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Journal articles on the topic 'Nanoglass'

Author: Grafiati
Published: 6 September 2023

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1

Chen, Na, Di Wang, Tao Feng, Robert Kruk, Ke-Fu Yao, Dmitri V. Louzguine-Luzgin, Horst Hahn, and Herbert Gleiter. "A nanoglass alloying immiscible Fe and Cu at the nanoscale." Nanoscale 7, no. 15 (2015): 6607–11. http://dx.doi.org/10.1039/c5nr01406a.

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Synthesized from ultrafine particles with a bottom-up approach, nanoglasses are of particular importance in pursuing unique properties. From different kinds of nanoglasses with immiscible metals, nanoglass alloys are created, which may open an avenue to an entirely new world of solid solutions. These new solid solutions are likely to have properties that are yet unknown in today's alloys.
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2

Gleiter, Herbert. "Nanoglasses: a new kind of noncrystalline materials." Beilstein Journal of Nanotechnology 4 (September 13, 2013): 517–33. http://dx.doi.org/10.3762/bjnano.4.61.

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Nanoglasses are a new class of noncrystalline solids. They differ from today’s glasses due to their microstructure that resembles the microstructure of polycrystals. They consist of regions with a melt-quenched glassy structure connected by interfacial regions, the structure of which is characterized (in comparison to the corresponding melt-quenched glass) by (1) a reduced (up to about 10%) density, (2) a reduced (up to about 20%) number of nearest-neighbor atoms and (3) a different electronic structure. Due to their new kind of atomic and electronic structure, the properties of nanoglasses may be modified by (1) controlling the size of the glassy regions (i.e., the volume fraction of the interfacial regions) and/or (2) by varying their chemical composition. Nanoglasses exhibit new properties, e.g., a Fe90Sc10 nanoglass is (at 300 K) a strong ferromagnet whereas the corresponding melt-quenched glass is paramagnetic. Moreover, nanoglasses were noted to be more ductile, more biocompatible, and catalytically more active than the corresponding melt-quenched glasses. Hence, this new class of noncrystalline materials may open the way to technologies utilizing the new properties.
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3

Abaza, Engy Fahmy, Ahmed Abbas Zaki, Haytham Samir Moharram, Amal Alaa El Din El Batouti, and Asmaa Aly Yassen. "Influence of gamma radiation on microshear bond strength and nanoleakage of nanofilled restoratives in Er, Cr:YSGG laser-prepared cavities." European Journal of Dentistry 12, no. 03 (July 2018): 338–43. http://dx.doi.org/10.4103/ejd.ejd_305_17.

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ABSTRACT Objective: To evaluate the effect of gamma radiation on microshear bond strength and nanoleakage of nanofilled restoratives in laser-prepared cavities. Materials and Methods: Twenty-eight flat buccal dentin surfaces were prepared for microshear bond strength test. Er, Cr:YSGG laser was used to prepare another 28 Class V cavities on the buccal surfaces of the molars. All teeth were divided into four groups; 1st group: Application of Filtek Z350 nanocomposite material, 2nd group: As the 1st group and then exposure to gamma radiation, 3rd group: Application of Ketac N100 nanoglass ionomer, and the 4th group: As the 3rd group and then gamma irradiated. The bond strength test was performed after storage in artificial saliva for 24 h. For the nanoleakage test, teeth were submerged in a solution of ammoniacal silver nitrate, sectioned, and then examined under a scanning electron microscope. The collected data were statistically analyzed. Results: Nanocomposite showed higher bond strength values than nanoglass ionomer. Despite the fact that gamma radiation did not decrease nanocomposite bond strength, it decreased nanoglass ionomer bond strength. Nanoglass ionomer-restored cavities showed higher silver ion penetration than nanocomposite in both control and gamma-irradiated groups. Conclusion: Gamma radiation has no effect on bond strength and nanoleakage of nanocomposite so that it can be placed before radiotherapy. On the other hand, the bond strength of nanoglass ionomer was adversely affected by gamma radiation.
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4

Sahar, Md Rahim, and S. K. Ghoshal. "Nanoglass: Present Challenges and Future Promises." Advanced Materials Research 1108 (June 2015): 45–58. http://dx.doi.org/10.4028/www.scientific.net/amr.1108.45.

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This presentation provides a panoramic overview of the recent progress in nanoglass plasmonics, challenges, excitement, applied interests and the future promises. A glimpse of our gamut research activities with some significant results is highlighted and facilely analyzed. The term'nanoglass'refers to the science and technology dealing with the manipulation of the physical properties of rare earth doped inorganic glasses by embedding metallic nanoparticles (NPs) or nanoclusters. On the other hand, the word'plasmonics'refer to the coherent coupling of photons to free electron oscillations (called plasmon) at the interface between a conductor and a dielectric. Nanoglass plasmonis being an emerging concept in advanced optical material of nanophotonics has given photonics the ability to exploit the optical response at nanoscale and opened up a new avenue in metal-based glass optics. There is a vast array of nanoglass plasmonic concepts yet to be explored, with applications spanning solar cells, (bio) sensing, communications, lasers, solid-state lighting, waveguides, imaging, optical data transfer, display and even bio-medicine. Localized surface plasmon resonance (LSPR) can enhance the optical response of nanoglass by orders of magnitude as observed. The luminescence enhancement and surface enhanced Raman scattering (SERS) are new paradigm of research. A thumbnail sketch of the fundamental aspects of SPR, LSPR, SERS and photonic applications of various rare earth doped/co-doped binary glasses containing metallic NPs are presented. The recent development in nanoglass in the context of Malaysia at the outset of international scenario is projected.
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Sha, Z. D., L. C. He, Q. X. Pei, Z. S. Liu, Y. W. Zhang, and T. J. Wang. "The mechanical properties of a nanoglass/metallic glass/nanoglass sandwich structure." Scripta Materialia 83 (July 2014): 37–40. http://dx.doi.org/10.1016/j.scriptamat.2014.04.009.

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6

Sha, Z. D., P. S. Branicio, Q. X. Pei, Z. S. Liu, H. P. Lee, T. E. Tay, and T. J. Wang. "Strong and superplastic nanoglass." Nanoscale 7, no. 41 (2015): 17404–9. http://dx.doi.org/10.1039/c5nr04740d.

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7

Danilov, Denis, Horst Hahn, Herbert Gleiter, and Wolfgang Wenzel. "Mechanisms of Nanoglass Ultrastability." ACS Nano 10, no. 3 (February 17, 2016): 3241–47. http://dx.doi.org/10.1021/acsnano.5b05897.

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8

Salman, Awham Jumah, Zahraa Fakhri Jawad, Rusul Jaber Ghayyib, Fadhaa Atheer Kareem, and Zainab Al-khafaji. "Verification of Utilizing Nanowaste (Glass Waste and Fly Ash) as an Alternative to Nanosilica in Epoxy." Energies 15, no. 18 (September 18, 2022): 6808. http://dx.doi.org/10.3390/en15186808.

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Silica is considered one of the most prevalent components in the Earth’s shell and is synthesized for use in technological applications. Nevertheless, new methods for finding a better, cheaper, and more ecologically friendly supply of silica with less energy consumption are unavoidable. This study investigates whether nanopowders made from waste with a great silica amount (fly ash and glass) can be utilized as fillers in an epoxy glue to enhance its characteristics. Four different contents (5, 10, 15, and 20 wt%) of nano–fly ash, nanoglass, and nanosilica powder were introduced into the samples. Fourier transform infrared analysis, differential scanning calorimetry analysis, viscosity testing, and microhardness testing were conducted for nanoglass/epoxy and nano–fly ash/epoxy samples, which were compared with the silica/epoxy samples. Results indicated that the nanoglass and nano–fly ash powder have the same impact as nanosilica on the characteristics of epoxy. The hardness and viscosity of epoxy increased with the increase in the added filler. At 20 wt%, the hardness value of the nanoglass/epoxy composites was greater than that of the nanosilica/epoxy and fly ash/epoxy composites by about 15% and 7%, respectively. The results also indicated that the highest viscosity values were obtained when using nano–fly ash powder of 20 wt%. Furthermore, the modification of the epoxy by the nanoparticles had no significant effect on the values of the glass transition temperatures.
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9

Śniadecki, Z., D. Wang, Yu Ivanisenko, V. S. K. Chakravadhanula, C. Kübel, H. Hahn, and H. Gleiter. "Nanoscale morphology of Ni50Ti45Cu5 nanoglass." Materials Characterization 113 (March 2016): 26–33. http://dx.doi.org/10.1016/j.matchar.2015.12.025.

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10

Zhou, Peng, Qiaomin Li, Pan Gong, Xinyun Wang, and Mao Zhang. "Electrodeposition of FeCoP nanoglass films." Microelectronic Engineering 229 (May 2020): 111363. http://dx.doi.org/10.1016/j.mee.2020.111363.

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11

Kumar, Gideon Praveen, Suyue Yuan, Fangsen Cui, Paulo Sergio Branicio, and Mehdi Jafary‐Zadeh. "Nanoglass‐based balloon expandable stents." Journal of Biomedical Materials Research Part B: Applied Biomaterials 108, no. 1 (March 20, 2019): 73–79. http://dx.doi.org/10.1002/jbm.b.34367.

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12

Ghosh, Arnab, Milon Miah, Chinmoy Majumder, Shekhar Bag, Dipankar Chakravorty, and Shyamal Kumar Saha. "Synthesis of multilayered structure of nano-dimensional silica glass/reduced graphene oxide for advanced electrochemical applications." Nanoscale 10, no. 12 (2018): 5539–49. http://dx.doi.org/10.1039/c8nr00852c.

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13

Nandam, Sree Harsha, Ruth Schwaiger, Aaron Kobler, Christian Kübel, Chaomin Wang, Yulia Ivanisenko, and Horst Hahn. "Controlling shear band instability by nanoscale heterogeneities in metallic nanoglasses." Journal of Materials Research 36, no. 14 (July 8, 2021): 2903–14. http://dx.doi.org/10.1557/s43578-021-00285-4.

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Abstract Strain localization during plastic deformation drastically reduces the shear band stability in metallic glasses, ultimately leading to catastrophic failure. Therefore, improving the plasticity of metallic glasses has been a long-standing goal for several decades. In this regard, nanoglass, a novel type of metallic glass, has been proposed to exhibit differences in short and medium range order at the interfacial regions, which could promote the formation of shear transformation zones. In the present work, by introducing heterogeneities at the nanoscale, both crystalline and amorphous, significant improvements in plasticity are realized in micro-compression tests. Both amorphous and crystalline dispersions resulted in smaller strain bursts during plastic deformation. The yield strength is found to increase significantly in Cu–Zr nanoglasses compared to the corresponding conventional metallic glasses. The reasons for the mechanical behavior and the importance of nanoscale dispersions to tailor the properties is discussed in detail. Graphic Abstract
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14

Zhao, Peng, Huang, Yang, Hu, and Wang. "Super Ductility of Nanoglass Aluminium Nitride." Nanomaterials 9, no. 11 (October 29, 2019): 1535. http://dx.doi.org/10.3390/nano9111535.

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Ceramics have been widely used in many fields because of their distinctive properties, however, brittle fracture usually limits their application. To solve this problem, nanoglass ceramics were developed. In this article, we numerically investigated the mechanical properties of nanoglass aluminium nitride (ng-AlN) with different glassy grain sizes under tension using molecular dynamics simulations. It was found that ng-AlN exhibits super ductility and tends to deform uniformly without the formation of voids as the glassy grain size decreases to about 1 nm, which was attributed to a large number of uniformly distributed shear transformation zones (STZs). We further investigated the effects of temperature and strain rate on ng-AlNd = 1 nm, which showed that temperature insignificantly influences the elastic modulus, while the dependence of the ultimate strength on temperature follows the T2/3 scaling law. Meanwhile, the ultimate strength of ng-AlNd = 1 nm is positively correlated with the strain rate, following a power function relationship.
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15

Bag, Soumabha, Ananya Baksi, Sree Harsha Nandam, Di Wang, Xinglong Ye, Jyotirmoy Ghosh, Thalappil Pradeep, and Horst Hahn. "Nonenzymatic Glucose Sensing Using Ni60Nb40 Nanoglass." ACS Nano 14, no. 5 (April 8, 2020): 5543–52. http://dx.doi.org/10.1021/acsnano.9b09778.

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16

Wang, Xiao Lei, Feng Jiang, Horst Hahn, Ju Li, Herbert Gleiter, Jun Sun, and Ji Xiang Fang. "Plasticity of a scandium-based nanoglass." Scripta Materialia 98 (March 2015): 40–43. http://dx.doi.org/10.1016/j.scriptamat.2014.11.010.

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17

Şopu, Daniel, and Karsten Albe. "Influence of grain size and composition, topology and excess free volume on the deformation behavior of Cu–Zr nanoglasses." Beilstein Journal of Nanotechnology 6 (February 24, 2015): 537–45. http://dx.doi.org/10.3762/bjnano.6.56.

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The influence of grain size and composition on the mechanical properties of Cu–Zr nanoglasses (NGs) is investigated by molecular dynamics simulations using two model glasses of different alloy composition, namely Cu64Zr36 (Cu-rich) and Cu36Zr64 (Zr-rich). When the grain size is increased, or the fraction of interfaces in these NGs is decreased, we find a transition from a homogeneous to an inhomogeneous plastic deformation, because the softer interfaces are promoting the formation shear transformation zones. In case of the Cu-rich system, shear localization at the interfaces is most pronounced, since both the topological order and free volume content of the interfaces are very different from the bulk phase. After thermal treatment the redistribution of free volume leads to a more homogenous deformation behavior. The deformation behavior of the softer Zr-rich nanoglass, in contrast, is only weakly affected by the presence of glass–glass interfaces, since the interfaces don’t show topological disorder. Our results provide clear evidence that the mechanical properties of metallic NGs can be systematically tuned by controlling the size and the chemical composition of the glassy nanograins.
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18

Chatterjee, Soumi, Ramaprasad Maiti, Shyamal Kumar Saha, and Dipankar Chakravorty. "Enhancement of electrical conductivity in CoO-SiO2 nanoglasses and large magnetodielectric effect in ZnO-nanoglass composites." Journal of Applied Physics 117, no. 17 (May 7, 2015): 174303. http://dx.doi.org/10.1063/1.4919418.

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19

Sha, Z. D., L. C. He, Q. X. Pei, H. Pan, Z. S. Liu, Y. W. Zhang, and T. J. Wang. "On the notch sensitivity of CuZr nanoglass." Journal of Applied Physics 115, no. 16 (April 28, 2014): 163507. http://dx.doi.org/10.1063/1.4873238.

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20

Liu, Yang, Zhenhua Gao, Weiguang Zhang, Xun Sun, Zifei Wang, Xue Wang, Baoyuan Xu, and Xiangeng Meng. "Stimulated emission from CsPbBr3 quantum dot nanoglass." Optical Materials Express 9, no. 8 (July 17, 2019): 3390. http://dx.doi.org/10.1364/ome.9.003390.

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21

Yao, Li, and Zhao-Hui Jin. "Stagnation accommodated global plasticity in nanoglass composites." Scripta Materialia 106 (September 2015): 46–51. http://dx.doi.org/10.1016/j.scriptamat.2015.05.002.

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22

Adibi, Sara, Paulo S. Branicio, and Roberto Ballarini. "Compromising high strength and ductility in nanoglass–metallic glass nanolaminates." RSC Advances 6, no. 16 (2016): 13548–53. http://dx.doi.org/10.1039/c5ra24715b.

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Large-scale molecular-dynamics simulations are used to investigate the mechanical properties of 50 nm diameter Cu64Zr36 nanolaminate nanopillars constructed from 5 nm thick layers of metallic glass (MG) or MG and 5 nm grain sized nanoglass.
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23

Wu, Kaiyao, Fei Chu, Yuying Meng, Kaveh Edalati, Qingsheng Gao, Wei Li, and Huai-Jun Lin. "Cathodic corrosion activated Fe-based nanoglass as a highly active and stable oxygen evolution catalyst for water splitting." Journal of Materials Chemistry A 9, no. 20 (2021): 12152–60. http://dx.doi.org/10.1039/d1ta00769f.

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A new Fe78Si9B13 nanoglass covered by in situ formed FeOOH as an OER catalyst for water splitting. Overpotential is only 240 mV at 10 mA cm−1 in 1 M KOH, and the Tafel slope is 42 mV dec−1.
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24

Fandzloch, Marzena, Weronika Bodylska, Katarzyna Roszek, Katarzyna Halubek-Gluchowska, Anna Jaromin, Yuriy Gerasymchuk, and Anna Lukowiak. "Solvothermally-derived nanoglass as a highly bioactive material." Nanoscale 14, no. 14 (2022): 5514–28. http://dx.doi.org/10.1039/d1nr05984j.

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25

Ghafari, M., X. Mu, J. Bednarcik, W. D. Hutchison, H. Gleiter, and S. J. Campbell. "Magnetic properties of iron clusters in Sc75Fe25 nanoglass." Journal of Magnetism and Magnetic Materials 494 (January 2020): 165819. http://dx.doi.org/10.1016/j.jmmm.2019.165819.

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26

Baksi, Ananya, Sree Harsha Nandam, Di Wang, Robert Kruk, Mohammed Reda Chellali, Julia Ivanisenko, Isabella Gallino, Horst Hahn, and Soumabha Bag. "Ni60Nb40 Nanoglass for Tunable Magnetism and Methanol Oxidation." ACS Applied Nano Materials 3, no. 7 (June 11, 2020): 7252–59. http://dx.doi.org/10.1021/acsanm.0c01584.

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27

Singh, Shiv Prakash, Ralf Witte, Oliver Clemens, Abhishek Sarkar, Leonardo Velasco, Robert Kruk, and Horst Hahn. "Magnetic Tb75Fe25 Nanoglass for Cryogenic Permanent Magnet Undulator." ACS Applied Nano Materials 3, no. 7 (June 23, 2020): 7281–90. http://dx.doi.org/10.1021/acsanm.0c01674.

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28

Ghafari, M., H. Hahn, H. Gleiter, Y. Sakurai, M. Itou, and S. Kamali. "Evidence of itinerant magnetism in a metallic nanoglass." Applied Physics Letters 101, no. 24 (December 10, 2012): 243104. http://dx.doi.org/10.1063/1.4769816.

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29

Guo, Chunyu, Yini Fang, Bin Wu, Si Lan, Guo Peng, Xun-li Wang, Horst Hahn, Herbert Gleiter, and Tao Feng. "Ni-P nanoglass prepared by multi-phase pulsed electrodeposition." Materials Research Letters 5, no. 5 (December 12, 2016): 293–99. http://dx.doi.org/10.1080/21663831.2016.1264495.

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30

Witte, R., T. Feng, J. X. Fang, A. Fischer, M. Ghafari, R. Kruk, R. A. Brand, D. Wang, H. Hahn, and H. Gleiter. "Evidence for enhanced ferromagnetism in an iron-based nanoglass." Applied Physics Letters 103, no. 7 (August 12, 2013): 073106. http://dx.doi.org/10.1063/1.4818493.

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31

Hu, Qingzhuo, Jili Wu, and Bo Zhang. "Synthesis and nanoindentation behaviors of binary CuTi nanoglass films." Physica B: Condensed Matter 521 (September 2017): 28–31. http://dx.doi.org/10.1016/j.physb.2017.06.053.

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32

Wang, Chaomin, Di Wang, Xiaoke Mu, Sunkulp Goel, Tao Feng, Yulia Ivanisenko, Horst Hahn, and Herbert Gleiter. "Surface segregation of primary glassy nanoparticles of Fe90Sc10 nanoglass." Materials Letters 181 (October 2016): 248–52. http://dx.doi.org/10.1016/j.matlet.2016.05.189.

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33

Yin, Leqi, Lu Han, Jing Wang, An Zhang, Dongguang Liu, Laima Luo, Yuan Huang, and Zumin Wang. "Formation and properties of ZrO2–Cu composite nanoglass films." Vacuum 173 (March 2020): 109113. http://dx.doi.org/10.1016/j.vacuum.2019.109113.

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34

Guo, Chunyu, Yini Fang, Fei Chen, and Tao Feng. "Nanoindentation creep behavior of electrodeposited Ni-P nanoglass films." Intermetallics 110 (July 2019): 106480. http://dx.doi.org/10.1016/j.intermet.2019.106480.

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35

Wang, J. Q., N. Chen, P. Liu, Z. Wang, D. V. Louzguine-Luzgin, M. W. Chen, and J. H. Perepezko. "The ultrastable kinetic behavior of an Au-based nanoglass." Acta Materialia 79 (October 2014): 30–36. http://dx.doi.org/10.1016/j.actamat.2014.07.015.

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36

Jing, J., A. Krämer, R. Birringer, H. Gleiter, and U. Gonser. "Modified atomic structure in a PdFeSi nanoglass." Journal of Non-Crystalline Solids 113, no. 2-3 (December 1989): 167–70. http://dx.doi.org/10.1016/0022-3093(89)90007-0.

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37

Ohta, Y., M. Kitayama, K. Kaneko, S. Toh, F. Shimizu, and K. Morinaga. "In Situ Measurement of Capacitance: A Method for Fabricating Nanoglass." Journal of the American Ceramic Society 88, no. 6 (June 2005): 1634–36. http://dx.doi.org/10.1111/j.1551-2916.2005.00257.x.

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38

Chen, Daqin, Zhongyi Wan, and Shen Liu. "Highly Sensitive Dual-Phase Nanoglass-Ceramics Self-Calibrated Optical Thermometer." Analytical Chemistry 88, no. 7 (March 11, 2016): 4099–106. http://dx.doi.org/10.1021/acs.analchem.6b00434.

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39

Mat Jan, Nur Amanina, M. R. Sahar, Sib Krishna Ghoshal, R. Ariffin, M. S. Rohani, K. Hamzah, and S. F. Ismail. "Thermal and Photoluminescence Properties of Nd3+ Doped Tellurite Nanoglass." Nano Hybrids 3 (January 2013): 81–92. http://dx.doi.org/10.4028/www.scientific.net/nh.3.81.

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Series of glasses based on (75-x)TeO2-15MgO-10Na2O-xNd2O3, where x=0, 1.0, 2.0 and 3.0, are synthesized by conventional melt-quenching technique. The nanoglass particles are derived from heat treatment of this glass near crystallisation temperature for 3 hours. The existence of nanocrystalline nature of this glass is confirmed by x-ray diffraction (XRD) technique followed by calculation using Scherrer equation. Meanwhile, the crystallization temperature, Tc determined using Differential thermal analysis (DTA). The fluorescence spectra of Nd3+ions exhibit emission transition of2P3/24I9/2,4G7/24I9/2,2H11/24I9/2, and4F9/24I9/2under 765 nm excitation wavelengths.
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40

Mahraz, Zahra Ashur, M. R. Sahar, and S. K. Ghoshal. "Tuning Surface Plasmon in Erbium-Boro-Tellurite Nanoglass via Thermal Annealing." Materials Science Forum 846 (March 2016): 85–90. http://dx.doi.org/10.4028/www.scientific.net/msf.846.85.

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The demand for tunable surface plasmon (SP) of embedded metal nanoparticles (NPs) in rare earth doped inorganic lasing glasses is ever-growing. Following melt quenching method Er3+ doped zinc-boro-tellurite glasses containing silver (Ag) NPs are prepared. Glasses are heat treated (thermally annealed) at varying temperatures and time duration to alter the NPs morphology which generates SP. The annealing assisted SP resonance mediated modification in spectral features is discerned. Samples heat treatment at 410 °C for 6 hrs duration ensures the reduction of Ag+ ions to Ago NPs. Thermally annealed glasses are characterized via XRD, UV–Vis-IR absorption, photoluminescence spectroscopy, and TEM imaging. XRD spectra confirm the amorphous nature of the glass and TEM image reveals the existence of homogeneously distributed spherically shaped silver NPs of average diameter ~4.5 nm. NPs are found to grow with the increase of both annealing time and temperature. The UV–Vis spectra exhibit seven absorption bands corresponding to 4f–4f transitions of Er3+ ions in the wavelength range of 500-650 nm. The localized SPR band is evidenced at 550 and 580 nm. Heat treatment causes a red shift of the plasmon peaks ascribed to the alteration in glass refractive index. Furthermore, the glass sample annealed for 6 hrs displays maximum enhancement in the emission intensity corresponding to the peaks centered at 536 (2H11/2→4I15/2), 550 (4S3/2→4I15/2) and 632 nm (4F9/2→4I15/2). This enhancement is primarily attributed to the local field effect of the silver NPs. Admirable features of the results suggest that our systematic method for heat treatment in tuning NPs size assisted SPR may contribute towards the development of functional glass.
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41

Tarafder, Anal, Atiar Rahaman Molla, and Basudeb Karmakar. "Processing and Properties of Eu3+-Doped Transparent YAG (Y3Al5O12) Nanoglass-Ceramics." Journal of the American Ceramic Society 93, no. 10 (July 2, 2010): 3244–51. http://dx.doi.org/10.1111/j.1551-2916.2010.03898.x.

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42

Stoesser, A., M. Ghafari, A. Kilmametov, H. Gleiter, Y. Sakurai, M. Itou, S. Kohara, H. Hahn, and S. Kamali. "Influence of interface on structure and magnetic properties of Fe50B50 nanoglass." Journal of Applied Physics 116, no. 13 (October 7, 2014): 134305. http://dx.doi.org/10.1063/1.4897153.

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43

Singh, I., R. Narasimhan, and Y. W. Zhang. "Ductility enhancement in nanoglass: role of interaction stress between flow defects." Philosophical Magazine Letters 94, no. 11 (October 6, 2014): 678–87. http://dx.doi.org/10.1080/09500839.2014.961584.

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44

Stöter, Matthias, Bernhard Biersack, Sabine Rosenfeldt, Markus J. Leitl, Hussein Kalo, Rainer Schobert, Hartmut Yersin, Geoffrey A. Ozin, Stephan Förster, and Josef Breu. "Encapsulation of Functional Organic Compounds in Nanoglass for Optically Anisotropic Coatings." Angewandte Chemie International Edition 54, no. 16 (February 20, 2015): 4963–67. http://dx.doi.org/10.1002/anie.201411137.

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45

Hirmukhe, S. S., A. Sharma, Sree Harsha Nandam, Horst Hahn, K. E. Prasad, and I. Singh. "Investigation of softening induced indentation size effect in Nanoglass and Metallic glasss." Journal of Non-Crystalline Solids 577 (February 2022): 121316. http://dx.doi.org/10.1016/j.jnoncrysol.2021.121316.

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Hirmukhe, S. S., A. T. Joshi, and I. Singh. "Mixed mode (I and II) fracture behavior of nanoglass and metallic glass." Journal of Non-Crystalline Solids 580 (March 2022): 121390. http://dx.doi.org/10.1016/j.jnoncrysol.2021.121390.

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Aseev, V. A., and N. V. Nikonorov. "Spectroluminescence properties of photothermorefractive nanoglass-ceramics doped with ytterbium and erbium ions." Journal of Optical Technology 75, no. 10 (October 1, 2008): 676. http://dx.doi.org/10.1364/jot.75.000676.

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Adibi, Sara, Zhen-Dong Sha, Paulo S. Branicio, Shailendra P. Joshi, Zi-Shun Liu, and Yong-Wei Zhang. "A transition from localized shear banding to homogeneous superplastic flow in nanoglass." Applied Physics Letters 103, no. 21 (November 18, 2013): 211905. http://dx.doi.org/10.1063/1.4833018.

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49

Chen, Na, Di Wang, Peng Fei Guan, Hai Yang Bai, Wei Hua Wang, Zheng Jun Zhang, Horst Hahn, and Herbert Gleiter. "Direct observation of fast surface dynamics in sub-10-nm nanoglass particles." Applied Physics Letters 114, no. 4 (January 28, 2019): 043103. http://dx.doi.org/10.1063/1.5052016.

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Wu, G. Y., J. Z. Jiang, and X. P. Lin. "Nanoglass Fe79B21 powders prepared by chemical reduction: A low-temperature Mössbauer study." Nanostructured Materials 12, no. 5-8 (January 1999): 843–46. http://dx.doi.org/10.1016/s0965-9773(99)00248-2.

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