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200 1 $aDe la révolution$eTraduit du russe$fLéon Trotsky$gIntroduction par Alfred Rosmer.
210   $aParis$cditions de Minuit$d1963.
215   $a649 p.$d23 cm
300   $aSul front.: Cours Nouveau, La révolution défigurée, La révolution permanente, La révolution trahie
702  1$aRosmer,$bAlfred
702  1$aTrockij,$bLev Davydovic$f<1879-1940>
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100   $a20202201d2021      |y         0
101 0 $aeng
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181   $ctxt$2rdacontent
182   $cc$2rdamedia
183   $acr$2rdacarrier
200 00$aShape Memory Alloys 2020
210   $aBasel, Switzerland$cMDPI - Multidisciplinary Digital Publishing Institute$d2021
215   $a1 online resource (154 p.)
311 08$a3-0365-2470-3 
311 08$a3-0365-2471-1 
330   $aShape memory alloys (SMAs), in comparison with other materials, have the exceptional ability to change their properties, structure, and functionality depending on the thermal, magnetic, and/or stress fields applied. As is well known, in recent decades, the development of SMAs has allowed innovative solutions and alternatives in biomedical applications and advanced engineering structures for aerospace and automotive industries as well as in sensor and actuation systems, among other sectors. Irrespective of this, designing and engineering using these special smart materials requires a solid background in materials science in order to consolidate their importance in these fields and to broaden their relevance for other new applications. The goal of this Special Issue is to foster the dissemination of some of the latest research devoted to these special materials from different perspectives.
606   $aTechnology: general issues$2bicssc
610   $aadditive manufacturing
610   $aanisotropy
610   $aco-based Heusler alloy
610   $acyclic heat treatment
610   $acyclic tests
610   $adensity control
610   $adifferential scanning calorimetry
610   $aearthquake engineering
610   $aEBSD
610   $aelastic constants
610   $aenergy dissipation
610   $afatigue test
610   $aFe-Mn-Al-Ni
610   $ahigh-entropy alloys
610   $ahigh-temperature shape memory alloys
610   $aintermetallic
610   $alaser powder bed fusion
610   $alaser-ultrasound
610   $alattice structure
610   $amagnetic-field-induced transition
610   $amagnetocaloric effect
610   $amartensitic transformation
610   $amartensitic transitions
610   $amechanical damping
610   $amechanical testing
610   $amedium-entropy alloys
610   $ametamagnetic shape memory alloy
610   $ametamagnetic shape memory alloys
610   $amicrostructure
610   $amulti-component alloys
610   $an/a
610   $aNiTi
610   $aNiTiNb
610   $aphase diagram
610   $aphonon softening
610   $apipe joints
610   $aprocess simulation
610   $aresonant ultrasound spectroscopy
610   $aselective laser melting
610   $ashape memory alloy
610   $ashape memory alloys
610   $aSME
610   $astructural defects
610   $astructure control
610   $asuperelasticity
610   $atexture
610   $atitanium palladium
610   $atitanium platinum
610   $aX-ray diffraction
615  7$aTechnology: general issues
700   $aLopez$b Gabriel A$4edt$01287633
702   $aLopez$b Gabriel A$4oth
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996   $aShape Memory Alloys 2020$93020234
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