total 10 results

1. High-Throughput Selection and Experimental Realization of Two New Ce-Based Nitride Perovskites: CeMoN3and CeWN3

Author

Sherbondy, Rachel, Smaha, Rebecca W., Bartel, Christopher J., Holtz, Megan E., Talley, Kevin R., Levy-Wendt, Ben, Perkins, Craig L., Eley, Serena, Zakutayev, Andriy, and Brennecka, Geoff L.

Abstract

Nitride perovskites have only been experimentally realized in very few cases despite the widespread existence and commercial importance of perovskite materials. From oxide perovskites used in ultrasonics to halide perovskites that have revolutionized the photovoltaics industry, the discovery of new perovskite materials has historically impacted a wide number of fields. Here, we add two new perovskites, CeWN3and CeMoN3, to the list of experimentally realized perovskite nitrides using high-throughput computational screening and subsequent high-throughput thin film growth techniques. Candidate compositions are first down-selected using a tolerance factor and then thermochemical stability. A novel competing fluorite-family phase is identified for both material systems, which we hypothesize is a transient intermediate phase that crystallizes during the evolution from an amorphous material to a stable perovskite. Different processing routes to overcome the competing fluorite phase and obtain phase-pure nitride perovskites are demonstrated for the CeMoN3–xand CeWN3–xmaterial systems, which provide a starting point for the development of future nitride perovskites. Additionally, we find that these new perovskite phases have interesting low-temperature magnetic behavior: CeMoN3–xorders antiferromagnetically below TN≈ 8 K with indications of strong magnetic frustration, while CeWN3–xexhibits no long-range order down to T= 2 K but has strong antiferromagnetic correlations. This work demonstrates the importance and effectiveness of using high-throughput techniques, both computational and experimental: they are integral to optimize the process of realizing two entirely novel nitride perovskites.

Published

2022

2. Targeted chemical pressure yields tuneable millimetre-wave dielectric

Author

Dawley, Natalie M., Marksz, Eric J., Hagerstrom, Aaron M., Olsen, Gerhard H., Holtz, Megan E., Goian, Veronica, Kadlec, Christelle, Zhang, Jingshu, Lu, Xifeng, Drisko, Jasper A., Uecker, Reinhard, Ganschow, Steffen, Long, Christian J., Booth, James C., Kamba, Stanislav, Fennie, Craig J., Muller, David A., Orloff, Nathan D., and Schlom, Darrell G.

Abstract

Epitaxial strain can unlock enhanced properties in oxide materials, but restricts substrate choice and maximum film thickness, above which lattice relaxation and property degradation occur. Here we employ a chemical alternative to epitaxial strain by providing targeted chemical pressure, distinct from random doping, to induce a ferroelectric instability with the strategic introduction of barium into today’s best millimetre-wave tuneable dielectric, the epitaxially strained 50-nm-thick n= 6 (SrTiO3)nSrO Ruddlesden–Popper dielectric grown on (110) DyScO3. The defect mitigating nature of (SrTiO3)nSrO results in unprecedented low loss at frequencies up to 125 GHz. No barium-containing Ruddlesden–Popper titanates are known, but the resulting atomically engineered superlattice material, (SrTiO3)n−m(BaTiO3)mSrO, enables low-loss, tuneable dielectric properties to be achieved with lower epitaxial strain and a 200% improvement in the figure of merit at commercially relevant millimetre-wave frequencies. As tuneable dielectrics are key constituents of emerging millimetre-wave high-frequency devices in telecommunications, our findings could lead to higher performance adaptive and reconfigurable electronics at these frequencies.

Published

2020

3. Emergent Ferromagnetism in CaRuO3/CaMnO3(111)-Oriented Superlattices

Author

Kane, Margaret, Bhandari, Churna, Holtz, Megan E., Balakrishnan, Purnima P., Grutter, Alexander J., Fitzsimmons, Michael, Yang, Chao-Yao, Satpathy, Sashi, Paudyal, Durga, and Suzuki, Yuri

Abstract

The boundary between CaRuO3and CaMnO3is an ideal test bed for emergent magnetic ground states stabilized through interfacial electron interactions. In this system, nominally antiferromagnetic and paramagnetic materials combine to yield interfacial ferromagnetism in CaMnO3due to electron leakage across the interface. In this work, we show that the crystal symmetry at the surface is a critical factor determining the nature of the interfacial interactions. Specifically, by growing CaRuO3/CaMnO3heterostructures along the (111) instead of the (001) crystallographic axis, we achieve a 3-fold enhancement of the magnetization and involve the CaRuO3layers in the ferromagnetism, which now spans both constituent materials. The stabilization of a net magnetic moment in CaRuO3through strain effects has been long-sought but never consistently achieved, and our observations demonstrate the importance of interface engineering in the development of new functional heterostructures.

Published

2024

4. Ferroelectric Domain Walls in PbTiO3Are Effective Regulators of Heat Flow at Room Temperature

Author

Langenberg, Eric, Saha, Dipanjan, Holtz, Megan E., Wang, Jian-Jun, Bugallo, David, Ferreiro-Vila, Elias, Paik, Hanjong, Hanke, Isabelle, Ganschow, Steffen, Muller, David A., Chen, Long-Qing, Catalan, Gustau, Domingo, Neus, Malen, Jonathan, Schlom, Darrell G., and Rivadulla, Francisco

Abstract

Achieving efficient spatial modulation of phonon transmission is an essential step on the path to phononic circuits using “phonon currents”. With their intrinsic and reconfigurable interfaces, domain walls (DWs), ferroelectrics are alluring candidates to be harnessed as dynamic heat modulators. This paper reports the thermal conductivity of single-crystal PbTiO3thin films over a wide variety of epitaxial-strain-engineered ferroelectric domain configurations. The phonon transport is proved to be strongly affected by the density and type of DWs, achieving a 61% reduction of the room-temperature thermal conductivity compared to the single-domain scenario. The thermal resistance across the ferroelectric DWs is obtained, revealing a very high value (≈5.0 × 10–9K m2W–1), comparable to grain boundaries in oxides, explaining the strong modulation of the thermal conductivity in PbTiO3. This low thermal conductance of the DWs is ascribed to the structural mismatch and polarization gradient found between the different types of domains in the PbTiO3films, resulting in a structural inhomogeneity that extends several unit cells around the DWs. These findings demonstrate the potential of ferroelectric DWs as efficient regulators of heat flow in one single material, overcoming the complexity of multilayers systems and the uncontrolled distribution of grain boundaries, paving the way for applications in phononics.

Published

2019

5. Mitigation of PEM Fuel Cell Catalyst Degradation with Porous Carbon Supports

Author

Padgett, Elliot, Yarlagadda, Venkata, Holtz, Megan E., Ko, Matthew, A, Barnaby D., Singh, Ratandeep, Ziegelbauer, Joseph M., Andrews, Ross N., Ilavsky, Jan, Kongkanand, Anusorn, and Muller, David A.

Abstract

Maintaining high performance after extensive use remains a key challenge for low-Pt proton exchange membrane fuel cells for transportation applications. Strategically improving catalyst durability requires better understanding of the relationship between degradation mechanisms and catalyst structure. To investigate the effects of the carbon support morphology, we compare the electrochemical performance and durability of membrane electrode assemblies (MEAs) using Pt and PtCox catalysts with a range of porous, solid, and intermediate carbon supports (HSC, Vulcan, and acetylene black). We find that electrochemical surface area (ECSA) retention after a catalyst-targeted durability test tends to improve with increasing support porosity. Using electron microscopy, we investigate microstructural changes in the catalysts and reveal the underlying degradation mechanisms in MEA specimens. Pt migration to the membrane and catalyst coarsening, measured microscopically, together were quantitatively consistent with the ECSA loss, indicating that these were the only two significant degradation pathways. Changes in catalyst particle size, morphology, and PtCo core-shell structure indicate that Ostwald ripening is a significant coarsening mechanism for catalysts on all carbons, while particle coalescence is only significant on the more solid carbon supports. Porous carbon supports thus appear to protect against particle coalescence, providing an effective strategy for mitigating catalyst coarsening.

Published

2019

6. Strain Relaxation and Activity in PtCo Fuel Cell Catalyst Nanoparticles.

Author

Padgett, Elliot, Holtz, Megan E, Kongkanand, Anusorn, and Muller, David A

Published

2023

7. Atomically engineered ferroic layers yield a room-temperature magnetoelectric multiferroic

Author

Mundy, Julia A., Brooks, Charles M., Holtz, Megan E., Moyer, Jarrett A., Das, Hena, Rébola, Alejandro F., Heron, John T., Clarkson, James D., Disseler, Steven M., Liu, Zhiqi, Farhan, Alan, Held, Rainer, Hovden, Robert, Padgett, Elliot, Mao, Qingyun, Paik, Hanjong, Misra, Rajiv, Kourkoutis, Lena F., Arenholz, Elke, Scholl, Andreas, Borchers, Julie A., Ratcliff, William D., Ramesh, Ramamoorthy, Fennie, Craig J., Schiffer, Peter, Muller, David A., and Schlom, Darrell G.

Abstract

A single-phase multiferroic material is constructed, in which ferroelectricity and strong magnetic ordering are coupled near room temperature, enabling direct electric-field control of magnetism.

Published

2016

8. Topological Surface State Annihilation and Creation in SnTe/Crx(BiSb)2–xTe3Heterostructures

Author

Deng, Peng, Grutter, Alexander, Han, Yulei, Holtz, Megan E., Zhang, Peng, Quarterman, Patrick, Pan, Shuaihang, Qi, Shifei, Qiao, Zhenhua, and Wang, Kang L.

Abstract

Topological surface states are a new class of electronic states with novel properties, including the potential for annihilation between surface states from two topological insulators at a common interface. Here, we report the annihilation and creation of topological surface states in the SnTe/Crx(BiSb)2–xTe3(CBST) heterostructures as evidenced by magneto-transport, polarized neutron reflectometry, and first-principles calculations. Our results show that topological surface states are induced in the otherwise topologically trivial two-quintuple-layers thick CBST when interfaced with SnTe, as a result of the surface state annihilation at the SnTe/CBST interface. Moreover, we unveiled systematic changes in the transport behaviors of the heterostructures with respect to changing Fermi level and thickness. Our observation of surface state creation and annihilation demonstrates a promising way of designing and engineering topological surface states for dissipationless electronics.

Published

2022

9. Correction to Topological Surface State Annihilation and Creation in SnTe/Crx(BiSb)2–xTe3Heterostructures

Author

Deng, Peng, Grutter, Alexander, Han, Yulei, Holtz, Megan E., Zhang, Peng, Quarterman, Patrick, Pan, Shuaihang, Qi, Shifei, Qiao, Zhenhua, and Wang, Kang L.

Published

2022

10. Stromataxic Stabilization of a Metastable Layered ScFeO3Polymorph

Author

Garten, Lauren M., Jiang, Zhen, Paik, Hanjong, Perkins, John D., Kakekhani, Arvin, Fei, Ruixiang, Werder, Don J., Holtz, Megan E., Ginley, David S., Rappe, Andrew M., Schlom, Darrell G., and Staruch, Margo L.

Abstract

Metastable polymorphs—materials with the same stoichiometry as the ground state but a different crystal structure— enable many critical technologies. This work describes the development of a stabilization approach for metastable polymorphs that are difficult to achieve through other stabilization techniques (such as epitaxy or quenching) called stromataxy. Stromataxy is a method based on controlling the precursor structure during the initial stages of material growth to dictate phase formation. To illustrate this approach, we controlled the atomic layering of the precursors of ScFeO3and stabilized the metastable P63cmphase, under conditions that previously led to the ground-state Ia3̅ bixbyite phase. Ab initio mechanistic calculations highlight the importance of the variable oxidation state of Fe and the layer stability during layer-by-layer growth. The broad applicability of a stromataxy approach was demonstrated by stabilizing this metastable phase on substrates that have previously been shown to stabilize other polymorphs under continuous growth. Stromataxy is shown as a viable option for accessing polymorphs that are close in energy, difficult to differentiate by strain, or that lack a well epitaxially matched substrate.

Published

2021