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Journal articles on the topic 'Physical Metallurgy'

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Published: 4 June 2021
Last updated: 29 July 2024

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1

Haasen, Peter, and J. M. Galligan. "Physical Metallurgy." Journal of Engineering Materials and Technology 109, no. 2 (April 1, 1987): 176. http://dx.doi.org/10.1115/1.3225960.

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2

Harris, Jack, John W. Martin, and Edward A. Little. "‘Physical metallurgy’." Materials Science and Technology 13, no. 8 (August 1997): 705–6. http://dx.doi.org/10.1179/mst.1997.13.8.705.

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3

J. Raub, Christoph. "Physical metallurgy." Journal of Alloys and Compounds 261, no. 1-2 (September 1997): 313. http://dx.doi.org/10.1016/s0925-8388(97)00183-7.

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4

Greenwood, G. W. "Modern physical metallurgy." International Materials Reviews 30, no. 1 (January 1985): 302. http://dx.doi.org/10.1179/imr.1985.30.1.302.

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5

Greenwood, G. W. "Modern physical metallurgy." British Corrosion Journal 20, no. 3 (January 1985): 104. http://dx.doi.org/10.1179/000705985798272803.

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6

Harris, J. "Engineering metallurgy: Part 1 Applied physical metallurgy." International Materials Reviews 39, no. 5 (January 1994): 213–14. http://dx.doi.org/10.1179/imr.1994.39.5.213.

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7

Van Tendeloo, Gustaaf. "Advances in physical metallurgy." Materials Research Bulletin 32, no. 5 (May 1997): 633. http://dx.doi.org/10.1016/s0025-5408(97)00016-0.

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8

Gonser, U. "Perspectives in physical metallurgy." Hyperfine Interactions 68, no. 1-4 (April 1992): 71–82. http://dx.doi.org/10.1007/bf02396453.

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9

Yurioka, Nobutaka. "Advances in Physical Metallurgy and Processing of Steels. Physical Metallurgy of Steel Weldability." ISIJ International 41, no. 6 (2001): 566–70. http://dx.doi.org/10.2355/isijinternational.41.566.

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10

Banya, Shiro. "Physical chemistry of extractive metallurgy." Bulletin of the Japan Institute of Metals 26, no. 7 (1987): 656–60. http://dx.doi.org/10.2320/materia1962.26.656.

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11

Dey, G. K. "Physical metallurgy of nickel aluminides." Sadhana 28, no. 1-2 (February 2003): 247–62. http://dx.doi.org/10.1007/bf02717135.

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12

Harris, J. E. "Physical metallurgy of Magnox fuel element." Materials Science and Technology 6, no. 10 (October 1990): 940–46. http://dx.doi.org/10.1179/026708390790189515.

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13

Bleck, Wolfgang, and Christian Haase. "Physical Metallurgy of High Manganese Steels." Metals 9, no. 10 (September 28, 2019): 1053. http://dx.doi.org/10.3390/met9101053.

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14

DeArdo, A. J. "Accelerated Cooling: A Physical Metallurgy Perspective." Canadian Metallurgical Quarterly 27, no. 2 (April 1988): 141–54. http://dx.doi.org/10.1179/cmq.1988.27.2.141.

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15

Kulkarni, G. J., D. Banerjee, and T. R. Ramachandran. "Physical metallurgy of aluminum-lithium alloys." Bulletin of Materials Science 12, no. 3-4 (September 1989): 325–40. http://dx.doi.org/10.1007/bf02747140.

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16

Cahn, Robert. "Physical metallurgy: Where is it headed?" JOM 55, no. 5 (May 2003): 24–25. http://dx.doi.org/10.1007/s11837-003-0241-5.

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17

Mauk, Michael G. "Silicon solar cells: Physical metallurgy principles." JOM 55, no. 5 (May 2003): 38–42. http://dx.doi.org/10.1007/s11837-003-0244-2.

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18

Yeh, Jien-Wei. "Physical Metallurgy of High-Entropy Alloys." JOM 67, no. 10 (August 19, 2015): 2254–61. http://dx.doi.org/10.1007/s11837-015-1583-5.

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19

Senuma, Takehide. "Advances in Physical Metallurgy and Processing of Steels. Physical Metallurgy of Modern High Strength Steel Sheets." ISIJ International 41, no. 6 (2001): 520–32. http://dx.doi.org/10.2355/isijinternational.41.520.

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20

HASEGAWA, Ryosuke. "Metallurgy and Physical Properties of Rare Earths." Tetsu-to-Hagane 71, no. 16 (1985): 1837–45. http://dx.doi.org/10.2355/tetsutohagane1955.71.16_1837.

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21

Sarrak, V. I. "Application of Mechanical Spectroscopy to Physical Metallurgy." Materials Science Forum 119-121 (January 1993): 783–84. http://dx.doi.org/10.4028/www.scientific.net/msf.119-121.783.

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22

ADHIKARI, S., and P. MUKHOPADHYAY. "Physical Metallurgy of Beryllium and Its Alloys." Mineral Processing and Extractive Metallurgy Review 14, no. 1 (January 1995): 253–99. http://dx.doi.org/10.1080/08827509408914114.

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23

Bhadeshia, H. K. D. H. "Adventures in the physical metallurgy of steels." Materials Science and Technology 30, no. 9 (May 23, 2014): 995–97. http://dx.doi.org/10.1179/0267083614z.0000000724.

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24

Sauthoff, G. "Physical metallurgy and processing of intermetallic compounds." Intermetallics 5, no. 6 (January 1997): 491–92. http://dx.doi.org/10.1016/s0966-9795(97)00014-9.

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25

Cahn, Robert W. "The Birth and Evolution of Physical Metallurgy." Progress in Materials Science 49, no. 3-4 (January 2004): 221–26. http://dx.doi.org/10.1016/s0079-6425(03)00023-9.

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26

Leisch, M. "Three-dimensional nanoscale analysis in physical metallurgy." Vacuum 67, no. 3-4 (September 2002): 435–42. http://dx.doi.org/10.1016/s0042-207x(02)00228-2.

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27

Froes, F. H. "Ordered intermetallics — Physical metallurgy and mechanical behaviour." Materials & Design 14, no. 5 (January 1993): 315–16. http://dx.doi.org/10.1016/0261-3069(93)90151-k.

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28

Martinez, Lorenzo. "The relationship of physical metallurgy and corrosion." JOM 45, no. 9 (September 1993): 21. http://dx.doi.org/10.1007/bf03222428.

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29

Roebuck, Bryan, and Laurie Winkless. "Powder metallurgy at the National Physical Laboratory." Metal Powder Report 71, no. 2 (March 2016): 126–29. http://dx.doi.org/10.1016/j.mprp.2015.08.073.

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30

Takeyama, Masao, and Satoru Kobayashi. "Physical metallurgy for wrought gamma titanium aluminides." Intermetallics 13, no. 9 (September 2005): 993–99. http://dx.doi.org/10.1016/j.intermet.2004.12.014.

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31

Jarvis, David John, and O. Minster. "Metallurgy in Space." Materials Science Forum 508 (March 2006): 1–18. http://dx.doi.org/10.4028/www.scientific.net/msf.508.1.

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Over the past five years, an application-oriented research strategy has been initiated by ESA to permit valuable microgravity research in a broad range of physical sciences. The main objective is to integrate ESA, national activities and industry into an overall European strategy, which will allow research to be performed aboard the International Space Station (ISS), as well as other microgravity platforms, like unmanned space capsules, sounding rockets and parabolic flights. A key area of microgravity research is centred on metallurgy in space. The principal aims of this research field are (i) to investigate various physical phenomena during solidification processes and (ii) to determine the thermophysical properties of important liquid alloys. A number of metallurgical sub-topics have been identified in the ESA research programme, including the columnar-to-equiaxed transition during solidification; metastable and non-equilibrium solidification; multiphase multicomponent alloy solidification; eutectic, peritectic, monotectic and intermetallic alloy growth; fluid flow effects on mushy zone formation; and the measurement of thermophysical properties of liquid alloys. This review paper will therefore highlight the theoretical, experimental and modelling efforts currently being undertaken in the ESA programme.
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32

Colaço, R., and R. Vilar. "Physical metallurgy of laser surface melted plastic mould steels: a case study." Revista de Metalurgia 34, no. 2 (April 30, 1998): 135–39. http://dx.doi.org/10.3989/revmetalm.1998.v34.i2.676.

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33

Radović, Nenad, Goran Vukicevic, Dragomir Glišić, and Stefan Dikić. "Some aspects of physical metallurgy of microalloyed steels." Metallurgical and Materials Engineering 25, no. 04 (January 14, 2020): 247–63. http://dx.doi.org/10.30544/468.

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Some aspects of deformation, precipitation, and recrystallization behavior in medium carbon V-microalloyed and low carbon Nb/Ti-microalloyed steels are presented in the paper. Changes in microstructure are explained together with methods of quantification. The temperature of No-recrystallization (Tnr) is defined as a milestone to show the onset of retardation of recrystallization while the apparent activation energy for hot working shows the extent of this retardation. In the case of high cooling rates, this method is not sufficiently sensitive and Trl (recrystallization limit temperature) and Trs (recrystallization stop temperature) must be evaluated from softening data. Paper presented the possibility to estimate Tnr temperature on six stands finishing train at Hot Strip Mill in HBIS Iron and Steel Serbia, Smederevo as well as the activation energy for static recrystallization, QSRX, derived from Tnr temperatures.
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34

Appel, Fritz, Jonathan D. H. Paul, Michael Oehring, Helmut Clemens, and Franz Dieter Fischer. "Physical metallurgy of high Nb-containing TiAl alloys." Zeitschrift für Metallkunde 95, no. 7 (July 2004): 585–91. http://dx.doi.org/10.3139/146.017992.

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35

Kacher, J., C. Kirchlechner, J. Michler, E. Polatidis, R. Schwaiger, H. Van Swygenhoven, M. Taheri, and M. Legros. "Impact of in situ nanomechanics on physical metallurgy." MRS Bulletin 44, no. 06 (June 2019): 465–70. http://dx.doi.org/10.1557/mrs.2019.124.

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36

Appel, Fritz, Jonathan D. H. Paul, Michael Oehring, Helmut Clemens, and Franz Dieter Fischer. "Physical metallurgy of high Nb-containing TiAl alloys." International Journal of Materials Research 95, no. 7 (July 1, 2004): 585–91. http://dx.doi.org/10.1515/ijmr-2004-0113.

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Abstract Intermetallic titanium aluminides exhibit attractive thermophysical properties, which give them the potential for extensive use as lightweight structural components. Novel design concepts are based on alloys with the general composition (in at.%) Ti-45Al-(5–10) Nb, which were subjected to precipitation hardening. Optimized compositions have been identified that are capable of carrying stresses in excess of 700 MPa at service temperatures of 700 °C and have superior creep properties. The alloys exhibit at room temperature yield stresses in excess of 1GPa combined with plastic tensile elongations of about 2%. Wrought alloys of this type can be an attractive alternative to the nickel-base superalloys in certain ranges of stress and temperature. The future and promise of these new TiAl alloys lies in innovative processing methods designed to achieve better performance.
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37

Cahn, John W. "The Expanding Scope of Thermodynamics in Physical Metallurgy." Materials Transactions, JIM 35, no. 6 (1994): 377–83. http://dx.doi.org/10.2320/matertrans1989.35.377.

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38

Paxton, A. T. "From quantum mechanics to physical metallurgy of steels." Materials Science and Technology 30, no. 9 (February 27, 2014): 1063–70. http://dx.doi.org/10.1179/1743284714y.0000000521.

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39

Blavette, Didier, Sébastien Duguay, and Philippe Pareige. "Atom probe tomography: from physical metallurgy towards microelectronics." International Journal of Materials Research 102, no. 9 (September 2011): 1074–81. http://dx.doi.org/10.3139/146.110561.

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40

Subramanian, K. N., and J. G. Lee. "Physical metallurgy in lead-free electronic solder development." JOM 55, no. 5 (May 2003): 26–32. http://dx.doi.org/10.1007/s11837-003-0242-4.

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41

Pelton, Alan R., Scott M. Russell, and John DiCello. "The physical metallurgy of nitinol for medical applications." JOM 55, no. 5 (May 2003): 33–37. http://dx.doi.org/10.1007/s11837-003-0243-3.

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42

Tkadlečková, Markéta. "Numerical Modelling in Steel Metallurgy." Metals 11, no. 6 (May 28, 2021): 885. http://dx.doi.org/10.3390/met11060885.

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Steel production represents a complex process which is accompanied by a series of physical–chemical processes from melting, through the multiphase flow of steel and chemical reactions (processes taking place between the slag, metal, and an inert gas) after solidification [...]
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43

Jie, Yan, and Kai Yong Jiang. "Multi-Response Optimization of TiC-Cu P/M Composite Physical Properties." Advanced Materials Research 788 (September 2013): 73–76. http://dx.doi.org/10.4028/www.scientific.net/amr.788.73.

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the present study investigates the relationship of powder metallurgy (P/M) process parameters with the properties of TiC-Cu composite produced .The response surface methodology (RSM) was employed for developing experimental models. Analysis on process parameters using powder metallurgy (P/M) was made based on the developed models. In this study, titanium carbide percent (TiC %), balling time, sintering temperature are considered as input process parameters. The properties such as conductivities,bend strength and Vickers hardness were evaluated. Analysis of variance test had also been carried out to check the adequacy of the developed regression models. TiC-Cu composites are found to be more sensitive to balling time and TiC percent than other parameters such as sintering temperature.
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44

WANIBE, Yoshimoto, and Takashi ITOH. "A Starting Point of Physical Chemistry in Powder Metallurgy." Tetsu-to-Hagane 74, no. 8 (1988): 1526–34. http://dx.doi.org/10.2355/tetsutohagane1955.74.8_1526.

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45

Patisson, Fabrice, Olivier Mirgaux, and Jean-Pierre Birat. "Hydrogen steelmaking. Part 1: Physical chemistry and process metallurgy." Matériaux & Techniques 109, no. 3-4 (2021): 303. http://dx.doi.org/10.1051/mattech/2021025.

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Pushed to the forefront by the objective to drastically reduce the CO2 emissions from the steel industry, a new steelmaking route based on hydrogen and electricity is the subject of a great deal of attention and numerous R&D projects. The first step is to chemically reduce iron ore with H2, which is produced by electrolysis of water with low-carbon electricity, and then to transform the direct reduced iron into steel in an electric arc furnace. The second step is a conventional one, similar to that used for scrap recycling. The first step is similar to the so-called direct reduction process but would use pure electrolytic H2 instead of the H2–CO syngas obtained from natural gas reforming. In this paper, we first show how the reduction by pure H2 takes place at the microscopic level of the iron oxide grains and pellets. The three-step (hematite-magnetite-wüstite-iron) reduction occurs successively in time and simultaneously in the pellets. Secondly, a sophisticated kinetic model of the reduction of a single pellet based on the experimental findings is described. Lastly, we present a mathematical model for the simulation of the reduction by pure H2 in a shaft furnace, which can be very useful for the design of a future installation. The main results are that using pure hydrogen, the reduction kinetics are faster and can end with full metallization, the direct reduction process would be simpler, and the shaft furnace could be squatter. The gains in terms of CO2 emissions are quantified (85% off) and the whole route is compared to other zero-carbon solutions in Part 2.
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46

Hrivnak, Ivan. "Physical Metallurgy of Pulsed Current Submerged Arc Weldin Steels." ISIJ International 38, no. 10 (1998): 1100–1106. http://dx.doi.org/10.2355/isijinternational.38.1100.

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47

Barnett, M. R., and J. J. Jonas. "Distinctive Aspects of the Physical Metallurgy of Warm Rolling." ISIJ International 39, no. 9 (1999): 856–73. http://dx.doi.org/10.2355/isijinternational.39.856.

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48

Stoloff, N. S. "Physical and mechanical metallurgy of Ni3Al and its alloys." International Materials Reviews 34, no. 1 (January 1989): 153–84. http://dx.doi.org/10.1179/imr.1989.34.1.153.

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49

Tabatchikova, T. I. "Physical metallurgy: Scientific school of the Academician V.M. Schastlivtsev." Physics of Metals and Metallography 117, no. 4 (April 2016): 315–28. http://dx.doi.org/10.1134/s0031918x16030133.

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50

Pilloni, L., F. Attura, A. Calza-Bini, G. De Santis, G. Filacchioni, A. Carosi, and S. Amato. "Physical metallurgy of BATMAN II Ti-bearing martensitic steels." Journal of Nuclear Materials 258-263 (October 1998): 1329–35. http://dx.doi.org/10.1016/s0022-3115(98)00199-8.

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