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Published: 30 May 2022
Last updated: 31 May 2022

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1

Efremovich, Zaikov Gennadiĭ, ed. Structure of the polymer amorphous state. Utrecht: VSP, 2004.

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2

Mossotti, V. G. Short-range physicochemical structure of amorphous aluminosilicates. [Denver, Colo.?]: Dept. of the Interior, U.S. Geological Survey, 1987.

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3

Mossotti, V. G. Short-range physicochemical structure of amorphous aluminosilicates. [Denver, Colo.?]: Dept. of the Interior, U.S. Geological Survey, 1987.

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4

Mossotti, V. G. Short-range physicochemical structure of amorphous aluminosilicates. [Denver, Colo.?]: Dept. of the Interior, U.S. Geological Survey, 1987.

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5

Overhof, H. Electronic transport in hydrogenated amorphous semiconductors. Berlin: Springer-Verlag, 1989.

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6

International Symposium on Structure and Bonding in Noncrystalline Solids (1983 Reston, Va.). Structure and bonding in noncrystalline solids. New York: Plenum Press, 1986.

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7

Šesták, Jaroslav. Glassy, Amorphous and Nano-Crystalline Materials: Thermal Physics, Analysis, Structure and Properties. Dordrecht: Springer Science+Business Media B.V., 2011.

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8

Sapelkin, Andrei V. Structure of and phase transformations in bulk amorphous (GaSb)1-x(Ge2)x. Leicester: De Montfort University, 1998.

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9

1945-, Švec Petr, Idzikowski Bogdan, Miglierini Marcel, and North Atlantic Treaty Organization. Scientific Affairs Division., eds. Properties and applications of nanocrystalline alloys from amorphous precursors. Dordrecht: Kluwer Academic Publishers, 2005.

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10

Karolus, Małgorzata. Rentgenowska metoda badania struktury materiałów amorficznych i nanokrystalicznych. Katowice: Uniwersytet Śląski, 2011.

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11

1962-, Zhukova Valentina, ed. Magnetic properties and applications of ferromagnetic microwires with amorpheous and nanocrystalline structure. Hauppauge, NY: Nova Science Publishers, 2009.

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12

Born, R. Ab initio calculations of conformational effects on ¹³C NMR spectra of amorphous polymers. Berlin: Springer, 1997.

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13

Tiberto, Paola, and Franco Vinai. Magnetic amorphous alloys: Structural, magnetic and transport properties. Trivandrum, India: Research Signpost, 2003.

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14

Wijn, H. P. J., ed. Perovskites II, Oxides with Corundum, Ilmenite and Amorphous Structures. Berlin/Heidelberg: Springer-Verlag, 1994. http://dx.doi.org/10.1007/b54938.

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15

Workshop on Structure and Electronic Properties of Amorphous Superconductor Superlattices (1988 University of Tokyo). Workshop on Structural and Electronic Properties of Amorphous Superconductor Superlattices. London: Taylor & Francis, 1989.

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16

Szurmak, Joanna. A study of the structural, optical and electrical properties of nitrogen-doped hydrogenated amorphous carbon. Ottawa: National Library of Canada, 1998.

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17

1953-, Tant Martin R., Hill Anita J, American Chemical Society. Division of Polymeric Materials: Science and Engineering., and American Chemical Society Meeting, eds. Structure and properties of glassy polymers. Washington, DC: American Chemical Society, 1998.

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18

Geological Survey (U.S.), ed. Short-range physicochemical structure of amorphous aluminosilicates. [Denver, Colo.?]: Dept. of the Interior, U.S. Geological Survey, 1987.

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19

Geological Survey (U.S.), ed. Short-range physicochemical structure of amorphous aluminosilicates. [Denver, Colo.?]: Dept. of the Interior, U.S. Geological Survey, 1987.

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20

Stachurski, Zbigniew H. Fundamentals of Amorphous Solids: Structure and Properties. Wiley & Sons, Incorporated, John, 2014.

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21

Stachurski, Zbigniew H. Fundamentals of Amorphous Solids: Structure and Properties. Wiley & Sons, Incorporated, John, 2015.

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22

Stachurski, Zbigniew H. Fundamentals of Amorphous Solids: Structure and Properties. Wiley & Sons, Limited, John, 2015.

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23

B, Devine Roderick A., Duraud J. -P, and Dooryhée E, eds. Structure and imperfections in amorphous and crystalline SiO₂. Chichester: Wiley, 2000.

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24

R. A. B. Devine (Editor), J. P. Duraud (Editor), and E. Dooryhée (Editor), eds. Structure and Imperfections in Amorphous and Crystalline Silicon Dioxide. Wiley, 2000.

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25

Structure and Bonding in Noncrystalline Solids. Springer, 1986.

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26

Schultrich, Bernd. Tetrahedrally Bonded Amorphous Carbon Films I: Basics, Structure and Preparation. Springer, 2018.

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27

Schultrich, Bernd. Tetrahedrally Bonded Amorphous Carbon Films I: Basics, Structure and Preparation. Springer, 2019.

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28

(Editor), Y. Kawazoe, and Y. Waseda (Editor), eds. Structure and Properties of Aperiodic Materials (Advances in Materials Research). Springer, 2003.

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29

Zhang, Bangwei. Amorphous and Nano Alloys Electroless Depositions: Technology, Composition, Structure and Theory. Elsevier Science & Technology Books, 2015.

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30

(Editor), Phillipe Jund, and Remi Jullien (Editor), eds. Physics of Glasses: Structure and Dynamics: Cargese, Corsica, France, May 10-22, 1999 (AIP Conference Proceedings). American Institute of Physics, 1999.

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31

Šesták, Jaroslav, Pavel Hubík, and Jiří J. Mareš. Glassy, Amorphous and Nano-Crystalline Materials: Thermal Physics, Analysis, Structure and Properties. Springer, 2012.

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32

(Editor), Bogdan Idzikowski, Peter Svec (Editor), and Marcel Miglierini (Editor), eds. Properties and Applications of Nanocrystalline Alloys from Amorphous Precursors. Springer, 2005.

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33

J, Roe R., O'Reilly James M. 1934-, E.I. du Pont de Nemours & Company., and Materials Research Society, eds. Structure, relaxation, and physical aging of glassy polymers: Symposium held November 28-30, 1990, Boston, Massachusetts, U.S.A. Pittsburgh, Pa: Materials Research Society, 1991.

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34

K, Srivastava S., INDIAS (Allahabad, India : Organization), D.A. University, Indore, India., and International Conference on Disordered Materials (1st : 1991 : Indore, India), eds. Disordered materials: Structure and properties : proceedings of the International Conference, INDIAS-91 held at D.A. University, Indore, India, from 3-6 February 1991. Allahabad: INDIAS Publications, 1993.

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35

I, Kochubeĭ D., Zhidomirov G. M, and Institut kataliza (Akademii͡a︡ nauk SSSR), eds. Rentgenospektralʹnyĭ metod izuchenii͡a︡ struktury amorfnykh tel: EXAFS-spektroskopii͡a︡. Novosibirsk: "Nauka," Sibirskoe otd-nie, 1988.

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36

Sagnes, Emmanuel. Influence of DC saddle-field discharge deposition parameters on the structure of hydrogenated amorphous carbon semiconductor. 1998.

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37

Schulze, Dietrich, Prof. Dr. habil. and Becherer Gerhard, eds. Amorphous structures: Methods and results. Berlin: Akademie-Verlag, 1990.

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38

Bi, J. F., and K. L. Teo. Nanoscale Ge1−xMnxTe ferromagnetic semiconductors. Edited by A. V. Narlikar and Y. Y. Fu. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533053.013.17.

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This article discusses the structure characterizations, magnetic and transport behaviors of the nanoscale ferromagnetic semiconductors Ge1-xMnxTe grown by molecular beam epitaxy with various manganese compositions x ranging from 0.14 to 0.98. After providing an overview of the growth procedure and characterization, the article analyzes the structures of the Ge1-xMnxTe system using X-ray diffraction and high-resolution transmission electron microscopy. It then considers the optical, magnetic and transport properties of the semiconductors and shows that the crystal quality is degraded and the proportion of amorphous phase increases with increasing Mn composition. Nanoclusters and nanoscale grains can be observed when x > 0.24, which greatly affect their magnetic and electronic properties. The magnetic anisotropy is weakened due to different orientations of the clusters embedded in the GeTe host. An anomalous Hall effect is also observed in the samples, which can be attributed to extrinsic skew scattering.
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39

H, Francombe Maurice, ed. Non-crystalline films for device structures. San Diego: Acadmic Press, 2002.

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40

Kokubo, N., S. Okayasu, and K. Kadowaki. Multi-Vortex States in Mesoscopic Superconductors. Edited by A. V. Narlikar. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780198738169.013.3.

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This article investigates multi-vortex states in mesoscopic amorphous superconductors with different geometries by means of scanning SQUID microscopy. It first describes the setup of the scanning SQUID microscope used in magnetic imaging of superconducting vortices before discussing the physical properties of amorphous superconducting thin films. It then presents the results of experiments showing the formation of multi-vortex states in mesoscopic dots of weak pinning, amorphous MoGe thin films, along with the formation of vortex polygons and concentric vortex rings in mesoscopic disks. It also considers the concept of multiple vortex shells and its applicability to vortex patterns observed in mesoscopic circle and square dots. The article highlights some of the key features of mesoscopic superconducting dots, including commensurability effect, multiple shell structures, repeated packing sequences, inclusion structural hierarchy, and pinning effect.
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41

Amorphous Semiconductors: Structural, Optical, and Electronic Properties. Wiley, 2017.

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42

Francombe, Maurice. Non-crystalline Films for Device Structures Volume 29 (Thin Films Series). Academic Press, 2001.

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43

Janssen, Ted, Gervais Chapuis, and Marc de Boissieu. Aperiodic Crystals. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198824442.001.0001.

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Until the 1970s all materials studied consisted of periodic arrays of unit cells, or were amorphous. In the following decades a new class of solid state matter, called aperiodic crystals, has been found. It is a long-range ordered structure, but without lattice periodicity. It is found in a wide range of materials: organic and inorganic compounds, minerals (including a substantial portion of the earth’s crust), and metallic alloys, under various pressures and temperatures. Because of the lack of periodicity the usual techniques for the study of structure and physical properties no longer work, and new techniques have to be developed. This book deals with the characterization of the structure, the structure determination, and the study of the physical properties, especially the dynamical and electronic properties of aperiodic crystals. The treatment is based on a description in a space with more dimensions than three, the so-called superspace. This allows us to generalize the standard crystallography and to look differently at the dynamics. The three main classes of aperiodic crystals, modulated phases, incommensurate composites, and quasicrystals are treated from a unified point of view which stresses the similarities of the various systems. The book assumes as a prerequisite a knowledge of the fundamental techniques of crystallography and the theory of condensed matter, and covers the literature at the forefront of the field.
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44

Manage, Dammika P. Structural and optical characterization of hydrogenated amorphous carbon thin films. 1998.

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45

S, Arzhakov M., Arzhakov S. A, and Zaikov Gennadiĭ Efremovich, eds. Structural and mechanical behavior of glassy polymers. Commack, N.Y: Nova Science Publishers, 1997.

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46

Wijn, H. P. J., G. Srinivasan, Y. Endoh, M. S. Seehra, K. Kakurai, and A. K. Katori. Perovskites II, Oxides with Corundum, Ilmenite and Amorphous Structures (Numerical Data & Functional Relationships in Science & Technology). Springer, 1994.

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47

(Editor), Bryant W. Rossiter, and John F. Hamilton (Editor), eds. Physical Methods of Chemistry, Volume 5: Determination of Structural Features of Crystalline and Amorphous Solids. Second Edition. 2nd ed. John Wiley & Sons, 1990.

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48

Shore, Bradd, and Sara Kauko. The Landscape of Family Memory. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780190230814.003.0005.

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How do families remember? How are families remembered? How are family memories structured, and what functions do they serve? “Family memory” as a focus of historical, sociological, and anthropological research often finds itself situated in the amorphous space that lies between autobiographical memory and collective memory. Reviewing memory literature that investigates family memory, this chapter proposes that family memory can be distinguished as its own realm for specific memory production, modes of remembering, and mnemonic transmission. Primordial in shaping families’ identities, family memory engages constant dialogue between the family understood as a collective unit and the family understood as a collection of remembering individuals. This chapter examines how family memory shapes individual identities; how it is organized around specific narratives, places and objects, and routines and rituals; and how it persists and evolves over time through intrafamilial and intergenerational transmission.
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49

Tiwari, Sandip. Phase transitions and their devices. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780198759874.003.0004.

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Phase transitions as a collective response of an ensemble, with appearance of unique stable properties spontaneously, is critical to a variety of devices: electronic, magnetic, optical, and their coupled forms. This chapter starts with a discussion of broken symmetry and its manifestation in the property changes in thermodynamic phase transition and the Landau mean-field articulation. It then follows it with an exploration of different phenomena and their use in devices. The first is ferroelectricity—spontaneous electric polarization—and its use in ferroelectric memories. Electron correlation effects are explored, and then conductivity transition from electron-electron and electron-phonon coupling and its use in novel memory and device forms. This is followed by development of an understanding of spin correlations and interactions and magnetism—spontaneous magnetic polarization. The use and manipulation of the magnetic phase transition in disk drives, magnetic and spin-torque memory as well as their stability is explored. Finally, as a fourth example, amorphous-crystalline structural transition in optical, electronic, and optoelectronic form are analyzed. This latter’s application include disk drives and resistive memories in the form of phase-change as well as those with electochemical transport.
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50

Giddens, Thomas, ed. Critical Directions in Comics Studies. University Press of Mississippi, 2020. http://dx.doi.org/10.14325/mississippi/9781496828996.001.0001.

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Recent decades have seen a blossoming of academic and scholarly concern with comics. Within the ecosystems of this growth, dominant assumptions have taken root—assumptions around the particular methods and approaches used to approach the comics form, around the ways we should read comics, how its ‘system’ works, and the disciplinary relationships that surround this evolving area of study. But other perspectives have also begun to flourish amidst this verdant landscape of comics studies. These approaches seek to question the reliance on structural linguistics and the tools of English and cultural studies in the examination and understanding of comics. They turn instead to politics, to aesthetics, to law, to critical theory. This collection seeks to grow, and to grow within those more critical directions in comics studies; to fertilize and help sustain them, to multiply them, and continue to cultivate a healthy skepticism, creativity, and openness in the approach to comics knowledge. Accordingly, this volume contains a collection of indicative and provocative essays, accumulated and compiled for readers to explore and make meaning out of: to get lost in, and hopefully find new and enriching directions forward in their encounters with the rich possibilities that comics enable. Traversing phenomenological, existential, material, legal, contextual, political, and revolutionary meanings in their engagements with both comics form and examples of comics work, and interspersed with critical comics interludes, these essays seek to consolidate, exemplify, and open up potential futures for the fecund and amorphous fields of critical comics studies.
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