Study of the Effect of Operating Temperatures (1320 K, 1420 K and 1520 K) on the Vacant Sites of TiN Alloy in B2 Structure at 45%, 50% and 55% N by MEAM Method

Advances in Materials Physics and Chemistry Pub Date : 2023-01-01 DOI:10.4236/ampc.2023.137010

Alain S. Dzabana Honguelet, Yahnn J. Mighensle Mimboui, Ronolvie Bitho Ondongo, Timothée Nsongo

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Abstract

In this work, we have studied the vacancy formation energy of TiN alloy of structure B2 of size 10 × 10 × 10 for nitrogen percentages of 45%, 50% and 55% under the influence of temperature at 1320 K, 1420 K and 1520 K using the Modified Embedded Atom Method MEAM under the calculation code LAMMPS version 2020. This study has enabled us to understand the behavior of the TiN alloy under different nitrogen percentages in terms of total energy, vacancy formation energy, crystalline parameter, occupancy rate and order parameter. For total energy, we have shown that as temperature increases, total energy decreases, making it easier to obtain TiN at higher temperatures; reaching the value of -7344.9169 eV for the 55% nitrogen structure for the temperature of 1420 K. For the energy of formation, we have shown that the compounds obtained at 1320 K and 1520 K have a more considerable energy of formation than that obtained at 1420 K. The study of fractions and the order parameter showed us that the structure of TiN with 55% nitrogen is less likely, as the composition obtained is at most 53.35%.

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用MEAM法研究了在45%、50%和55% N条件下，1320 K、1420 K和1520 K对B2结构TiN合金空位的影响

本文研究了氮含量为45%、50%和55%时，尺寸为10 × 10 × 10的B2结构TiN合金在1320 K、1420 K和1520 K温度影响下的空位形成能，采用改进嵌入原子法MEAM，计算程序为LAMMPS version 2020。本研究使我们从总能、空位形成能、结晶参数、占位率和有序参数等方面了解了不同氮含量下TiN合金的行为。对于总能量，我们已经表明，随着温度的升高，总能量降低，使得在更高温度下更容易获得TiN;当温度为1420 K时，55%氮结构达到-7344.9169 eV。对于生成能，我们已经证明在1320k和1520k下得到的化合物比在1420k下得到的化合物具有更大的生成能。分数和序参量的研究表明，氮含量为55%的TiN的结构不太可能，得到的成分最多为53.35%。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Advances in Materials Physics and Chemistry

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