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L. Gailliard

Bio: L. Gailliard is an academic researcher from Mines ParisTech. The author has contributed to research in topics: Figure of merit & Bismuth telluride. The author has an hindex of 3, co-authored 3 publications receiving 314 citations.

Papers
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Journal ArticleDOI
Jean-Pierre Fleurial1, L. Gailliard1, R. Triboulet, H. Scherrer1, S. Scherrer1 
TL;DR: A thermoelectric characterization of samples of bismuth telluride of both n - and p -type is carried out, as a function of stoichiometric deviation as mentioned in this paper.

273 citations

Journal ArticleDOI
TL;DR: In this article, a model of the transport properties of p-type (Bi x Sb 1−x ) 2 Te 3 single crystals is presented, where the authors consider a single valence band and acoustic phonon and ionized impurity scattering for holes.

32 citations

Journal ArticleDOI
Jean-Pierre Fleurial1, L. Gailliard1, R. Triboulet, H. Scherrer1, S. Scherrer1 
TL;DR: In this paper, a mixed-scattering model was used to fit the sharp variations of the various parameters with stoichiometric deviations, and the optimum Fermi level for the maximum of the figure of merit was found just at the bottom of the conduction band.

26 citations


Cited by
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Journal ArticleDOI
TL;DR: The state-of-the-art in photodetectors based on semiconducting 2D materials are reviewed, focusing on the transition metal dichalcogenides, novel van der Waals materials, black phosphorus, and heterostructures.
Abstract: Two-dimensional (2D) materials have attracted a great deal of interest in recent years. This family of materials allows for the realization of versatile electronic devices and holds promise for next-generation (opto)electronics. Their electronic properties strongly depend on the number of layers, making them interesting from a fundamental standpoint. For electronic applications, semiconducting 2D materials benefit from sizable mobilities and large on/off ratios, due to the large modulation achievable via the gate field-effect. Moreover, being mechanically strong and flexible, these materials can withstand large strain (>10%) before rupture, making them interesting for strain engineering and flexible devices. Even in their single layer form, semiconducting 2D materials have demonstrated efficient light absorption, enabling large responsivity in photodetectors. Therefore, semiconducting layered 2D materials are strong candidates for optoelectronic applications, especially for photodetection. Here, we review the state-of-the-art in photodetectors based on semiconducting 2D materials, focusing on the transition metal dichalcogenides, novel van der Waals materials, black phosphorus, and heterostructures.

746 citations

Journal ArticleDOI
TL;DR: A large and tunable Seebeck coefficient of the single-layer MoS(2) paves the way to new applications of this material such as on-chip thermopower generation and waste thermal energy harvesting.
Abstract: We study the photoresponse of single-layer MoS(2) field-effect transistors by scanning photocurrent microscopy. We find that, unlike in many other semiconductors, the photocurrent generation in single-layer MoS(2) is dominated by the photothermoelectric effect and not by the separation of photoexcited electron-hole pairs across the Schottky barriers at the MoS(2)/electrode interfaces. We observe a large value for the Seebeck coefficient for single-layer MoS(2) that by an external electric field can be tuned between -4 × 10(2) and -1 × 10(5) μV K(-1). This large and tunable Seebeck coefficient of the single-layer MoS(2) paves the way to new applications of this material such as on-chip thermopower generation and waste thermal energy harvesting.

541 citations

01 Jan 2013
TL;DR: In this article, the photoresponse of single-layer MoS2 field effect transistors was studied by scanning photocurrent microscopy and it was shown that the photothermoelectric effect is dominant over the separation of photoexcited electron−hole pairs across the Schottky barriers at the MoS 2/electrode interfaces.
Abstract: We study the photoresponse of single-layer MoS2 field- effect transistors by scanning photocurrent microscopy. We find that, unlike in many other semiconductors, the photocurrent generation in single-layer MoS2 is dominated by the photothermoelectric effect and not by the separation of photoexcited electron−hole pairs across the Schottky barriers at the MoS2/electrode interfaces. We observe a large value for the Seebeck coefficient for single-layer MoS2 that by an external electric field can be tuned between −4 × 10 2 and −1 × 10 5 μ VK −1 . This large and tunable Seebeck coefficient of the single-layer MoS2 paves the way to new applications of this material such as on- chip thermopower generation and waste thermal energy harvesting.

486 citations

Journal ArticleDOI
TL;DR: In this paper, the authors identify and quantify the key material properties that make Bi2Te3 such a good thermoelectric material, which can be used for benchmarking future improvements in Bi2TE3 or new replacement materials.
Abstract: DOI: 10.1002/aelm.201800904 made for efficient thermoelectric cooling or temperature management uses Bi2Te3 alloys. Such solid-state devices dominate the market for temperature control in optoelectronics. As the need to eliminate greenhouse-gas refrigerants increases, Peltier cooling is becoming more attractive particularly in small systems where efficiencies are comparable to traditional refrigerant based cooling. Such small devices may enable distributive heating/ cooling (only where and when it is needed) with higher system level energy efficiency, for example in electric vehicles where energy for heating/cooling competes with vehicle range. Even for thermoelectric power generation, e.g., recovery of waste heat, Bi2Te3 alloys are most used because of superior efficiency up to 200 °C and the technology to make devices with Bi2Te3 is most advanced.[1–3] While the material and production technology for making Bi2Te3-based devices has remained essentially unchanged since the 1960s, our understanding of these materials has advanced considerably. Most recently, the interest in topological insulators (TI) has led to new insights into the complex electronic structure[4,5] revealing that with the accuracy in assessing the band structures available today, improvements in the electronic structure by band engineering should not only be possible but predictable.[6–9] Indeed, the p-type alloys chosen for use in commercial Peltier coolers appear to have unintentionally arrived at a composition close to a band convergence. The understanding of defects and doping is also advancing rapidly that will lead to new strategies for additional improvements in the electronic properties. The thermal conductivity of Bi2Te3-based alloys can also be engineered, where in particular there is much recent interest in microstructure engineering or nanostructuring.[10–22] Reduced thermal conductivity has led to numerous reports of exceptionally high efficiency (zT) that would be sufficient to revolutionize the industry. However, between measurement and material uncertainties, a revolutionary new Bi2Te3-based material has not made it to the market. Because even small but reliable improvements could make significant impact, it is worthwhile to better understand all the complex, interdependent effects of band engineering and microstructure engineering. To demonstrate and quantify improvements in thermoelectric properties, it is necessary to have well characterized properties or reliable benchmarks for comparison. Bismuth telluride is the working material for most Peltier cooling devices and thermoelectric generators. This is because Bi2Te3 (or more precisely its alloys with Sb2Te3 for p-type and Bi2Se3 for n-type material) has the highest thermoelectric figure of merit, zT, of any material around room temperature. Since thermoelectric technology will be greatly enhanced by improving Bi2Te3 or finding a superior material, this review aims to identify and quantify the key material properties that make Bi2Te3 such a good thermoelectric. The large zT can be traced to the high band degeneracy, low effective mass, high carrier mobility, and relatively low lattice thermal conductivity, which all contribute to its remarkably high thermoelectric quality factor. Using literature data augmented with newer results, these material parameters are quantified, giving clear insight into the tailoring of the electronic band structure of Bi2Te3 by alloying, or reducing thermal conductivity by nanostructuring. For example, this analysis clearly shows that the minority carrier excitation across the small bandgap significantly limits the thermoelectric performance of Bi2Te3, even at room temperature, showing that larger bandgap alloys are needed for higher temperature operation. Such effective material parameters can also be used for benchmarking future improvements in Bi2Te3 or new replacement materials.

350 citations

01 Jan 1995
TL;DR: In this paper, the ZT for PGEC relaxation of A,,.34.4.4 Introduction Systematic Search Historical Review New Materials Phonon "Glasses" Desired Performance PGEC Relaxation of A,.
Abstract: 34.4 Introduction Systematic Search Historical Review New Materials Phonon "Glasses" Desired Performance PGEC Relaxation of A,,. Assumption Band Gaps of Semiconductors Carrier Mobilities Background Explanation Electronegativities and Good Thermoelectric Semiconductors Dopant and Mixed-Crystal Effects on Mobilities Dopant Effects on the Weighted Mobility Mixed-Crystal Effects on Mobility Weighted Mobility Lattice Thermal Conductivity Phonon Scattering Mechanisms New Amin Crystals and New Thermoelectrics Conclusions From the Analysis Appendix: Calculation of ZT for PGEC References

341 citations