Your search keyword '"Woods, P. M."' showing total 1,030 results

1. Phonon-assisted Casimir interactions between piezoelectric materials

Author

Le, Dai-Nam, Rodriguez-Lopez, Pablo, and Woods, Lilia M.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science, Quantum Physics

Abstract

The strong coupling between electromagnetic field and lattice oscillation in piezoelectric materials gives rise to phonon polariton excitations. Such quasiparticles open up new directions in modulating the ubiquitous Casimir force. Here by utilizing the generalized Born-Huang hydrodynamics model, three types of phonons in piezoelectrics are studied: longitudinal optical phonon, transverse optical phonon and phonon polariton. The phonon-electromagnetic coupling results in a complex set of Fresnel reflection matrices which prevents the utilization of the standard Lifshitz approach for calculating Casimir forces in the imaginary frequency domain. Our calculations are based on an approach within real frequency and finite temperatures, through which various regimes of the Casimir interaction are examined. Our study shows that piezoelectrics emerge as a set of materials where this ubiquitous force can be controlled via phonon properties for the first time. The Casimir interaction appears as a suitable means to distinguish between different types of surface phonon polaritons associated with different structural piezoelectric polytypes., Comment: 8 pages, 4 figures, supplementary information with 10 pages, 4 figures; submitted

Published

2024

2. Dissecting van der Waals interactions with Density Functional Theory -- Wannier-basis approach

Author

Dang, Diem Thi-Xuan, Le, Dai-Nam, and Woods, Lilia M.

Subjects

Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Chemical Physics, Physics - Computational Physics, Quantum Physics

Abstract

A new scheme for the computation of dispersive interactions from first principles is presented. This cost-effective approach relies on a Wannier function representation compatible with density function theory descriptions. This is an electronic-based many-body method that captures the full electronic and optical response properties of the materials. It provides the foundation to discern van der Waals and induction energies as well as the role of anisotropy and different stacking patterns when computing dispersive interactions in systems. Calculated results for binding energies in layered materials, such as graphite, hBN, and MoS$_2$ give encouraging comparisons with available experimental data. Strategies for broadened computational descriptions of dispersive interactions are also discussed. Our investigation aims at stimulating new experimental studies to measure van der Waals energies in a wider range of materials, especially in layered systems., Comment: 24 pages, 1 abstract figure, 4 figures, source codes: 10.6084/m9.figshare.26023024.v2 or https://github.com/Diem-TX-Dang/vdW-MBDWan-code/tree/main, submitted

Published

2024

3. Astronomy's climate emissions: Global travel to scientific meetings in 2019

Author

Gokus, Andrea, Jahnke, Knud, Woods, Paul M, Moss, Vanessa A, Ossenkopf-Okada, Volker, Sacchi, Elena, Stevens, Adam R H, Burtscher, Leonard, Kayhan, Cenk, Dalgleish, Hannah, Grinberg, Victoria, Rector, Travis A, Rybizki, Jan, and White, Jacob

Subjects

Physics - Physics and Society, Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

Travel to academic conferences -- where international flights are the norm -- is responsible for a sizeable fraction of the greenhouse gas (GHG) emissions associated with academic work. In order to provide a benchmark for comparison with other fields, as well as for future reduction strategies and assessments, we estimate the CO2-equivalent emissions for conference travel in the field of astronomy for the prepandemic year 2019. The GHG emission of the international astronomical community's 362 conferences and schools in 2019 amounted to 42,500 tCO2e, assuming a radiative-forcing index factor of 1.95 for air travel. This equates to an average of 1.0 $\pm$ 0.6 tCO2e per participant per meeting. The total travel distance adds up to roughly 1.5 Astronomical Units, that is, 1.5 times the distance between the Earth and the Sun. We present scenarios for the reduction of this value, for instance with virtual conferencing or hub models, while still prioritizing the benefits conferences bring to the scientific community., Comment: Supplementary material is available at PNAS Nexus online: https://academic.oup.com/pnasnexus/article/3/5/pgae143/7659884

Published

2024

4. Elementary excitations of single-photon emitters in hexagonal Boron Nitride

Author

Pelliciari, Jonathan, Mejia, Enrique, Woods, John M., Gu, Yanhong, Li, Jiemin, Chand, Saroj B., Fan, Shiyu, Watanabe, Kenji, Taniguchi, Takashi, Bisogni, Valentina, and Grosso, Gabriele

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science

Abstract

Single-photon emitters serve as building blocks for many emerging concepts in quantum photonics. The recent identification of bright, tunable, and stable emitters in hexagonal boron nitride (hBN) has opened the door to quantum platforms operating across the infrared to ultraviolet spectrum. While it is widely acknowledged that defects are responsible for single-photon emitters in hBN, crucial details regarding their origin, electronic levels, and orbital involvement remain unknown. Here, we employ a combination of resonant inelastic X-ray scattering and photoluminescence spectroscopy in defective hBN unveiling an elementary excitation at 285 meV that gives rise to a plethora of harmonics correlated with single-photon emitters. We discuss the importance of N $\pi^*$ antibonding orbitals in shaping the electronic states of the emitters. The discovery of the elementary excitations of hBN provides new fundamental insights into quantum emission in low-dimensional materials, paving the way for future investigations in other platforms.

Published

2024

5. Vanadium-Doped Molybdenum Disulfide Monolayers with Tunable Electronic and Magnetic Properties: Do Vanadium-Vacancy Pairs Matter?

Author

Zhou, Da, Pham, Yen Thi Hai, Dang, Diem Thi-Xuan, Sanchez, David, Oberoi, Aaryan, Wang, Ke, Fest, Andres, Sredenschek, Alexander, Liu, Mingzu, Terrones, Humberto, Das, Saptarshi, Le, Dai-Nam, Woods, Lilia M., Phan, Manh-Huong, and Terrones, Mauricio

Subjects

Condensed Matter - Materials Science, Physics - Applied Physics

Abstract

Monolayers of molybdenum disulfide (MoS2) are the most studied two-dimensional (2D) transition-metal dichalcogenides (TMDs), due to its exceptional optical, electronic, and opto-electronic properties. Recent studies have shown the possibility of incorporating a small amount of magnetic transition metals (e.g., Fe, Co, Mn, V) into MoS2 to form a 2D dilute magnetic semiconductor (2D-DMS). However, the origin of the observed ferromagnetism has remained elusive, due to the presence of randomly generated sulfur vacancies during synthesis that can pair with magnetic dopants to form complex dopant-vacancy configurations altering the magnetic order induced by the dopants. By combining high-angle annular dark-field scanning transmission electron microscopy (HAADF-STEM) imaging with first-principles density functional theory (DFT) calculations and magnetometry data, we demonstrate the critical effects of sulfur vacancies and their pairings with vanadium atoms on the magnetic ordering in V-doped MoS2 (V-MoS2) monolayers. Additionally, we fabricated a series of field effect transistors on these V-MoS2 monolayers and observed the emergence of p-type behavior as the vanadium concentration increased. Our study sheds light on the origin of ferromagnetism in V-MoS2 monolayers and provides a foundation for future research on defect engineering to tune the electronic and magnetic properties of atomically thin TMD-based DMSs.

Published

2024

6. Implementing a First-Year Experience Course for IT Majors

Author

Woods, David M.

Abstract

Schools have implemented the high-impact practice of first-year experience (FYE) courses to assist students with the transition to college. These courses help connect new students to the school with the goal of improving retention. While students in computing majors face the same challenges as other new college students, they also face some challenges specific to computing fields. Additionally, computing fields face ongoing concerns about enrollment and diversity. This work discusses the implementation of an information technology (IT) specific FYE course combining content from a university-wide FYE course with content focused on helping students gain a better understanding of the IT curriculum and IT career paths.

Published

2023

7. Giant anisotropy and Casimir phenomena: the case of carbon nanotube metasurfaces

Author

Rodriguez-Lopez, Pablo, Le, Dai-Nam, Bondarev, Igor V., Antezza, Mauro, and Woods, Lilia M.

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science

Abstract

The Casimir interaction and torque are related phenomena originating from the exchange of electromagnetic excitations between objects. While the Casimir force exists between any types of objects, the materials or geometrical anisotropy drives the emergence of the Casimir torque. Here both phenomena are studied theoretically between dielectric films with immersed parallel single wall carbon nanotubes in the dilute limit with their chirality and collective electronic and optical response properties taken into account. It is found that the Casimir interaction is dominated by thermal fluctuations at sub-micron separations, while the torque is primarily determined by quantum mechanical effects. This peculiar quantum vs. thermal separation is attributed to the strong influence of reduced dimensionality and inherent anisotropy of the materials. Our study suggests that nanostructured anisotropic materials can serve as novel platforms to uncover new functionalities in ubiquitous Casimir phenomena., Comment: 9 pages, 4 figures, submitted to Phys. Rev. B

Published

2023

8. Confinement-Induced Nonlocality and Casimir Force in Transdimensional Systems

Author

Bondarev, Igor V., Pugh, Michael D., Rodriguez-Lopez, Pablo, Woods, Lilia M., and Antezza, Mauro

Subjects

Quantum Physics

Abstract

We study within the framework of the Lifshitz theory the long-range Casimir force for in-plane isotropic and anisotropic free-standing transdimensional material slabs. In the former case, we show that the confinement-induced nonlocality not only weakens the attraction of ultrathin slabs but also changes the distance dependence of the material-dependent correction to the Casimir force to go as $\sim\!1/\!\sqrt{l}$ contrary to the $\sim\!1/l$ dependence of that of the local Lifshitz force. In the latter case, we use closely packed array of parallel aligned single-wall carbon nanotubes in a dielectric layer of finite thickness to demonstrate strong orientational anisotropy and crossover behavior for the inter-slab attractive force in addition to its reduction with decreasing slab thickness. We give physical insight as to why such a pair of ultrathin slabs prefers to stick together in the perpendicularly oriented manner, rather than in the parallel relative orientation as one would customarily expect., Comment: 20 pages, 4 figures, 52 references

Published

2023

9. Nonlinear effects in many-body van der Waals interactions

Author

Le, Dai-Nam, Rodriguez-Lopez, Pablo, and Woods, Lilia M.

Subjects

Condensed Matter - Materials Science, Physics - Chemical Physics, Quantum Physics, 81V45, 81V55, 81V70, 81T55

Abstract

Van der Waals interactions are ubiquitous and they play an important role for the stability of materials. Current understanding of this type of coupling is based on linear response theory, while optical nonlinearities are rarely considered in this context. Many materials, however, exhibit strong optical nonlinear response, which prompts further evaluation of dispersive forces beyond linear response. Here we present a $\textit{Discrete Coupled Nonlinear Dipole}$ approach that takes into account linear and nonlinear properties of all dipolar nanoparticles in a given system. This method is based on a Hamiltonian for nonlinear dipoles, which we apply in different systems uncovering a complex interplay of distance, anisotropy, polarizibilities, and hyperpolarizabilities in the vdW energy. This investigation broadens our basic understanding of dispersive interactions, especially in the context of nonlinear materials., Comment: 7 pages, 3 figures; submitted; a part of this work has been presented at APS March Meeting 2023 (N17.00010)

Published

2023

10. System for Observing Play and Leisure Activity in Youth: A Systematic Review of US and Canadian Studies

Author

Kinder, Christopher J., Nam, Kahyun, Kulinna, Pamela H., Woods, Amelia M., and McKenzie, Thomas L.

Abstract

Background: The System of Observing Play and Leisure Activity in Youth (SOPLAY) has assisted in providing valid and reliable data of youth physical activity and characteristics specific to environmental contexts. The review aimed to examine empirical research that employed the SOPLAY instrument to measure physical activity in leisure-based activity environments in North American countries. Methods: The review was conducted in accordance with the Preferred Reporting Items for Systematic Reviews and Meta-Analyses. A systematic search was conducted with an exhaustive process using 10 electronic databases to locate peer-reviewed studies implementing SOPLAY that were published between 2000 and 2021. Results: A total of 60 studies were included in the review. Most studies (n = 35) reported physical activity findings related to contextual characteristics measured using SOPLAY. Interestingly, a few of the studies (n = 8) found the provision of equipment and supervision, particularly adult supervision, significantly increased child physical activity observed. Conclusions: This review provides information relative to the group-level physical activity observed across multiple contexts (i.e., playgrounds, parks, recreation centers) using a validated direct observation instrument.

Published

2023

11. Implementing Service-Learning in an IT Strategy Course

Author

Woods, David M.

Abstract

Students studying technical fields like IS/IT (Information Systems/Information Technology) face the challenge of showing potential employers that they have done work for real clients, not just course projects that are never used. At the same time, instructors face the challenge of actively engaging students in learning course content and understanding how to apply course content in different situations. Previous work shows that service-learning can be a valuable tool to improve student engagement while offering an opportunity for a real-world learning experience. However, the existing literature provides examples of using service-learning in various IS/IT courses but with little discussion of service-learning in IS/IT strategy courses. This work discusses implementing a service-learning project with a local non-profit organization in an IS/IT strategy class. Details of the design and implementation of the service-learning project and assessment from the student, instructor, and client perspectives are provided.

Published

2022

12. Interaction-driven transport of dark excitons in 2D semiconductors with phonon-mediated optical readout

Author

Chand, Saroj B., Woods, John M., Quan, Jiamin, Mejia, Enrique, Taniguchi, Takashi, Watanabe, Kenji, Alù, Andrea, and Grosso, Gabriele

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Quantum Gases

Abstract

The growing field of quantum information technology requires propagation of information over long distances with efficient readout mechanisms. Excitonic quantum fluids have emerged as a powerful platform for this task due to their straightforward electro-optical conversion. In two-dimensional transition metal dichalcogenides, the coupling between spin and valley provides exciting opportunities for harnessing, manipulating and storing bits of information. However, the large inhomogeneity of single layers cannot be overcome by the properties of bright excitons, hindering spin-valley transport. Nonetheless, the rich band structure supports dark excitonic states with strong binding energy and longer lifetime, ideally suited for long-range transport. Here we show that dark excitons can diffuse over several micrometers and prove that this repulsion-driven propagation is robust across non-uniform samples. The long-range propagation of dark states with an optical readout mediated by chiral phonons provides a new concept of excitonic devices for applications in both classical and quantum information technology.

Published

2022

13. Enhanced Magnetism in Heterostructures with Transition-Metal Dichalcogenide Monolayers

Author

Dang, Diem Thi-Xuan, Barik, Ranjan Kumar, Phan, Manh-Huong, and Woods, Lilia M.

Subjects

Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Two-dimensional materials and their heterostructures have opened up new possibilities for magnetism at the nanoscale. In this study, we utilize first-principles simulations to investigate the structural, electronic, and magnetic properties of $\textrm{Fe}/\textrm{WSe}_2/\textrm{Pt}$ systems containing pristine, defective, or doped $\textrm{WSe}_2$ monolayers. The proximity effects of the ferromagnetic Fe layer are studied by considering defective and vanadium-doped $\textrm{WSe}_2$ monolayers. All heterostructures are found to be ferromagnetic, and the insertion of the transition-metal dichalcogenide results in a redistribution of spin orientation and an increased density of magnetic atoms due to the magnetized $\textrm{WSe}_2$. There is an increase in the overall total density of states at the Fermi level due to $\textrm{WSe}_2$; however, the transition-metal dichalcogenide may lose its distinct semiconducting properties due to the stronger than van der Waals coupling. Spin-resolved electronic structure properties are linked to larger spin Seebeck coefficients found in heterostructures with $\textrm{WSe}_2$ monolayers., Comment: 22 pages, 5 figures, 1 table

Published

2022

14. Twisted bilayered graphenes at magic angles and Casimir interactions: correlation-driven effects

Author

Rodriguez-Lopez, Pablo, Le, Dai-Nam, Calderón, María J., Bascones, Elena, and Woods, Lilia M.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science, Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Superconductivity, Quantum Physics

Abstract

Twisted bilayered graphenes at magic angles are systems housing long ranged periodicity of Moir\'e pattern together with short ranged periodicity associated with the individual graphenes. Such materials are a fertile ground for novel states largely driven by electronic correlations. Here we find that the ubiquitous Casimir force can serve as a platform for macroscopic manifestations of the quantum effects stemming from the magic angle bilayered graphenes properties and their phases determined by electronic correlations. By utilizing comprehensive calculations for the electronic and optical response, we find that Casimir torque can probe anisotropy from the Drude conductivities in nematic states, while repulsion in the Casimir force can help identify topologically nontrivial phases in magic angle twisted bilayered graphenes., Comment: 9 pages, 6 figures (main), 7 pages, 7 figures (supplementary); provisionally accepted for publication in 2D Materials

Published

2022

15. Technical Feasibility and Clinical Efficacy of Iliac Vein Stent Placement in Adolescents and Young Adults with May–Thurner Syndrome

Author

Bertino, Frederic J., Hawkins, C. Matthew, Woods, Gary M., Shah, Jay H., Variyam, Darshan E., Patel, Kavita N., and Gill, Anne E.

Published

2024

16. Promoting Positive Student Outcomes: The Use of Reflection and Planning Activities with a Growth-Mindset Focus and SMART Goals

Author

Poe, Laura F., Brooks, Nita G., Korzaan, Melinda, Hulshult, Andrea R., and Woods, David M.

Abstract

The growth-mindset was examined to determine student perception of success by incorporating goalsetting activities into the course curriculum. Faculty at three universities conducted a mixed methods study to examine the extent to which reflection and planning activities designed to engage a growth-mindset focus through setting SMART (Specific, Measurable, Achievable, Relevant, and Timebound) goals resulted in perceived positive outcomes for students. Students engaged in these activities throughout the semester completed a voluntary survey at the end of each course. The survey focused on students' perceptions regarding the activities relative to their overall course progress. Students' favorable results revealed that students favorably perceived that the growth mindset planning and reflection assignments increased their learning. Details of the study along with conclusions and directions for future research are provided.

Published

2021

17. Emergence of new optical resonances in single-layer transition metal dichalcogenides with atomic-size phase patterns

Author

Woods, John M., Chand, Saroj B., Mejia, Enrique, Taniguchi, Takashi, Watanabe, Kenji, Flick, Johannes, and Grosso, Gabriele

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science, Condensed Matter - Quantum Gases

Abstract

Atomic-scale control of light-matter interactions represent the ultimate frontier for many applications in photonics and quantum technology. Two-dimensional semiconductors, including transition metal dichalcogenides, are a promising platform to achieve such control due to the combination of an atomically thin geometry and convenient photophysical properties. Here, we demonstrate that a variety of durable polymorphic structures can be combined to generate additional optical resonances beyond the standard excitons. We theoretically predict and experimentally show that atomic-sized patches of 1T phase within the 1H matrix form unique electronic bands that give rise to new and robust optical resonances with strong absorption, circularly polarized emission and long radiative lifetime. The atomic manipulation of two-dimensional semiconductors opens unexplored scenarios for light harvesting devices and exciton-based photonics.

Published

2022

18. Dispersive interactions between standard and Dirac materials and the role of dimensionality

Author

Le, Dai-Nam, Rodriguez-Lopez, Pablo, and Woods, Lilia M.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics, Quantum Physics

Abstract

The van der Waals (vdW) interaction plays a prominent role between neutral objects at separations where short ranged chemical forces are negligible. This type of dispersive coupling is determined by the interplay between geometry and response properties of the materials making up the objects. Here, we investigate the vdW interaction between 1D, 2D, and 3D standard and Dirac materials within the Random Phase Approximation, which takes into account collective excitations originating from the electronic Coulomb potential. A comprehensive understanding of characteristic functionalities and scaling laws are obtained for systems with parabolic energy dispersion (standard materials) and crossing linear bands (Dirac materials). By comparing the quantum mechanical and thermal limits the onset of thermal fluctuations in the vdW interaction is discussed showing that thermal effects are significantly pronounced at smaller scales in reduced dimensions., Comment: 8 pages (main), 6 pages (supplementary information), 5 figures. Published on Journal of Physics: Materials

Published

2022

19. Enacting Number Talks in a Simulated Classroom Environment: What Do Preservice Teachers Notice about Students?

Author

Woods, Dawn M.

Abstract

Number talks are short mathematical discussions offering sensemaking opportunities for students. Aside from bolstering students' mathematical learning, this instructional routine may also support preservice teachers (PSTs) in investigating how to facilitate discussion-focused instruction. In this study, PSTs engage in a learning cycle to explore, plan and rehearse two separate number talks during human-in-the-loop simulations, and then reflect on these experiences. During the first simulation, PSTs focus on understanding the routine's components while positioning avatar-students as sensemakers as they elicit their participation. In the second simulation, PSTs build their instructional skills as they record representations of students' mathematical thinking, probe students' thinking in order to make mathematics visible, as well as notice missed opportunities to support students' mathematical reasoning during reflections of their experiences. Implications of this study suggest that simulations, when embedded within a cycle of enactment and reflection, support PSTs in developing professional noticing skills.

Published

2021

20. Visualization of dark excitons in semiconductor monolayers for high-sensitivity strain sensing

Author

Chand, Saroj B., Woods, John M., Mejia, Enrique, Taniguchi, Takashi, Watanabe, Kenji, and Grosso, Gabriele

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Transition metal dichalcogenides (TMDs) are layered materials that have a semiconducting phase with many advantageous optoelectronic properties, including tightly bound excitons and spin-valley locking. In Tungsten-based TMDs, spin and momentum forbidden transitions give rise to dark excitons that typically are optically inaccessible but represent the lowest excitonic states of the system. Dark excitons can deeply affect transport, dynamics and coherence of bright excitons, hampering device performance. Therefore, it is crucial to create conditions in which these excitonic states can be visualized and controlled. Here, we show that compressive strain in WS2 enables phonon scattering of photoexcited electrons between momentum valleys, enhancing the formation of dark intervalley excitons. We show that the emission and spectral properties of momentum-forbidden excitons are accessible and strongly depend on the local strain environment that modifies the band alignment. This mechanism is further exploited for strain sensing in two-dimensional semiconductors revealing a gauge factor exceeding 10^4.

Published

2022

21. A Gapped Phase in Semimetallic T$_{d}$-WTe$_{2}$ Induced by Lithium Intercalation

Author

Wang, Mengjing, Kumar, Aakash, Dong, Hao, Woods, John M., Pondick, Joshua V., Xu, Shiyu, Guo, Peijun, Qiu, Diana Y., and Cha, Judy J.

Subjects

Condensed Matter - Materials Science

Abstract

The Weyl semimetal WTe$_{2}$ has shown several correlated electronic behaviors, such as the quantum spin Hall effect, superconductivity, ferroelectricity, and a possible exciton insulator state, all of which can be tuned by various physical and chemical approaches. Here, we discover a new electronic phase in WTe$_{2}$ induced by lithium intercalation. The new phase exhibits an increasing resistivity with decreasing temperature and its carrier density is almost two orders of magnitude lower than the carrier density of the semi-metallic T$_{d}$ phase, probed by in situ Hall measurements as a function of lithium intercalation. Our theoretical calculations predict the new lithiated phase to be a charge density wave (CDW) phase with a bandgap of ~ 0.14 eV, in good agreement with the in situ transport data. The new phase is structurally distinct from the initial T$_{d}$ phase, characterized by polarization angle-dependent Raman spectroscopy, and large lattice distortions close to 6 % are predicted in the new phase. Thus, we report the first experimental evidence of CDW in T$_{d}$-WTe$_{2}$, projecting WTe$_{2}$ as a new playground for studying the interplay between CDW and superconductivity. Our finding of a new gapped phase in a two-dimensional (2D) semi-metal also demonstrates electrochemical intercalation as a powerful tuning knob for modulating electron density and phase stability in 2D materials., Comment: 6 figures

Published

2022

22. Using Goal Setting Assignments to Promote a Growth Mindset in IT Students

Author

Woods, David M.

Abstract

This paper explores how goal-setting activities in a course were used to promote a growth mindset in students. Research shows many benefits for students with a growth mindset that emphasizes learning and addressing challenges by focusing on effort and process rather than judgments about success or ability. Activities designed to prompt students to improve general skills that would make them better students and prepare them to be lifelong learners were introduced in two upper level IT courses. The activities were designed to promote a growth mindset by focusing on the efforts made and processes used rather than the outcomes. Assessment of the activities found that students demonstrated a growth mindset in their work, saw clear value in the activities, and made progress in improving specific skills.

Published

2020

23. Applying Agile across the IT Curriculum

Author

Hulshult, Andrea and Woods, David M.

Abstract

Agile is emerging as a new paradigm for organizations across a variety of industry sectors because Agile helps teams manage and adapt quickly to change. In order to provide our students with workforce ready skills and better performance in group projects, a regional campus Computer and Information Technology (CIT) department began implementing Agile across its curriculum. After a visit to a local business who underwent an Agile transformation and is now using Agile for all their teams, they said that understanding the culture of Agile is more important than the practices themselves. Revising our curriculum allows us to give our students the advantage of learning how to be Agile and what it means to thrive in an Agile culture.

Published

2020

24. Heterointerface control over lithium-induced phase transitions in MoS2 heterostructures

Author

Pondick, Joshua V., Kumar, Aakash, Wang, Mengjing, Yazdani, Sajad, Woods, John M., Qiu, Diana Y., and Cha, Judy J.

Subjects

Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Phase transitions of two-dimensional materials and their heterostructures enable many applications including electrochemical energy storage, catalysis, and memory; however, the nucleation pathways by which these transitions proceed remain underexplored, prohibiting engineering control for these applications. Here, we demonstrate that the lithium intercalation-induced 2H-1T' phase transition in MoS2 proceeds via nucleation of the 1T' phase at a heterointerface by monitoring the phase transition of MoS2/graphene and MoS2/hexagonal boron nitride (hBN) heterostructures with Raman spectroscopy in situ during intercalation. We observe that graphene-MoS2 heterointerfaces require an increase of 0.8 V in applied electrochemical potential to nucleate the 1T' phase in MoS2 compared to hBN-MoS2 heterointerfaces. The increased nucleation barrier at graphene-MoS2 heterointerfaces is due to the reduced charge transfer from lithium to MoS2 at the heterointerface as lithium also dopes graphene based on ab initio calculations. Further, we show that the growth of the 1T' domain propagates along the heterointerface, rather than through the interior of MoS2. Our results provide the first experimental observations of the heterogeneous nucleation and growth of intercalation-induced phase transitions in two-dimensional materials and heterointerface effects on their phase transition., Comment: 5 figures

Published

2021

25. Thickness Dependence of Magneto-transport Properties in Tungsten Ditelluride

Author

Zhang, Xurui, Kakani, Vivek, Woods, John M., Cha, Judy J., and Shi, Xiaoyan

Subjects

Condensed Matter - Materials Science

Abstract

We investigate the electronic structure of tungsten ditelluride (WTe$_2$) flakes with different thicknesses in magneto-transport studies. The temperature-dependent resistance and magnetoresistance (MR) measurements both confirm the breaking of carrier balance induced by thickness reduction, which suppresses the `turn-on' behavior and large positive MR. The Shubnikov-de-Haas oscillation studies further confirm the thickness-dependent change of electronic structure of WTe$_2$ and reveal a possible temperature-sensitive electronic structure change. Finally, we report the thickness-dependent anisotropy of Fermi surface, which reveals that multi-layer WTe$_2$ is an electronic 3D material and the anisotropy decreases as thickness decreases.

Published

2021

26. IT Disconnect at Cascade Sustainable Energy

Author

Woods, David M.

Abstract

The IT or IS department of a business or other organization exists to serve the larger organization and support other parts of the organization in working to achieve departmental and organizational goals. This case explores a situation where the IT organization has lost focus on the need to serve and support the rest of the organization. The case explores problems with the technology system used to support the new employee orientation process at Cascade Sustainable Energy and follows a new IT employee as he explores the problem and looks to improve the connection between IT and the HR staff responsible for the orientation process. The similarities between a corporate new employee orientation process and the new student orientation processes used at most colleges and universities should allow students to understand the case. The case is setup to allow students to engage in developing ideas for improving the technology supporting the orientation process and to look at the existing disconnect and how it might be solved. This case can also be used to support discussion of recent studies showing that a sizable portion of business leaders have concerns about their IT organization's ability to support the company's business strategy.

Published

2019

27. Coral settlement and recruitment are negatively related to reef fish trait diversity

Author

Chow, Cher F. Y., Bolton, Caitlin, Boutros, Nader, Brambilla, Viviana, Fontoura, Luisa, Hoey, Andrew S., Madin, Joshua S., Pizarro, Oscar, Torres-Pulliza, Damaris, Woods, Rachael M., Zawada, Kyle J. A., Barbosa, Miguel, and Dornelas, Maria

Published

2023

28. Heterointerface effects on lithium-induced phase transitions in intercalated MoS2

Author

Yazdani, Sajad, Pondick, Joshua V., Kumar, Aakash, Yarali, Milad, Woods, John M., Hynek, David J., Qiu, Diana Y., and Cha, Judy J.

Subjects

Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The intercalation-induced phase transition of MoS2 from the semiconducting 2H to the semimetallic 1T' phase has been studied in detail for nearly a decade; however, the effects of a heterointerface between MoS2 and other two-dimensional (2D) crystals on the phase transition have largely been overlooked. Here, ab initio calculations show that intercalating Li at a MoS2-hexagonal boron nitride (hBN) interface stabilizes the 1T phase over the 2H phase of MoS2 by ~ 100 mJ m-2, suggesting that encapsulating MoS2 with hBN may lower the electrochemical energy needed for the intercalation-induced phase transition. However, in situ Raman spectroscopy of hBN-MoS2-hBN heterostructures during electrochemical intercalation of Li+ shows that the phase transition occurs at the same applied voltage for the heterostructure as for bare MoS2. We hypothesize that the predicted thermodynamic stabilization of the 1T'-MoS2-hBN interface is counteracted by an energy barrier to the phase transition imposed by the steric hindrance of the heterointerface. The phase transition occurs at lower applied voltages upon heating the heterostructure, which supports our hypothesis. Our study highlights that interfacial effects of 2D heterostructures can go beyond modulating electrical properties and can modify electrochemical and phase transition behaviors., Comment: 4 figures and 1 table

Published

2020

29. Cm2 Scale Synthesis of MoTe2 Thin Films with Large Grains and Layer Control David

Author

Hynek, David J., Singhania, Raivat M., Xu, Shiyu, Davis, Benjamin, Wang, Lei, Yarali, Milad, Pondick, Joshua V., Woods, John M., Strandwitz, Nicholas C., and Cha, Judy J.

Subjects

Condensed Matter - Materials Science

Abstract

Owing to the small energy differences between its polymorphs, MoTe2 can access a full spectrum of electronic states, from the 2H semiconducting state to the 1T semimetallic state, and from the Td Weyl semimetallic state to the superconducting state in the 1T and Td phase at low temperature. Thus, it is a model system for phase transformation studies as well as quantum phenomena such as the quantum spin Hall effect and topological superconductivity. Careful studies of MoTe2 and its potential applications require large area MoTe2 thin films with high crystallinity and thickness control. Here, we present cm2 scale synthesis of 2H MoTe2 thin films with layer control and large grains that span several microns. Layer control is achieved by controlling the initial thickness of the precursor MoOx thin films, which are deposited on sapphire substrates by atomic layer deposition and subsequently tellurized. Despite the van der Waals epitaxy, the precursor-substrate interface is found to critically determine the uniformity in thickness and grain size of the resulting MoTe2 films: MoTe2 grown on sapphire show uniform films while MoTe2 grown on amorphous SiO2 substrates form islands. This synthesis strategy decouples the layer control from the variabilities of growth conditions for robust growth results, and is applicable to grow other transition metal dichalcogenides with layer control., Comment: 6 figure

Published

2020

30. Enhanced solar photothermal effect of PANi fabrics with plasmonic nanostructures

Author

Nga, Do T., Phan, Anh D., Lam, Vu D., Woods, Lilia M., and Wakabayashi, Katsunori

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science, Physics - Applied Physics, Physics - Optics

Abstract

The photothermal energy conversion in hanging and floating polyaniline (PANi)-cotton fabrics is investigated using a model based on the heat diffusion equation. Perfect absorption and anti-reflection of wet hanging PANi-cotton fabrics cause quick transfer of total incident light into water confining nearly 100 $\%$ of the sunlight. As a result, a hanging membrane is found to have more attractive properties than a floating above water fabric. We find, however, that the photothermal properties of a floating PANi-cotton membrane can greatly be enhanced by dispersing TiN nanoparticles in the water below the fabric. The calculated temperature gradients for TiN nanoparticle solutions show that the absorbed energy grows with increasing the nanoparticle density and that the photothermal process occurs mostly near the surface. The collective heating effects depend on the size and density of nanoparticles, which can further be used to modulate the photothermal process., Comment: 7 pages, 5 figures, accepted for publication in RSC Advances

Published

2020

31. Crossover Between Weak Antilocalization and Weak Localization and Electron-Electron Interaction in Few-Layer WTe$_2$

Author

Zhang, Xurui, Woods, John M., Cha, Judy J., and Shi, Xiaoyan

Subjects

Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We report electron transport studies in an encapsulated few-layer WTe$_2$ at low temperatures and high magnetic fields. The magnetoconductance reveals a temperature-induced crossover between weak antilocalization (WAL) and weak localization (WL) in quantum diffusive regime. We show that the crossover clearly manifests coexistence and competition among several characteristic lengths, including the dephasing length, the spin-flip length, and the mean free path. In addition, low temperature conductance increases logarithmically with the increase of temperature indicating an interplay of electron-electron interaction (EEI) and spin-orbit coupling (SOC). We demonstrate the existences and quantify the strengths of EEI and SOC which are considered to be responsible for gap opening in the quantum spin hall state in WTe2 at the monolayer limit.

Published

2020

32. High-resolution observations of the solar photosphere, chromosphere and transition region. A database of coordinated IRIS and SST observations

Author

van der Voort, L. H. M. Rouppe, De Pontieu, B., Carlsson, M., Rodriguez, J. de la Cruz, Bose, S., Chintzoglou, G., Drews, A., Froment, C., Gosic, M., Graham, D. R., Hansteen, V. H., Henriques, V. M. J., Jafarzadeh, S., Joshi, J., Kleint, L., Kohutova, P., Leifsen, T., Martinez-Sykora, J., Nobrega-Siverio, D., Ortiz, A., Pereira, T. M. D., Popovas, A., Noda, C. Quintero, Dalda, A. Sainz, Scharmer, G. B., Schmit, D., Scullion, E., Skogsrud, H., Szydlarski, M., Timmons, R., Vissers, G. J. M., Woods, M. M., and Zacharias, P.

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

NASA's Interface Region Imaging Spectrograph (IRIS) provides high resolution observations of the solar atmosphere through UV spectroscopy and imaging. Since the launch of IRIS in June 2013, we have conducted systematic observation campaigns in coordination with the Swedish 1-m Solar Telescope (SST) on La Palma. The SST provides complementary high-resolution observations of the photosphere and chromosphere. The SST observations include spectro-polarimetric imaging in photospheric Fe I lines and spectrally-resolved imaging in the chromospheric Ca II 8542 A, H-alpha, and Ca II K lines. We present a database of co-aligned IRIS and SST datasets that is open for analysis to the scientific community. The database covers a variety of targets including active regions, sunspots, plage, quiet Sun, and coronal holes., Comment: Accepted for publication in Astronomy & Astrophysics (July 21, 2020)

Published

2020

33. The Casimir force, causality and the Gurzhi model

Author

Klimchitskaya, G. L., Mostepanenko, V. M., Yu, Kailiang, and Woods, L. M.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

An extended Drude model, termed as the Gurzhi model, which takes into account the electron-phonon and electron-electron interactions, is applied to calculate the Casimir force between two metallic plates. It is shown that although the dielectric permittivity of the Gurzhi model has a first order pole in the upper half-plane of complex frequencies and, thus, violates the causality principle, it can be used in a restricted frequency interval in combination with the experimental permittivity determined by the optical data for the complex index of refraction. The imaginary part of the Gurzhi dielectric permittivity of Au at low frequencies demonstrates better agreement with the permittivity given by the optical data than the simple Drude model. The Casimir pressure between two Au plates is computed using the Gurzhi, Drude and plasma model approaches, taking into account the optical data, as well as with the simple Drude and plasma models. The contribution of the electron-electron scattering to the Casimir pressure is estimated. Although a comparison with the measurement data of two precise experiments show that the Gurzhi model does not resolve the Casimir puzzle, the obtained results suggest further clarification of this fundamental problem., Comment: 20 pages, 1 Table, 5 figures; accepted for publication in Phys. Rev. B

Published

2020

34. Interaction-driven transport of dark excitons in 2D semiconductors with phonon-mediated optical readout

Author

Chand, Saroj B., Woods, John M., Quan, Jiamin, Mejia, Enrique, Taniguchi, Takashi, Watanabe, Kenji, Alù, Andrea, and Grosso, Gabriele

Published

2023

35. A review of the psychometric properties and implications for the use of the fertility quality of life tool

Author

Woods, Brittany M., Bray, Leigh Ann, Campbell, Sukhkamal, Holland, Aimee, Mrug, Sylvie, and Ladores, Sigrid

Published

2023

36. High throughput calculations for a dataset of bilayer materials

Author

Barik, Ranjan Kumar and Woods, Lilia M.

Published

2023

37. An observational pragmatic quality-of-life study on paediatric tonsillectomy and waiting for surgery

Author

Huynh, Julie, Woods, Charmaine M., and Ooi, Eng H.

Published

2023

38. Introducing the Cloud in an Introductory IT Course

Author

Woods, David M.

Abstract

Cloud computing is a rapidly emerging topic, but should it be included in an introductory IT course? The magnitude of cloud computing use, especially cloud infrastructure, along with students' limited knowledge of the topic support adding cloud content to the IT curriculum. There are several arguments that support including cloud computing in an introductory course. In light of this, several cloud computing activities based on the Amazon Web Services (AWS) cloud offerings were added to an introduction to IT course. Student and instructor perceptions of the activities and the AWS service are evaluated and future plans are discussed.

Published

2018

39. Effect of Functionalization on the Properties of Silsesquioxane; a Comparison to Silica

Author

Moradi, Marzieh, Woods, Bailey M., Rathnayake, Hemali, Williams, Stuart J., and Willing, Gerold A.

Subjects

Physics - Applied Physics, Condensed Matter - Materials Science

Abstract

While similar in nature, the properties of silica and silsesquioxane are very different, but little is known about these differences. In this paper, functionalized silsesquioxane microparticles are synthesized by adapting the modified St\"ober method and post-functionalized with rhodamine-B. The as synthesized silsesquioxane particles are characterized by a variety of physical and chemical methods. The synthesized particles are amorphous and nonporous in nature and are less dense than silica. While silsesquioxane and silica have some similar physical properties from their siloxane core, the organic functional group of silsesquioxane and the one-half oxygen difference in its structure impact many other properties of these particles like their charging behavior in liquids. These differences not only allow for the ease surface modification as compared to that necessary to modify silica, but also the use in a variety of colloidal systems that due to pH or electrolyte concentrations may not be suitable for silica particles. Keywords: silsesquioxane, Stober method, density, morphology, zeta potential

Published

2019

40. The Anatomy of a Star-Forming Galaxy II: the role of FUV heating via dust

Author

Benincasa, Samantha M., Wadsley, James W., Couchman, Hugh M. P., Pettitt, Alex R., Keller, Ben W., Woods, Rory M., and Grond, Jasper J.

Subjects

Astrophysics - Astrophysics of Galaxies

Abstract

Far-Ultraviolet (FUV) radiation greatly exceeds ultraviolet, supernovae and winds in the energy budget of young star clusters but is poorly modeled in galaxy simulations. We present results of the first isolated galaxy disk simulations to include photo-electric heating of gas via dust grains from FUV radiation self-consistently, using a ray-tracing approach that calculates optical depths along the source-receiver sight-line. This is the first science application of the TREVR radiative transfer algorithm. We find that FUV radiation alone cannot regulate star formation. However, FUV radiation produces warm neutral gas and is able to produce regulated galaxies with realistic scale heights. FUV is also a long-range feedback and is more important in the outer disks of galaxies. We also use the super-bubble feedback model, which depends only on the supernova energy per stellar mass, is more physically realistic than common, parameter-driven alternatives and thus better constrains supernova feedback impacts. FUV and supernovae together can regulate star formation without producing too much hot ionized medium and with less disruption to the ISM compared to supernovae alone., Comment: accepted by MNRAS

Published

2019

41. Signatures of Complex Optical Response in Casimir Interactions of Type I and II Weyl Semimetals

Author

Rodriguez-Lopez, Pablo, Popescu, Adrian, Fialkovsky, Ignat, Khusnutdinov, Nail, and Woods, Lilia M.

Subjects

Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The Casimir interaction is induced by electromagnetic fluctuations between objects and it is strongly dependent upon the electronic and optical properties of the materials making up the objects. Here we investigate this ubiquitous interaction between Weyl semimetals, a class of 3D systems with low energy linear dispersion and nontrivial topology due to symmetry conditions and stemming from separated energy cones. A comprehensive examination of all components of the bulk conductivity tensor as well as the surface conductivity due to the Fermi arc states in real and imaginary frequency domains is presented using the Kubo formalism for Weyl semimetals with different degree of tilting of their linear energy cones. The Casimir energy is calculated using a generalized Lifhsitz approach, for which electromagnetic boundary conditions for anisotropic materials were derived and used. We find that the Casimir interaction between Weyl semimetals is metallic-like and its magnitude and characteristic distance dependence can be modified by the degree of tilting and chemical potential. The nontrivial topology plays a secondary role in the Casimir interaction of these 3D materials and thermal fluctuations are expected to have similar effects as in metallic systems., Comment: supplementary information added

Published

2019

42. Confinement effect on solar thermal heating process of TiN solutions

Author

Phan, Anh D., Le, Nam B., Lien, Nghiem T. H., Woods, Lilia M., Ishi, Satoshi, and Wakabayashi, Katsunori

Subjects

Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Applied Physics

Abstract

We propose a theoretical approach to describe quantitatively the heating process in aqueous solutions of dispersed TiN nanoparticles under solar illumination. The temperature gradients of solution with different concentrations of TiN nanoparticles are calculated when confinement effects of the container on the solar absorption are taken into account. We find that the average penetration of solar radiation into the solution is significantly reduced with increasing the nanoparticle concentration. At high concentrations, our numerical results show that photons are localized near the surface of the solution. Moreover, the heat energy balance equation at the vapor-liquid interface is used to describe the solar steam generation. The theoretical time dependence of temperature rise and vaporization weight losses is consistent with experiments. Our calculations give strong evidence that the substantially localized heating near the vapor-liquid interface is the main reason for the more efficient steam generation process by floating plasmonic membranes when compared to randomly dispersed nanoparticles. The validated theoretical model suggests that our approach can be applied towards new predictions and other experimental data descriptions., Comment: 6 pages, 3 figures, accepted for publication in PCCP

Published

2019

43. Giant Spin Seebeck Effect through an Interface Organic Semiconductor

Author

Kalappattil, V., Geng, R., Das, R., Luong, H., Pham, M., Nguyen, T., Popescu, A., Woods, L. M., Kläui, M., Srikanth, H., and Phan, M. H.

Subjects

Physics - Applied Physics

Abstract

Interfacing an organic semiconductor C60 with a non-magnetic metallic thin film (Cu or Pt) has created a novel heterostructure that is ferromagnetic at ambient temperature, while its interface with a magnetic metal (Fe or Co) can tune the anisotropic magnetic surface property of the material. Here, we demonstrate that sandwiching C60 in between a magnetic insulator (Y3Fe5O12: YIG) and a non-magnetic, strong spin-orbit metal (Pt) promotes highly efficient spin current transport via the thermally driven spin Seebeck effect (SSE). Experiments and first principles calculations consistently show that the presence of C60 reduces significantly the conductivity mismatch between YIG and Pt and the surface perpendicular magnetic anisotropy of YIG, giving rise to enhanced spin mixing conductance across YIG/C60/Pt interfaces. As a result, a 600% increase in the SSE voltage (VLSSE) has been realized in YIG/C60/Pt relative to YIG/Pt. Temperature-dependent SSE voltage measurements on YIG/C60/Pt with varying C60 layer thicknesses also show an exponential increase in VLSSE at low temperatures below 200 K, resembling the temperature evolution of spin diffusion length of C60. Our study emphasizes the important roles of the magnetic anisotropy and the spin diffusion length of the intermediate layer in the SSE in YIG/C60/Pt structures, providing a new pathway for developing novel spin-caloric materials.

Published

2019

44. TREVR: A general $N log^2 N$ radiative transfer algorithm

Author

Grond, J. J., Woods, R. M., Wadsley, J. W., and Couchman, H. M. P.

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - Cosmology and Nongalactic Astrophysics, Astrophysics - Astrophysics of Galaxies

Abstract

We present TREVR (Tree-based REVerse Ray Tracing), a general algorithm for computing the radiation field, including absorption, in astrophysical simulations. TREVR is designed to handle large numbers of sources and absorbers; it is based on a tree data structure and is thus suited to codes that use trees for their gravity or hydrodynamics solvers (e.g. Adaptive Mesh Refinement). It achieves computational speed while maintaining a specified accuracy via controlled lowering of the resolution of both sources and rays from each source. TREVR computes the radiation field in order ${N\log N_{source}}$ time without absorption and order ${N \log N_{source} \log{N}}$ time with absorption. These scalings arise from merging sources of radiation according to an opening angle criterion and walking the tree structure to trace a ray to a depth that gives the chosen accuracy for absorption. The absorption-depth refinement criterion is unique to TREVR. We provide a suite of tests demonstrating the algorithm's ability to accurately compute fluxes, ionization fronts and shadows., Comment: 15 pages, 15 figures and 1 table. Accepted by MNRAS

Published

2019

45. Multiband Effects in Equations of Motion of Observables Beyond the Semiclassical Approach

Author

Stedman, Troy, Timm, Carsten, and Woods, Lilia M.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The equations of motion for the position and gauge invariant crystal momentum are considered for multiband wave packets of Bloch electrons. For a localized packet in a subset of bands well-separated from the rest of the band structure of the crystal, one can construct an effective electromagnetic Hamiltonian with respect to the center of the packet. We show that the equations of motion can be obtained via a projection operator procedure, which is derived from the adiabatic approximation within perturbation theory. These relations explicitly contain information from each band captured in the expansion coefficients and energy band structure of the Bloch states as well as non-Abelian features originating from interband Berry phase properties. This general and transparent Hamiltonian-based approach is applied to a wave packet spread over a single band, a set of degenerate bands, and two linear crossing bands. The generalized equations of motion hold promise for novel effects in transport currents and Hall effect phenomena.

Published

2019

46. Collaborative Gestures When Proving Geometric Conjectures

Author

Walkington, Candace, Nathan, Mitchell J., and Woods, Dawn M.

Abstract

Research in mathematics education has established that gestures--spontaneous movements of the hand that accompany speech--are important for learning. In the present study, we examine how students use gestures to communicate with each other while proving geometric conjectures, arguing that this communication represents an example of extended cognition. We identify three kinds of "collaborative gestures"--gestures that are physically distributed over multiple learners. Learners make echoing gestures by copying another learner's hand gestures, mirroring gestures by gesturing identically and simultaneously with another learner, and joint gestures where multiple learners collectively make a single gesture of a mathematical object using more than one set of hands. The identification and description of these kinds of collaborative gestures offers insight into how learners build distributed mathematical understanding. [For complete proceedings, see ED581294.]

Published

2017

47. Composition and Stacking Dependent Topology in Bilayers from the Graphene Family

Author

Popescu, Adrian, Rodriguez-Lopez, Pablo, and Woods, Lilia M.

Subjects

Condensed Matter - Materials Science

Abstract

We present a compositional and structural investigation of silicene, germanene, and stanene bilayers from first-principles. Due to the staggering of the individual layers, several stacking patterns are possible, most of which are not available to the bilayer graphene. This structural variety, in conjunction with the presence of the spin-orbit coupling, unveil a diversity of the electronic properties, with the appearance of distinct band features, including orbital hybridization and band inversion. We show that for particular cases, the intrinsic spin Hall response exhibits signatures of non-trivial electronic band topology, making these structures promising candidates to probe Dirac-like physics.

Published

2018

48. The Triggering of the 29-March-2014 Filament Eruption

Author

Woods, Magnus M., Inoue, Satoshi, Harra, Louise K., Matthews, Sarah A., Kusano, Kanya, and Kalmoni, Nadine M. E.

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

The X1 flare and associated filament eruption occurring in NOAA Active Region 12017 on SOL2014-03-29 has been the source of intense study. In this work, we analyse the results of a series of non linear force free field extrapolations of the pre and post flare period of the flare. In combination with observational data provided by the IRIS, Hinode and SDO missions, we have confirmed the existence of two flux ropes present within the active region prior to flaring. Of these two flux ropes, we find that intriguingly only one erupts during the X1 flare. We propose that the reason for this is due to tether cutting reconnection allowing one of the flux ropes to rise to a torus unstable region prior to flaring, thus allowing it to erupt during the subsequent flare.

Published

2018

49. Thermally driven anomalous Hall effect transitions in FeRh

Author

Popescu, Adrian, Rodriguez-Lopez, Pablo, Haney, Paul M., and Woods, Lilia M.

Subjects

Condensed Matter - Materials Science

Abstract

Materials exhibiting controllable magnetic phase transitions are currently in demand for many spintronics applications. Here we investigate from first principles the electronic structure and intrinsic anomalous Hall, spin Hall and anomalous Nernst response properties of the FeRh metallic alloy which undergoes a thermally driven antiferromagnetic-to-ferromagnetic phase transition. We show that the energy band structures and underlying Berry curvatures have important signatures in the various Hall effects. Specifically, the suppression of the anomalous Hall and Nernst effects in the AFM state and a sign change in the spin Hall conductivity across the transition are found. It is suggested that the FeRh can be used a spin current detector capable of differentiating the spin Hall effect from other anomalous transverse effects. The implications of this material and its thermally driven phases as a spin current detection scheme are also discussed.

Published

2018

50. Thermal Casimir and Casimir-Polder interactions in $N$ parallel 2D Dirac materials

Author

Khusnutdinov, Nail, Kashapov, Rashid, and Woods, Lilia M.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, High Energy Physics - Theory, Quantum Physics

Abstract

The Casimir and Casimir-Polder interactions are investigated in a stack of equally spaced graphene layers. The optical response of the individual graphene is taken into account using gauge invariant components of the polarization tensor extended to the whole complex frequency plane. The planar symmetry for the electromagnetic boundary conditions is further used to obtain explicit forms for the Casimir energy stored in the stack and the Casimir-Polder energy between an atom above the stack. Our calculations show that these fluctuation induced interactions experience strong thermal effects due to the graphene Dirac-like energy spectrum. The spatial dispersion and temperature dependence in the optical response are also found to be important for enhancing the interactions especially at smaller separations. Analytical expressions for low and high temperature limits and their comparison with corresponding expressions for an infinitely conducting planar stack are further used to expand our understanding of Casimir and Casimir-Polder energies in Dirac materials. Our results may be useful to experimentalists as new ways to probe thermal effects at the nanoscale in such universal interactions., Comment: 8 pages

Published

2018