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Journal of Materials Science

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13-11-2018 | Energy materials

Exploring the solid-state interfacial reaction of Al/Fe₂O₃ nanothermites by thermal analysis

Authors: Xiang Zhou, Ying Zhu, Xiang Ke, Kaili Zhang

Published in: Journal of Materials Science | Issue 5/2019

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Abstract

In this study, we use simultaneous differential scanning calorimetry and thermogravimetric analysis to analyze the solid-state reaction characteristics of Al/Fe₂O₃ nanothermites before n-Al melts. Different experimental setups for thermal analysis are compared, and the heat-release characteristics are studied on Al/Fe₂O₃ nanothermites in the form of powder and pellet, respectively. It is found that protection provided by mere argon flow is far from enough for thermal analysis of Al/Fe₂O₃ nanothermites. The experimental setup must be free of oxygen; otherwise, the determined exothermic peak is mostly the oxidation of n-Al by the residue oxygen molecules in the furnace body, due to the high reactivity and moderate accessibility of free oxygen molecules. Under proper experimental setup, it is found that besides the redox reaction between n-Al and n-Fe₂O₃, intermetallic reaction also occurs to form Fe₄Al₁₃. Moreover, the intermetallic reaction is more noticeable for nanothermite pellet than for nanothermite powder, and the eutectic reaction of Fe₄Al₁₃ and n-Al leads to melting peaks below 655 °C. The results indicate that instrument configuration and sample status affect the testing results to a large extent, and one should be prudent to derive reaction characteristics of nanothermites.

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Sundaram D, Yang V, Yetter RA (2017) Metal-based nanoenergetic materials: synthesis, properties, and applications. Prog Energy Combust Sci 61:293–365CrossRef

Zhou X, Torabi M, Lu J, Shen R, Zhang K (2014) Nanostructured energetic composites: synthesis, ignition/combustion modeling, and applications. ACS Appl Mater Interfaces 6:3058–3074CrossRef

Glavier L, Nicollet A, Jouot F et al (2017) Nanothermite/RDX-based miniature device for impact ignition of high explosives. Propellants Explos Pyrotech 42:308–317CrossRef

Zhou X, Wang Y, Cheng Z, Ke X, Jiang W (2017) Facile preparation and energetic characteristics of core–shell Al/CuO metastable intermolecular composite thin film on a silicon substrate. Chem Eng J 328:585–590CrossRef

Ru C, Wang F, Xu J et al (2017) Superior performance of a MEMS-based solid propellant microthruster (SPM) array with nanothermites. Microsyst Technol 23:3161–3174CrossRef

Jang NS, Ha SH, Kim KH, Cho MH, Kim SH, Kim JM (2017) Low-power focused-laser-assisted remote ignition of nanoenergetic materials and application to a disposable membrane actuator. Combust Flame 182:58–63CrossRef

Myagkov VG, Bykova LE, Zhigalov VS et al (2017) Thermite synthesis, structural and magnetic properties of Co–Al₂O₃ nanocomposite films. J Alloys Compd 724:820–826CrossRef

Lafontaine E, Comet M (2016) Nanothermites. ISTE Ltd, LondonCrossRef

Dreizin EL, Schoenitz M (2015) Correlating ignition mechanisms of aluminum-based reactive materials with thermoanalytical measurements. Prog Energy Combust Sci 50:81–105CrossRef

10.

Marin L, Gao Y, Vallet M et al (2017) Performance enhancement via incorporation of ZnO nanolayers in energetic Al/CuO multilayers. Langmuir 33:11086–11093CrossRef

11.

Ke X, Zhou X, Gao H et al (2018) Surface functionalized core/shell structured CuO/Al nanothermite with long-term storage stability and steady combustion performance. Mater Des 140:179–187CrossRef

12.

Kim JH, Cho MH, Kim KJ, Kim SH (2017) Laser ignition and controlled explosion of nanoenergetic materials: the role of multi-walled carbon nanotubes. Carbon 118:268–277CrossRef

13.

Kinsey AH, Slusarski K, Woll K, Gibbins D, Weihs TP (2016) Effect of dilution on reaction properties and bonds formed using mechanically processed dilute thermite foils. J Mater Sci 51:5738–5749. https://doi.org/10.1007/s10853-016-9876-9 CrossRef

14.

Zhu Y, Zhou X, Xu J et al (2018) In situ preparation of explosive embedded CuO/Al/CL20 nanoenergetic composite with enhanced reactivity. Chem Eng J 354:885–895CrossRef

15.

Marin L, Warot-Fonrose B, Esteve A, Chabal YJ, Alfredo Rodriguez L, Rossi C (2016) Self-organized Al₂Cu nanocrystals at the interface of aluminum-based reactive nanolaminates to lower reaction onset temperature. ACS Appl Mater Interfaces 8:13104–13113CrossRef

16.

Zhang T, Ma Z, Li G, Luo Y (2017) A new strategy for the fabrication of high performance reactive microspheres via energetic polyelectrolyte assembly. RSC Adv 7:904–913CrossRef

17.

Yan N, Qin L, Hao H, Hui L, Zhao F, Feng H (2017) Iron oxide/aluminum/graphene energetic nanocomposites synthesized by atomic layer deposition: enhanced energy release and reduced electrostatic ignition hazard. Appl Surf Sci 408:51–59CrossRef

18.

Williams RA, Schoenitz M, Ermoline A, Dreizin EL (2014) Low-temperature exothermic reactions in fully-dense Al/MoO₃ nanocomposite powders. Thermochim Acta 594:1–10CrossRef

19.

Padhye R, Smith DK, Korzeniewski C, Pantoya ML (2017) Tailoring surface conditions for enhanced reactivity of aluminum powders with solid oxidizing agents. Appl Surf Sci 402:225–231CrossRef

20.

Xu D, Yang Y, Cheng H, Li YY, Zhang K (2012) Integration of nano-Al with Co₃O₄ nanorods to realize high-exothermic core–shell nanoenergetic materials on a silicon substrate. Combust Flame 159:2202–2209CrossRef

21.

Zhou X, Xu D, Yang G et al (2014) Highly exothermic and superhydrophobic Mg/fluorocarbon core/shell nanoenergetic arrays. ACS Appl Mater Interfaces 6:10497–10505CrossRef

22.

Zhao N, He C, Liu J et al (2014) Dependence of catalytic properties of Al/Fe₂O₃ thermites on morphology of Fe₂O₃ particles in combustion reactions. J Solid State Chem 219:67–73CrossRef

23.

Qin L, Yan N, Li J, Hao H, Zhao F, Feng H (2017) Enhanced energy performance from core–shell structured Al@Fe₂O₃ nanothermite fabricated by atomic layer deposition. RSC Adv 7:7188–7197CrossRef

24.

Sui H, Atashin S, Wen JZ (2016) Thermo-chemical and energetic properties of layered nano-thermite composites. Thermochim Acta 642:17–24CrossRef

25.

Zhang T, Ma Z, Li G, Wang Z, Zhao B, Luo Y (2016) Electrostatic interactions for directed assembly of high performance nanostructured energetic materials of Al/Fe₂O₃/multi-walled carbon nanotube (MWCNT). J Solid State Chem 237:394–403CrossRef

26.

Zhou X, Ke X, Jiang W (2016) Aluminum/copper oxide nanostructured energetic materials prepared by solution chemistry and electrophoretic deposition. RSC Adv 6:93863–93866CrossRef

27.

Ke X, Zhou X, Hao G, Xiao L, Liu J, Jiang W (2017) Rapid fabrication of superhydrophobic Al/Fe₂O₃ nanothermite film with excellent energy-release characteristics and long-term storage stability. Appl Surf Sci 407:137–144CrossRef

28.

Liu P, Li X, Cheng L, Zhu X, Li Y, Song D (2018) Preparation and characterization of n-Al/FeF₃ nanothermite. Chem Eng J 331:850–855CrossRef

29.

Gedevanishvili S, Deevi SC (2002) Processing of iron aluminides by pressureless sintering through Fe + Al elemental route. Mater Sci Eng A 325:163–176CrossRef

30.

Li X, Scherf A, Heilmaier M, Stein F (2016) The Al-rich part of the Fe–Al phase diagram. J Phase Equilib Diffus 37:162–173CrossRef

31.

Sundman B, Ohnuma I, Dupin N, Kattner UR, Fries SG (2009) An assessment of the entire Al–Fe system including D03 ordering. Acta Mater 57:2896–2908CrossRef

Title: Exploring the solid-state interfacial reaction of Al/Fe2O3 nanothermites by thermal analysis
Authors: Xiang Zhou
Ying Zhu
Xiang Ke
Kaili Zhang
Publication date: 13-11-2018
Publisher: Springer US
Published in: Journal of Materials Science / Issue 5/2019
Print ISSN: 0022-2461
Electronic ISSN: 1573-4803
DOI: https://doi.org/10.1007/s10853-018-3094-6

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