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2024 | OriginalPaper | Buchkapitel

Evaluation of Elastic, Mechanical, and Thermophysical Properties of Nanostructured Aluminides for Aviation Industries

verfasst von : Sudhanshu Tripathi, Devraj Singh, Rajesh Kumar Saluja, Rashmi Vashisth

Erschienen in: Recent Advances in Aerospace Engineering

Verlag: Springer Nature Singapore

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Abstract

Intermetallic-based alloys due to their unique material properties are considered as most suitable modern engineering materials. The present study depicts the elastic, mechanical, and thermophysical properties of aluminides at nanoscale using ultrasonics non-destructive evaluation (NDE) technique. Ultrasonic method is one of the popular methods used widely to characterize the microstructural properties at bulk as well as nanoscale. To evaluate ultrasonic and thermophysical properties, the second-order elastic constants (SOECs) obtained via application of using the Coulomb–Born–Mayer interaction potential for the chosen material. The mechanical parameters have also been evaluated based on obtained SOECs. It is found that Young’s modulus for nanostructured aluminides matches with the reported range of 180–281 GPa. The better ductile behavior of nanostructured NiAl in comparison with nanostructured FeAl is confirmed by Pugh ratio. The ultrasonic velocity has been further utilized to find out the lattice thermal conductivity. All the computed parameters have been utilized to find out the thermal relaxation time, Debye temperature, and acoustic coupling constants for nanostructured aluminides. The ultrasonic theoretical model with well-established relations has been utilized to characterize the nanostructured aluminides. MATLAB as a simulation tool has been utilized to obtain the material characteristics.

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Literatur
1.
Lazar P, Podloucky R (2006) Ab initio study of the mechanical properties of NiAl microalloyed by X=Cr, Mo, Ti, Ga. Phys Rev B 73:104114CrossRef
2.
Kaplanskii YY, Loginov PA, Korotitskiy AV, Bychkova MY, Levashov EA (2020) Influence of heat treatment on the structure evolution and creep deformation behavior of a precipitation hardened B2-(Ni,Fe) Al alloy. Mater Sci Eng A 786:139451CrossRef
3.
Gao X, Wang H, Ma C, Lv M, Ren H (2021) Segregation of alloying elements at the bcc-Fe/B2–NiAl interface and the corresponding effects on the interfacial energy. Intermetallics 131:107096CrossRef
4.
Hu X-L, Zhang Y, Lu G-H, Wang T, Xiao P-H, Yin P-G, Xu H (2009) Effect of O impurity on structure and mechanical properties of NiAl intermetallics: A first-principles study. Intermetallics 17:358–364CrossRef
5.
Liu L, Wu X, Wang R, Li W, Liu Q (2015) First principle study on the temperature dependent elastic constants, anisotropy, generalized stacking fault energy and dislocation core of NiAl and FeAl. Comput Mater Sci 103:116–125CrossRef
6.
Park HS, Zimmerman JA (2006) Stable nanobridge formation in <110> gold nanowires under tensile deformation. Scripta Mater 54:1127–1132CrossRef
7.
Sutrakar VK, Pillai ACR, Mahapatra DR (2014) Orientation, size, and temperature dependent ductile brittle transition in NiAl nanowire under tensile loading-a molecular dynamics study. Defence Sci J 64
8.
Jozwik P, Polkowski W, Bojar Z (2015) Applications of Ni3Al based intermetallic alloys—Current stage and potential perceptivities. Materials (Basel). 8(5):2537–2568CrossRef
9.
Li X-H, Xing C-H, Cui H-L, Zhang R-Z (2019) Elastic and acoustical properties of Cr3AlB4 under pressure. J Phys Chem Solids 126:65–71CrossRef
10.
Shafiq M, Arif S, Ahmad I, Asadabadi SJ, Maqbool M, Aliabad HR (2015) Elastic and mechanical properties of lanthanide monoxides. J Alloy Compd 618:292–298CrossRef
11.
Al-Qaisi S, Abu-Jafar MS, Gopir GK, Ahmed R, Omran SB, Jaradat R, Dahliah D, Khenata R (2017) Structural, elastic, mechanical and thermodynamic properties of Terbium oxide: first-principles investigations. Results Phys 7:709–714CrossRef
12.
Iqbal R, Bilal M, Jalali-Asadabadi S, Rahnamaye Aliabad HA, Ahmad I (2018) Theoretical investigation of thermoelectric and elastic properties of intermetallic compounds ScTM (TM=Cu, Ag, Au and Pd). Int J Mod Phys B(32):1850004
13.
Brugger K (1964) Thermodynamic definition of higher order elastic coefficients. Phys Rev 133:A1611CrossRef
14.
Yadav RR, Pandey DK (2005) Size dependent acoustical properties of bcc metal. Acta Phys Pol A 107:933–946CrossRef
15.
Yadav CP, Pandey DK, Singh D (2019) Elastic and ultrasonic studies on RM (R=Tb, Dy, Ho, Er, Tm; M=Zn, Cu) compounds. Zeitschrift für Naturforschung A 74:1123–1130CrossRef
16.
Leibfried G, Hahn H (1958) Zur Temperaturabhängigkeit der elastischen Konstanten von Alkalihalogenidkristallen. Z Phys 150:497–525CrossRef
17.
Tripathi S, Agarwal R, Singh D (2019) Nonlinear elastic, ultrasonic and thermophysical properties of lead telluride. Int J Thermophys 40:1–18
18.
Tripathi S, Agarwal R, Singh D (2020) Size-dependent ultrasonic and thermophysical properties of indium phosphide nanowires. Zeitschrift für Naturforschung A 75:373–380CrossRef
19.
Singh D, Kaushik S, Tripathi S, Bhalla V, Gupta AK (2014) Temperature-dependent elastic and ultrasonic properties of berkelium monopnictides. Arab J Sci Eng 39:485–494CrossRef
20.
Gray DE (1972) American institute of physics (AIP). Handbook. McGraw-Hill, New York
21.
Morelli DT, Slack GA (2006) High lattice thermal conductivity solids. In: High thermal conductivity materials. Springer, pp 37–68
22.
Bukreeva KA, Babicheva RI, Dmitriev SV, Zhou K, Mulyukov RR (2013) Inhomogeneous elastic deformation of nanofilms and nanowires of NiAl and FeAl alloys. JETP Lett 98:91–95CrossRef
23.
Truell R, Elbaum C, Chick BB (2013) Ultrasonic methods in solid state physics. Academic Press
24.
Singh DJ (1992) Electronic structure, magnetism, and stability of Co-doped NiAl. Phys Rev B 46:14392CrossRef
25.
Connétable D, Maugis P (2008) First principle calculations of the κ-Fe3AlC perovskite and iron–aluminium intermetallics. Intermetallics 16:345–352CrossRef
26.
Pandey DK, Yadav RR (2009) Temperature dependent ultrasonic properties of aluminium nitride. Appl Acoust 70:412–415CrossRef
27.
Tripathi S, Agarwal R, Vashisth R, Singh D (2021) Diameter dependent ultrasonic investigation of SiC nanowires. Innovative applications of nanowires for circuit design. IGI Global, pp 71–100
28.
Frantsevich IN (1982) Elastic constants and elastic moduli of metals and insulators. In: Reference book
29.
Pugh SF (1954) XCII. Relations between the elastic moduli and the plastic properties of polycrystalline pure metals. Lond Edinburgh Dublin Philos Mag J Sci 45:823–843
30.
Hu W, Li M, Fukumoto M (2008) Preparation and properties of HVOF NiAl nanostructured coatings. Mater Sci Eng, A 478:1–8CrossRef
Metadaten
Titel
Evaluation of Elastic, Mechanical, and Thermophysical Properties of Nanostructured Aluminides for Aviation Industries
verfasst von
Sudhanshu Tripathi
Devraj Singh
Rajesh Kumar Saluja
Rashmi Vashisth
Copyright-Jahr
2024
Verlag
Springer Nature Singapore
Buch
Recent Advances in Aerospace Engineering

Print ISBN: 978-981-9713-05-9

Electronic ISBN: 978-981-9713-06-6

Copyright-Jahr: 2024

DOI
https://doi.org/10.1007/978-981-97-1306-6_42

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