Graphene, universality of the quantum Hall effect and redefinition of the SI system

Janssen, T. J. B. M.; Fletcher, Nick; Goebel, R; Williams, Jonathan M. J.; Tzalenchuk, Alexander; Yakimova, Rositsa; Kubatkin, Sergey; Lara‐Avila, Samuel; Falko, Vladimir

doi:10.1088/1367-2630/13/9/093026

Cited by 76 publications

(77 citation statements)

References 14 publications

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“…3 In particular, graphene grown on the Si-face of SiC (SiC/G) has been the material of choice for the fabrication of graphene-based high performance electronic devices such as high-frequency analogue transistors, 4 sensors, 5 and quantum resistance standards. [6][7][8][9][10] In SiC/G, the two-dimensional system is formed by graphene situated on top of a non-conducting buffer carbon layer (the 0-layer), covalently bonded to SiC. Charge transfer between graphene and the localised donor states in the buffer, driven by the work function difference A $ 1 eV, leads to a significant electron density in the as grown SiC/G, typically n $ 10 13 cm À2 .…”

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Tuning carrier density across Dirac point in epitaxial graphene on SiC by corona discharge

Lartsev

Yager

Bergsten

et al. 2014

Applied Physics Letters

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We demonstrate reversible carrier density control across the Dirac point (Delta n similar to 10(13) cm(-2)) in epitaxial graphene on SiC (SiC/G) via high electrostatic potential gating with ions produced by corona discharge. The method is attractive for applications where graphene with a fixed carrier density is needed, such as quantum metrology, and more generally as a simple method of gating 2DEGs formed at semiconductor interfaces and in topological insulators.

Funding Agencies|Graphene Flagship [CNECT-ICT-604391]; Swedish Foundation for Strategic Research (SSF); Linnaeus Centre for Quantum Engineering; Knut and Allice Wallenberg Foundation; Chalmers AoA Nano; NMS (UK); EMRP project GraphOhm; EMRP within EURAMET; European Union

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Tuning carrier density across Dirac point in epitaxial graphene on SiC by corona discharge

Lartsev

Yager

Bergsten

et al. 2014

Applied Physics Letters

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“…Thus, with graphene a highly precise QHR standard working at low magnetic fields and temperatures above 4 kelvin is conceivable, which would be an enormous advantage for practical metrology. In fact, when measuring with direct current (dc), it has been demonstrated already that the precision of the QHE in high quality graphene devices matches that of GaAs devices [6][7][8][9]. However, in the forthcoming fundamental constant-based redefinition of the Système International d'Unités (SI) [10], also the impedance units (capacitance and inductance) will be traced to fundamental constants [11].…”

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“…not specially shielded) GaAs devices. They demonstrate that it is indeed promising to develop a graphene-based impedance standard which is much less affected by capacitive effects and can possibly be applied without the elaborate methods required for GaAs, and at the same time can be operated under the same relaxed temperature and magnetic field requirements as are envisioned for the application of graphene as a dc resistance standard [6][7][8][9].The measurements presented in this study were carried out on a large-area Hall bar device (800 µm x 200 µm) lithographically patterned on a graphene film grown on the siliconterminated face of a 4H silicon carbide substrate [15]. The film had been grown in argon at atmospheric pressure, at a temperature of 1650 °C within 5 minutes.…”

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Towards a graphene-based quantum impedance standard

Kalmbach

Schurr

Ahlers

et al. 2014

Applied Physics Letters

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Precision measurements of the quantum Hall resistance with alternating current (ac) in the kHz range were performed on epitaxial graphene in order to assess its suitability as a quantum standard of impedance. The quantum Hall plateaus measured with alternating current were found to be flat within one part in 10 7 . This is much better than for plain GaAs quantum Hall devices and shows that the magnetic-fluxdependent capacitive ac losses of the graphene device are less critical. The observed frequency dependence of about -8×10 -8 /kHz is comparable in absolute value to the positive frequency dependence of plain GaAs devices, but the negative sign is attributed to stray capacitances which we believe can be minimized by a careful design of the graphene device. Further improvements thus may lead to a simpler and more user-friendly quantum standard for both resistance and impedance.Graphene is probably the most fascinating electronic material discovered in the last decades [1][2][3]. Among its various unique properties, an anomalous 'half-integer' quantum Hall effect (QHE) is most interesting for metrology, where the fact that the Hall resistance is quantized and depends only on fundamental constants is utilized for the representation and maintenance of the resistance unit, the ohm. Typically, twodimensional electron systems (2DES) realized in GaAs/AlGaAs heterostructures [4] are used for this purpose. The required relative measurement uncertainty of better than 1 part in 10 8 is, however, only obtained at strong magnetic fields around 10 tesla and at temperatures of 1.4 kelvin and below. In contrast, in graphene the cyclotron energy splitting between the Landau levels (which is the main factor determining the robustness of the quantized Hall resistance (QHR)) is so large that fingerprints of the QHE are even observed at room temperature [5]. Thus, with graphene a highly precise QHR standard working at low magnetic fields and temperatures above 4 kelvin is conceivable, which would be an enormous advantage for practical metrology. In fact, when measuring with direct current (dc), it has been demonstrated already that the precision of the QHE in high quality graphene devices matches that of GaAs devices [6][7][8][9]. However, in the forthcoming fundamental constant-based redefinition of the Système International d'Unités (SI) [10], also the impedance units (capacitance and inductance) will be traced to fundamental constants [11]. The most direct way to represent the impedance units is to use a quantum Hall resistance measured with alternating current (ac QHR). This has two advantages. Firstly, deriving the resistance and impedance units from the same quantum effect improves the consistency of the SI. And secondly, using the same QHE device at dc and at ac in one and the same cryomagnetic system would constitute a practical and economical advantage. Therefore, the question naturally arises whether graphene can replace GaAs also in the realm of impedance units, leading to an at least equally precise, but more userfriendl...

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“…Furthermore, considering the specialization and niche nature of much scientific research, it follows that scholars would be the primary audience for this content, regardless of the platform on which it appears. To illustrate, the most viewed YouTube NJP video abstract in the 56 article sample data set was "Graphene, universality of the quantum Hall effect and redefinition of the SI system," which described a physics related experiment to test the validity of a change in the way mass and electrical current are measured (Janssen, et al, 2011). This particular experiment may be of greatest interest to Journal of Librarianship and Scholarly Communication | jlsc-pub.org JL SC scientists in solid-state physics, a field that, according to the video abstract, has studied the presence of the quantum Hall effect in materials.…”

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Exploring Video Abstracts in Science Journals: An Overview and Case Study

Spicer

2014

Journal of Librarianship and Scholarly Communication

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INTRODUCTION The video abstract has emerged in recent years as a new way of communicating the results of scholarly enquiry. For library-based journal publishers who want to support multimodal scholarship, it is useful to understand the potential benefit and impact of incorporating video abstracts into their publications. This paper provides an overview of the growth of video abstracts in science scholarship, and presents a single journal case study that compares the use and potential impact of video abstracts hosted on both YouTube and on a journal’s own website. METHODS For the case study, video abstract usage data for the New Journal of Physics (NJP) was gathered from both YouTube and the NJP native platform and then correlated using a Spearman rank correlation coefficient test to analyze viewing usage. Viewership data from both platforms was also correlated with article usage counts using Spearman to study the relationship between article usage and corresponding video abstract usage. RESULTS Users predominantly accessed the journal’s hosted video abstracts instead of the abstracts posted on YouTube. However, there was a moderate positive correlation comparing view counts of the same video abstracts across both platforms, suggesting proportionate use of both platforms. In addition, the top 25 and 100 read articles had a significantly higher presence of video abstracts than articles overall in the data set, although a specific reason for that relationship cannot be identified. DISCUSSION & CONCLUSION Video abstracts are a natural evolution of science communication into multimodal environments. Publishing trends will likely continue to grow gradually, with appreciation for non-traditional scholarship (multimodal scholarship) and new measures for assessing impact (altmetrics) potentially encouraging greater adoption. Librarybased journal publishers should consider investing in software that offers dynamic media integration, offering the video abstract option to their authors, and leveraging YouTube to further raise the visibility of their authors’ research articles and publication. Library-based publishers should have some expectation that the video abstracts will be viewed relatively proportionally across platforms (i.e. a video abstract that receives a higher or lower view count on the journal’s website is moderately more likely to also receive a higher or lower view count on YouTube), with the majority of total views (for all videos) coming from the journal’s website. Subject and media librarians should become more aware of these emerging practices to support the video abstract publication and creation needs of their research communities.

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Graphene, universality of the quantum Hall effect and redefinition of the SI system

Cited by 76 publications

References 14 publications

Tuning carrier density across Dirac point in epitaxial graphene on SiC by corona discharge

Tuning carrier density across Dirac point in epitaxial graphene on SiC by corona discharge

Towards a graphene-based quantum impedance standard

Exploring Video Abstracts in Science Journals: An Overview and Case Study

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