Готові списки джерел за темами / Diamond Anvil Cell (DAC)

Добірка наукової літератури з теми "Diamond Anvil Cell (DAC)"

Автор: Grafiati
Опубліковано: 6 вересня 2023

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Статті в журналах з теми "Diamond Anvil Cell (DAC)"

1

Li, Bing, Cheng Ji, Wenge Yang, Junyue Wang, Ke Yang, Ruqing Xu, Wenjun Liu, Zhonghou Cai, Jiuhua Chen, and Ho-kwang Mao. "Diamond anvil cell behavior up to 4 Mbar." Proceedings of the National Academy of Sciences 115, no. 8 (February 5, 2018): 1713–17. http://dx.doi.org/10.1073/pnas.1721425115.

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Анотація:
The diamond anvil cell (DAC) is considered one of the dominant devices to generate ultrahigh static pressure. The development of the DAC technique has enabled researchers to explore rich high-pressure science in the multimegabar pressure range. Here, we investigated the behavior of the DAC up to 400 GPa, which is the accepted pressure limit of a conventional DAC. By using a submicrometer synchrotron X-ray beam, double cuppings of the beveled diamond anvils were observed experimentally. Details of pressure loading, distribution, gasket-thickness variation, and diamond anvil deformation were studied to understand the generation of ultrahigh pressures, which may improve the conventional DAC techniques.
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2

Arlt, T., and R. J. Angel. "Pressure buffering in a diamond anvil cell." Mineralogical Magazine 64, no. 2 (April 2000): 241–45. http://dx.doi.org/10.1180/002646100549337.

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AbstractThe clinopyroxenes kanoite and spodumene were studied by single-crystal X-ray diffraction in a diamond anvil cell (DAC) at room temperature. At the displacive phase transitions between the C2/c and P21/c polymorphs both phases coexist within the same crystal. In this two-phase region the pressure in the DAC remains constant. The experimental results demonstrate that pressure buffering at first-order phase transitions can occur in the DAC.
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3

Alabdulkarim, Mohamad E., Wendy D. Maxwell, Vibhor Thapliyal, and James L. Maxwell. "A Comprehensive Review of High-Pressure Laser-Induced Materials Processing, Part I: Laser-Heated Diamond Anvil Cells." Journal of Manufacturing and Materials Processing 6, no. 5 (September 29, 2022): 111. http://dx.doi.org/10.3390/jmmp6050111.

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Laser-heated diamond anvil cell (LH-DAC) experimentation has emerged as a leading technique for materials processing at extreme pressures and temperatures. LH-DAC systems are often employed to better characterise the structure and properties of materials in applications ranging from condensed matter physics to geophysical research to planetary science. This article reviews LH-DAC and related laser-based characterisation, as the first part of a series within the broader context of all high-pressure laser-induced material processing. In part I of this review, a synopsis of laser-heated diamond anvil cell experimental methods, developmental history, fundamental physicochemical processes, and emerging research trends are provided. Important examples of minerals/materials modified during LH-DAC investigations (since their inception) are also tabulated, including key phase transformations, material syntheses, laser parameters, and process conditions—as a reference for the reader and as a guide for directing future research efforts. Note that laser-dynamic-compression within diamond anvil cells (LDC-DAC experimentation) and laser-induced reactive chemical synthesis within diamond anvil cells (LRS-DAC experimentation) are treated separately, as Parts II and III of this review.
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4

Okuda, Yoshiyuki, Kenta Oka, Koutaro Hikosaka, and Kei Hirose. "Novel non-Joule heating technique: Externally laser-heated diamond anvil cell." Review of Scientific Instruments 94, no. 4 (April 1, 2023): 043901. http://dx.doi.org/10.1063/5.0122111.

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Анотація:
The externally heated diamond anvil cell (EHDAC) conducts high pressure and temperature experiments with spatial uniformity and temporal stability. These are conventionally combined with various spectroscopies and x-ray diffraction measurements. EHDAC techniques perform Joule heating on a heater placed close to or directly in contact with diamond anvils. However, the electrical wiring and heater required for Joule heating complicate EHDAC setups, hindering easy access for the measurement of physical properties. This study proposes an EHDAC technique using laser- instead of Joule-heating. We successfully achieved temperatures reaching 900 K by applying heat to diamond anvils through laser-heating of the gaskets with thermally insulating anvil seats. To test this setup, we measured the melting temperature of H2O ice VII, which was consistent with previous studies. We also measured the high-pressure and temperature impedance of H2O VII and verified the capability of electrical resistivity measurements in this setup. This technique allows various physical property measurements owing to its simple setup required for externally laser-heated diamond anvil cell experiments. The unique characteristics of this heating technique are that (1) no heaters or wiring are required, (2) it exhibits the most efficient heating among EHDAC studies, (3) it maintains the DAC body at room temperature, and (4) diamond anvils do not detach from anvil seats after the EHDAC experiment. This method significantly simplifies the experimental setup, which allows much easier access to various physical property measurements using an EHDAC.
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5

Alabdulkarim, Mohamad E., Wendy D. Maxwell, Vibhor Thapliyal, and James L. Maxwell. "A Comprehensive Review of High-Pressure Laser-Induced Materials Processing, Part III: Laser Reactive Synthesis within Diamond Anvil Cells." Journal of Manufacturing and Materials Processing 7, no. 2 (March 3, 2023): 57. http://dx.doi.org/10.3390/jmmp7020057.

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Анотація:
The synthesis of advanced materials at high pressures has been an area of growing research interest for several decades. This article is the third in a three-part series that reviews Laser Materials Processing Within Diamond Anvil Cells (L-DACs). Part III focuses on the practice of Laser Reactive Synthesis Within Diamond Anvil Cells (LRS-DAC). During LRS-DAC processing, chemicals are precompressed within diamond anvil cells, then microscale chemical reactions are induced by focused laser beams. The method is distinguished from the well-known Laser-Heated Diamond Anvil Cell (LH-DAC) technique (see Part I) through the existence of chemical precursors (reactants), end-products, and quantifiable changes in chemical composition upon reaction. LRS-DAC processing provides at least three new degrees of freedom in the search for advanced materials (beyond adjusting static pressures and temperatures), namely: laser-excitation/cleavage of chemical bonds, time-dependent reaction kinetics via pulsed lasers, and pressure-dependent chemical kinetics. All of these broaden the synthetic phase space considerably. Through LRS-DAC experimentation, it is possible to obtain increased understanding of high-pressure chemical kinetics—and even the nature of chemical bonding itself. Here, LRS-DAC experimental methods are reviewed, along with the underlying chemistry/physics of high-pressure microchemical reactions. A chronology of key events influencing the development of LRS-DAC systems is provided, together with a summary of novel materials synthesised, and unusual chemical reactions observed. Current gaps in knowledge and emerging opportunities for further research are also suggested.
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6

Sun, Yong Zhou, Jiu Hua Chen, Vadym Drozd, and Shah Najiba. "Behavior of Decomposed Ammonia Borane at High Pressure up to ~10 GPa." Materials Science Forum 783-786 (May 2014): 1829–35. http://dx.doi.org/10.4028/www.scientific.net/msf.783-786.1829.

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We conductedin situRaman spectroscopy study on ammonia borane loaded in diamond anvil cell (DAC). The ammonia borane was decomposed at around 140 degree Celsius under the pressure ~0.7 GPa. Raman spectra show the hydrogen was desorbed within 1 hour at 140 degree Celsius. The hydrogen was sealed in the DAC well and cooled down near to room temperature. Applying higher pressure up to ~10 GPa indicates interactions between the products and loss of dihydrogen bonding. No rehydrogenation was detected in the pressure range investigated.Keywords: Ammonia borane; Diamond anvil cell; High pressure; Phase transition
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7

Wang, Jia, and Bao Jia Wu. "Thin Film Microcircuit Preparation in a Diamond Anvil Cell." Advanced Materials Research 690-693 (May 2013): 499–502. http://dx.doi.org/10.4028/www.scientific.net/amr.690-693.499.

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An effective and convenient method about molybdenum metal thin film microcircuit was developed on diamond anvil cell(DAC) under high pressure. Alumina film was used as the protective layer and sputtered on DAC. By using this method, we studied the electrical resistance variation about nanoparticles ZnS power up to 36GPa. The reversible phase transition had been reflected clearly by the electrical resistance measurements with sample.
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8

Nissim, N., S. Eliezer, M. Werdiger, and L. Perelmutter. "Approaching the “cold curve” in laser-driven shock wave experiment of a matter precompressed by a partially perforated diamond anvil." Laser and Particle Beams 31, no. 1 (December 18, 2012): 73–79. http://dx.doi.org/10.1017/s0263034612000742.

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AbstractThis paper suggests a novel route to approach the cold compression curve in laser-plasma induced shock waves. This effect is achieved with a precompression in a diamond anvil cell (DAC). In order to keep the necessary structure of one dimensional shock wave it is required to use a diamond anvil cell with a partially perforated diamond anvil. Precompression pressures of about 50 GPa, that are an order of magnitude higher than the currently reported pressures, are possible to obtain with presentley existing diamond anvil cell technology. The precompressed Hugoniot of Al was calculated for different precompression pressures and it was found that at precompression pressure of 50 GPa the Hugoniot follows the “cold curve” up to about 2 Mbar and 5.2 g/cc. Furthermore, the thermal relative contribution on the Hugoniot curves is calculated.
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9

Skelton, E. F., A. W. Webb, M. W. Schaefer, D. Schiferl, A. I. Katz, H. D. Hochheimer, and S. B. Qadri. "X-Ray Diffraction Studies Under Non-Ambient Conditions: Application to Transition-Metal Dichalcogenide Solid Lubricants." Advances in X-ray Analysis 30 (1986): 465–71. http://dx.doi.org/10.1154/s0376030800021625.

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Анотація:
During the past quarter-century, the field of high pressure research has undergone a quiet revolution. This has resulted from the creation and development of the diamond-anvil cell (DAC). Because diamonds are the hardest known materials, the highest static pressures can be attained and indefinitely held in these devices, recent pressure records have surpassed 400 GPa.
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10

Dasenbrock-Gammon, Nathan, Raymond McBride, Gyeongjae Yoo, Sachith Dissanayake, and Ranga Dias. "Second harmonic AC calorimetry technique within a diamond anvil cell." Review of Scientific Instruments 93, no. 9 (September 1, 2022): 093901. http://dx.doi.org/10.1063/5.0104705.

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Анотація:
Tuning the energy density of matter at high pressures gives rise to exotic and often unprecedented properties, e.g., structural transitions, insulator–metal transitions, valence fluctuations, topological order, and the emergence of superconductivity. The study of specific heat has long been used to characterize these kinds of transitions, but their application to the diamond anvil cell (DAC) environment has proved challenging. Limited work has been done on the measurement of specific heat within DACs, in part due to the difficult experimental setup. To this end, we have developed a novel method for the measurement of specific heat within a DAC that is independent of the DAC design and is, therefore, readily compatible with any DACs already performing high pressure resistance measurements. As a proof-of-concept, specific heat measurements of the MgB2 superconductor were performed, showing a clear anomaly at the transition temperature ( T c), indicative of bulk superconductivity. This technique allows for specific heat measurements at higher pressures than previously possible.
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Дисертації з теми "Diamond Anvil Cell (DAC)"

1

Hadjikhani, Ali. "Raman Spectroscopy Study of Graphene Under High Pressure." FIU Digital Commons, 2012. http://digitalcommons.fiu.edu/etd/656.

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Due to its exceptional mechanical and electrical properties, graphene (one layer sheet of carbon atoms) has attracted a lot of attention since its discovery in 2004. The purpose of this research is to compare the Raman spectra of graphene with plasma treated graphene sheets which have been treated by changing the different parameters affecting the plasma treatment like gas flow, power and pressure and treatment time. The graphene we used for our high pressure studies are 4-5 layer CVD deposited graphene samples prepared by our collaborators in Dr. W. B. Choi’s group. First we report a Raman spectroscopy study of graphene on copper substrate at high pressures. Diamond anvil cell (DAC) was used to generate pressure. In situ Raman spectra were collected at pressures up to 10 GPa. The results indicate that the G band of graphene shifts with pressure significantly (about 5 cm-1/GPa) whereas the 2D band changes very little. The plasma treated samples were loaded into DAC. Raman spectrum was captured. Parts of the spectrum which were not related to the grapheme peak position were eliminated. The background was reduced. Peaks were found and fitted using FITYK software and the shift of each peak compared to its last position was observed when the pressure was increased. Next we studied plasma treated graphene samples treated with different partial pressure treatments under high pressure and compared them to each other using zirconia anvil cell with the same method.
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2

Begen, Burak. "INFLUENCE OF PRESSURE ON FAST DYNAMICS IN POLYMERS." University of Akron / OhioLINK, 2007. http://rave.ohiolink.edu/etdc/view?acc_num=akron1195437587.

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3

Dzyabura, Vasily. "Pathways to a Metallic Hydrogen." Thesis, Harvard University, 2013. http://dissertations.umi.com/gsas.harvard:10737.

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The primary subject of this thesis is the study of warm dense hydrogen by means of pulsed laser heating in the pressure region 1 to 2 Mbar and temperatures above the melting line, where a liquid-liquid phase transition from the insulating molecular fluid to a conducting atomic hydrogen fluid, so called plasma phase transition (PPT), was predicted to take place. The first evidence of the PPT under static compression is reported. The observations are in agreement with the negative slope phase line predicted by ab initio methods.
Physics
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4

Sly, Jonathan L. "High-pressure optical studies of III-V semiconductors using the diamond anvil cell." Thesis, University of Surrey, 1995. http://epubs.surrey.ac.uk/843077/.

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High pressure photoluminescence techniques have been used to investigate bulk and heterostructure properties in a number of III-V semiconductor materials systems. The results are reported in this thesis along with a description of the experimental procedures. The indirect band-gaps of a series of InxGa1-xSb/GaSb quantum-wells have been measured. The results have been extrapolated to zero indium content to give the indirect band-gaps of bulk GaSb; values quoted in the literature vary widely. We obtain results consistent with accepted values but cannot refine them due to experimental errors arising from using ruby as a pressure gauge. A development of the experimental technique is proposed which would eliminate this source of error. The low-temperature F and X band-gaps have been determined in bulk (AlxGa1-x)0.5In0.5P functions of composition; we obtain E8(T)=(1.985+0.61x)eV and E8(X)=(2.282+0.085x)eV respectively. Lower limits have been put on the position of the L minima in this system and 1% compressively strained Ga0.38,In0.62P. Band offsets have been determined in unstrained (y=0.5) and 1% (y=0.62) compressively strained Ga1-yInyP/(AlxGa1-x)0.5 In0.5P; we obtain Ev(meV)=63x+157x2 and Ec(meV)=547x-157x2 for the unstrained system and Ev(meV)=72+63x+157x2 and Ec(meV)=72+547x-157x2 for the strained system. Effects of atomic ordering on the conduction band of Ga0.5In0.5P have been investigated. An investigation of anomalous pressure coefficients in strained InxGa1-x As has been carried out. A strain-related reduction in pressure coefficients (similar to that reported for InxGa1-xAs/GaAs) is found in In0.67Ga0.33As/InGaAsP quantum-wells grown on [001] substrates, but not in InGaAs/GaAs grown on [111] substrates. Preliminary results from tensile samples show evidence of increased pressure coefficients. A new X-ray powder-diffraction technique is described for direct investigation of the elastic behaviour of strained InGaAs.
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5

Okuchi, Takuo, George D. Cody, Ho-kwang Mao, and Russell J. Hemley. "Hydrogen bonding and dynamics of methanol by high-pressure diamond-anvil cell NMR." American Institute of Physics, 2005. http://hdl.handle.net/2237/7067.

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6

Smith, D. "Hydrogenation of monolayer graphene in the diamond anvil cell and supercritical phenomena in methane." Thesis, University of Salford, 2016. http://usir.salford.ac.uk/38156/.

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Functionalisation with hydrogen could allow exploitation of the remarkable electronic properties of graphene by creating tuneable electronic band gaps as well as offering access to its incredibly high surface area-to-volume ratio for uses in advanced materials by opening pathways to conventional organic chemistry on the material. While partially-hydrogenated graphene is regularly produced and its properties studied, the current methods of producing the material – which typically employ bombarding graphene with atomised hydrogen – have not yet shown the potential to synthesise fully-hydrogenated graphene, termed graphane. This thesis describes an alternative method of hydrogenating graphene by heating the material in an atmosphere of molecular hydrogen under high pressure (2.6 – 6.5 GPa) in a diamond anvil cell. The hydrogen content of functionalised samples can be estimated by observing the Raman spectrum and such analysis suggests that the diamond anvil cell method currently hydrogenates samples to an extent that is competitive with existing methods. By tailoring the sample architecture to allow hydrogen direct access to both sides of a graphene crystal, it is feasible that the diamond anvil cell method of hydrogenation could be used to synthesise the first graphane crystal. Also presented in this thesis is a series of experiments probing methane in the supercritical region of its pressure-temperature phase diagram, combining Raman spectroscopy and direct structural measurements through X-ray diffraction. At 298K, we observe discontinuous changes in the vibrational Raman spectrum of methane which are not accompanied by a change in density. This phenomena may be explained by a crossing of the recently-theorised Frenkel line or by critical point proximity effects described by Widom in the 1960s. The Raman discontinuity is not observed at 523 K, suggesting that alternative methods must be employed to conclusively determine the presence (or absence) of the Frenkel line.
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7

Kondrat'yev, Andreiy I. "Finite element modeling and computer simulation of stresses and strains in diamond anvil cell devices." Birmingham, Ala. : University of Alabama at Birmingham, 2006. https://www.mhsl.uab.edu/dt/2008r/kondratyev.pdf.

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Анотація:
Thesis (Ph. D.)--University of Alabama at Birmingham, 2006.
Additional advisors: Heng Ban, Renato P. Camata, Krishan K. Chawla, Joseph G. Harrison. Description based on contents viewed Feb. 13, 2009; title from PDF t.p. Includes bibliographical references (p. 124-126).
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8

Nikitin, Sergey. "Laser ultrasonics in a diamond anvil cell for investigation of simple molecular compunds at ultrahigh pressures." Thesis, Le Mans, 2015. http://www.theses.fr/2015LEMA1005/document.

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Le travail que j’ai effectué durant ce doctorat est dédié à l’utilisation de l’ultrason des lasers sous haute pression physique. La recherche est construite en utilisant les récentes techniques de mesure de laser ultrasonique dans une enclume de diamant, conduisant à l’exploration de la propagation du son et de sa détermination suivant la vitesse de l’onde acoustique sous ultra-hautes pressions. La diffusion Brillouin a été appliquée ici pour déterminer l’épaisseur de la glace polycristalline compressée dans l’enclume à diamant sous pressions de mégabars. La technique permet d’examiner les caractéristiques des dimensions des inhomogénéités élastiques et la texture de la glace polycristalline, de ce fait ce processus est commun pour les surfaces de l’enclume à diamant avec des sous micromètres de résolution spatiale via les mesures des variations résolues dans le temps sur la vitesse de propagation du pouls acoustique voyageant dans l’échantillon compressé. Ceci a été appliqué pour mesurer la vitesse acoustique dans du H2O à l’état de glace jusqu’à 84 Gpa. La technique d’imagerie développée contient, pour chaque cristallite (ou groupe de cristallites) dans un ensemble homogène chimique transparent, des informations utiles sur son orientation ainsi que sur sa valeur élastique modulée par rapport à la direction de la propagation du son. Cela répand les bases pour une application réussite sur la déformation de solides sous haut-développement de modèles micromécaniques sous la pression à mégabars. Pour une plus longue durée, ce genre d’expériences répandus sur les minéraux de la terre et avec des températures basses ou hautes, assurerait un progrès important dans la compréhension de la construction de la cape terrestre, son évolution ainsi que celle d’autres planètes
This PhD research work is devoted to the use of laser ultrasound in high-pressure physics. The research is done using the recently established technique of laser ultrasonic measurements in a diamond anvil cell which allows investigation of the sound propagation and determination of the acoustic wave velocities at ultrahigh pressures. Time domain Brillouin scattering was applied here to depth-profiling of polycrystalline aggregate of ice compressed in a diamond anvil cell to megabar pressures. The technique allowed examination of characteristic dimensions of elastic inhomogeneities and texturing of polycrystalline ice in the direction, normal to the diamond anvil surfaces with sub-micrometer spatial resolution via time-resolved measurements of variations in the propagation velocity of the acoustic pulse travelling in the compressed sample. It was applied to measure the acoustic velocities in H2O ice up to 84 Gpa. The developed imaging technique provides, for each crystallite (or a group of crystallites) in chemically homogeneous transparent aggregate, usable information on its orientation as well as on the value of the elastic modulus along the direction of the sound propagation. This extends the basis for a successful application of highly developed micromechanical models of solids deformation at mbar pressure. On long term, such experiments extended to earth’s minerals and high or low temperatures would insure a significant progress in understanding of convection of the earth’s mantle and thus evolution of this and other planets
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9

Pigott, Jeffrey Scott. "Exploration of Earth's Deep Interior by Merging Nanotechnology, Diamond-Anvil Cell Experiments, and Computational Crystal Chemistry." The Ohio State University, 2015. http://rave.ohiolink.edu/etdc/view?acc_num=osu1435154850.

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Lord, Oliver T. "Experimental Constraints on the Chemistry of the Earth's Core : Novel approaches using the Laser-Heated Diamond Anvil Cell." Thesis, University of Bristol, 2009. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.520173.

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Книги з теми "Diamond Anvil Cell (DAC)"

1

Haselton, H. T. A control and data acquisition system for use with a hydrothermal diamond-anvil cell. Reston, VA: U.S. Dept. of the Interior, U.S. Geological Survey, 1994.

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2

T, Haselton H. A control and data acquisition system for use with a hydrothermal diamond-anvil cell. Reston, VA: U.S. Dept. of the Interior, U.S. Geological Survey, 1994.

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3

Ferraro, John R. Vibrational Spectroscopy at High External Pressures: The Diamond Anvil Cell. Elsevier Science & Technology Books, 2012.

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4

Sly, Jonathan L. High-pressure optical surdies of III-V semiconductors using the diamond anvil cell. 1995.

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Частини книг з теми "Diamond Anvil Cell (DAC)"

1

Halevy, Itzhak, Shlomo Haroush, Yosef Eisen, Ido Silberman, Dany Moreno, Amir Hen, Mike L. Winterrose, Sanjit Ghose, and Zhiqiang Chen. "Crystallographic and magnetic structure of HAVAR under high-pressure using diamond anvil cell (DAC)." In HFI / NQI 2010, 135–41. Dordrecht: Springer Netherlands, 2010. http://dx.doi.org/10.1007/978-94-007-1269-0_25.

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2

Dunstan, D. J. "Experimental Techniques in the Diamond Anvil Cell." In High Pressure Molecular Science, 87–101. Dordrecht: Springer Netherlands, 1999. http://dx.doi.org/10.1007/978-94-011-4669-2_5.

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3

Sweeney, Jeffrey S., and Dion L. Heinz. "Thermal Analysis in the Laser-heated Diamond Anvil Cell." In Experimental Techniques in Mineral and Rock Physics, 497–507. Basel: Birkhäuser Basel, 1993. http://dx.doi.org/10.1007/978-3-0348-5108-4_15.

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4

Merkel, Sebastien. "Radial Diffraction in the Diamond Anvil Cell: Methods and Applications." In NATO Science for Peace and Security Series B: Physics and Biophysics, 111–22. Dordrecht: Springer Netherlands, 2010. http://dx.doi.org/10.1007/978-90-481-9258-8_10.

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5

Ming, L. C., M. H. Manghnani, and J. Balogh. "Resistive heating in the diamond-anvil cell under vacuum conditions." In High‐Pressure Research in Mineral Physics: A Volume in Honor of Syun‐iti Akimoto, 69–74. Washington, D. C.: American Geophysical Union, 1987. http://dx.doi.org/10.1029/gm039p0069.

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6

Lorenz, Bernd, and Ingo Orgzall. "Kinetics of High Pressure Phase Transitions in the Diamond Anvil Cell." In NATO ASI Series, 243–51. Boston, MA: Springer US, 1991. http://dx.doi.org/10.1007/978-1-4899-2480-3_21.

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7

Sweeney, J. S., and D. L. Heinz. "Laser-heating through a diamond-anvil cell: Melting at high pressures." In Geophysical Monograph Series, 197–213. Washington, D. C.: American Geophysical Union, 1998. http://dx.doi.org/10.1029/gm101p0197.

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Boehler, R., M. Nicol, and M. L. Johnson. "Internally-heated diamond-anvil cell: Phase diagram and P-V-T of iron." In High‐Pressure Research in Mineral Physics: A Volume in Honor of Syun‐iti Akimoto, 173–76. Washington, D. C.: American Geophysical Union, 1987. http://dx.doi.org/10.1029/gm039p0173.

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9

Wu, T. C., and W. A. Bassett. "Deviatoric Stress in a Diamond Anvil Cell Using Synchrotron Radiation with Two Diffraction Geometries." In Experimental Techniques in Mineral and Rock Physics, 509–19. Basel: Birkhäuser Basel, 1993. http://dx.doi.org/10.1007/978-3-0348-5108-4_16.

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Obraztsova, E. D. "In situ Raman Investigations of Single-Wall Carbon Nanotubes Pressurized in Diamond Anvil Cell." In Frontiers of High Pressure Research II: Application of High Pressure to Low-Dimensional Novel Electronic Materials, 473–82. Dordrecht: Springer Netherlands, 2001. http://dx.doi.org/10.1007/978-94-010-0520-3_36.

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Тези доповідей конференцій з теми "Diamond Anvil Cell (DAC)"

1

Upadhyay, Anuj, Parasmani Rajput, and A. K. Sinha. "A XANES measurement set-up using Diamond Anvil Cell at BL-09, Indus-2 and demonstrative experiments." In DAE SOLID STATE PHYSICS SYMPOSIUM 2019. AIP Publishing, 2020. http://dx.doi.org/10.1063/5.0019282.

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2

Nakamura, Yuichi, Masanori Shimaoka, Yutaka Ishibashi, and Masahito Matsui. "Plastic Deformations of Micro-Spheres by Solidified Lubricants and Lubricants’ Shear Stress Under Very High Pressure." In World Tribology Congress III. ASMEDC, 2005. http://dx.doi.org/10.1115/wtc2005-63099.

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Анотація:
In order to grasp the possibility of evaluating shear properties for solidified lubricants under high pressure, plastic deformations of metal micro-spheres (about 0.07mm) in solidified lubricants were evaluated by employing a diamond-anvil pressure cell (DAC). Large deformations (2–5 times larger than the original sphere dimensions) were observed for CVT oil and ester oil up to 6 GPa at 23–25°C. Deformation starting pressure agreed with the solidified pressure. These deformations were caused by the non-hydrostatic pressure in the solidified lubricants. Shear stresses of the solidified lubricants were tentatively and roughly estimated from the plastic deformations of the spheres based on some assumptions. They almost agreed with the mean shear stress (traction force / hertzian contact area) from traction test.
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Sanjay Kumar, N. R., N. V. Chandra Shekar, and P. Ch Sahu. "Development of Nd-YAG laser heated diamond anvil cell facility and HPHT synthesis of WGe[sub 2]." In SOLID STATE PHYSICS: PROCEEDINGS OF THE 57TH DAE SOLID STATE PHYSICS SYMPOSIUM 2012. AIP, 2013. http://dx.doi.org/10.1063/1.4791117.

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4

Sorb, Y. A., N. Subramanian, T. R. Ravindran, and P. Ch Sahu. "Evidence for Ge-C bond formation at high P-T conditions in a laser heated diamond anvil cell." In SOLID STATE PHYSICS: Proceedings of the 56th DAE Solid State Physics Symposium 2011. AIP, 2012. http://dx.doi.org/10.1063/1.4709923.

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Sorb, Y. A., N. Subramanian, T. R. Ravindran, P. Ch Sahu, Alka B. Garg, R. Mittal, and R. Mukhopadhyay. "High Pressure in situ Micro-Raman Spectroscopy of Ge-Sn System Synthesized in a Laser Heated Diamond Anvil Cell." In SOLID STATE PHYSICS, PROCEEDINGS OF THE 55TH DAE SOLID STATE PHYSICS SYMPOSIUM 2010. AIP, 2011. http://dx.doi.org/10.1063/1.3606347.

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Hanna, Gabriel, Matthew D. McCluskey, Mark Elert, Michael D. Furnish, William W. Anderson, William G. Proud, and William T. Butler. "CONFOCAL MICROSCOPY TO MEASURE VOLUME IN A DIAMOND ANVIL CELL." In SHOCK COMPRESSION OF CONDENSED MATTER 2009: Proceedings of the American Physical Society Topical Group on Shock Compression of Condensed Matter. AIP, 2009. http://dx.doi.org/10.1063/1.3295039.

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Wang, Ruoheng, and I.-Ming Chou. "Oxygen fugacity control and measurement in hydrothermal diamond anvil cell." In Goldschmidt2022. France: European Association of Geochemistry, 2022. http://dx.doi.org/10.46427/gold2022.10961.

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Bowman, Richard W., Filippo Saglimbeni, Graham M. Gibson, Roberto Di Leonardo, and Miles J. Padgett. "Implementing optical tweezers at high pressure in a diamond anvil cell." In SPIE OPTO, edited by Jesper Glückstad, David L. Andrews, and Enrique J. Galvez. SPIE, 2013. http://dx.doi.org/10.1117/12.2015003.

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Laundy, David. "A Focusing Laue Monochromator Optimised for Diamond Anvil Cell Diffraction Experiments." In SYNCHROTRON RADIATION INSTRUMENTATION: Eighth International Conference on Synchrotron Radiation Instrumentation. AIP, 2004. http://dx.doi.org/10.1063/1.1757888.

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Duffy, T. S., Mark Elert, Michael D. Furnish, Ricky Chau, Neil Holmes, and Jeffrey Nguyen. "STRENGTH OF MATERIALS UNDER STATIC LOADING IN THE DIAMOND ANVIL CELL." In SHOCK COMPRESSION OF CONDENSED MATTER - 2007: Proceedings of the Conference of the American Physical Society Topical Group on Shock Compression of Condensed Matter. AIP, 2008. http://dx.doi.org/10.1063/1.2833175.

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Звіти організацій з теми "Diamond Anvil Cell (DAC)"

1

Jenei, Z. Investigation of Ultrahigh-Pressure Phase Transitions in Metals with a Toroidal Diamond Anvil Cell. Office of Scientific and Technical Information (OSTI), October 2019. http://dx.doi.org/10.2172/1573173.

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