The physical and chemical mechanisms in detonation of isopropyl nitrate gas–liquid two-phase mixtures

Yixiao Zhang; Yue Feng; Qi Zhang

doi:10.1063/5.0303305

The physical and chemical mechanisms in detonation of isopropyl nitrate gas–liquid two-phase mixtures

Yixiao Zhang
, Yue Feng
, Qi Zhang^*

^*Corresponding author for this work

Beijing Institute of Technology

Research output: Contribution to journal › Article › peer-review

Abstract

The physicochemical mechanisms governing the energy output of mist detonation under varying environmental pressures, temperatures, droplet sizes, and concentrations represent a critical challenge in optimizing the energy utilization of fuel cloud explosions. Under ambient temperature and pressure conditions, when the mist droplet size is 30 μ m and the concentration is 100 g/m³, stable detonation cannot be achieved. When the droplet size is 30 μ m, the highest detonation pressure occurs at a concentration of 400 g/m³, with a pressure of 2.3 MPa. Within an initial temperature range of 243.15–303.15 K, the transition distance from deflagration to detonation for the mist is approximately 200 mm, with a detonation velocity of about 1545 m/s. At initial pressures of 0.06, 0.1, and 0.16 MPa, the corresponding transition distances are approximately 100, 150, and 150 mm, respectively, with detonation pressures of about 3.625, 3.855, and 4.532 MPa, and detonation velocities of approximately 1530.4, 1455, and 1360.2 m/s.

Original language	English
Article number	013341
Journal	Physics of Fluids
Volume	38
Issue number	1
DOIs	https://doi.org/10.1063/5.0303305
Publication status	Published - 1 Jan 2026
Externally published	Yes

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title = "The physical and chemical mechanisms in detonation of isopropyl nitrate gas–liquid two-phase mixtures",

abstract = "The physicochemical mechanisms governing the energy output of mist detonation under varying environmental pressures, temperatures, droplet sizes, and concentrations represent a critical challenge in optimizing the energy utilization of fuel cloud explosions. Under ambient temperature and pressure conditions, when the mist droplet size is 30 μ m and the concentration is 100 g/m3, stable detonation cannot be achieved. When the droplet size is 30 μ m, the highest detonation pressure occurs at a concentration of 400 g/m3, with a pressure of 2.3 MPa. Within an initial temperature range of 243.15–303.15 K, the transition distance from deflagration to detonation for the mist is approximately 200 mm, with a detonation velocity of about 1545 m/s. At initial pressures of 0.06, 0.1, and 0.16 MPa, the corresponding transition distances are approximately 100, 150, and 150 mm, respectively, with detonation pressures of about 3.625, 3.855, and 4.532 MPa, and detonation velocities of approximately 1530.4, 1455, and 1360.2 m/s.",

author = "Yixiao Zhang and Yue Feng and Qi Zhang",

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AU - Zhang, Yixiao

AU - Feng, Yue

AU - Zhang, Qi

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Y1 - 2026/1/1

N2 - The physicochemical mechanisms governing the energy output of mist detonation under varying environmental pressures, temperatures, droplet sizes, and concentrations represent a critical challenge in optimizing the energy utilization of fuel cloud explosions. Under ambient temperature and pressure conditions, when the mist droplet size is 30 μ m and the concentration is 100 g/m3, stable detonation cannot be achieved. When the droplet size is 30 μ m, the highest detonation pressure occurs at a concentration of 400 g/m3, with a pressure of 2.3 MPa. Within an initial temperature range of 243.15–303.15 K, the transition distance from deflagration to detonation for the mist is approximately 200 mm, with a detonation velocity of about 1545 m/s. At initial pressures of 0.06, 0.1, and 0.16 MPa, the corresponding transition distances are approximately 100, 150, and 150 mm, respectively, with detonation pressures of about 3.625, 3.855, and 4.532 MPa, and detonation velocities of approximately 1530.4, 1455, and 1360.2 m/s.

AB - The physicochemical mechanisms governing the energy output of mist detonation under varying environmental pressures, temperatures, droplet sizes, and concentrations represent a critical challenge in optimizing the energy utilization of fuel cloud explosions. Under ambient temperature and pressure conditions, when the mist droplet size is 30 μ m and the concentration is 100 g/m3, stable detonation cannot be achieved. When the droplet size is 30 μ m, the highest detonation pressure occurs at a concentration of 400 g/m3, with a pressure of 2.3 MPa. Within an initial temperature range of 243.15–303.15 K, the transition distance from deflagration to detonation for the mist is approximately 200 mm, with a detonation velocity of about 1545 m/s. At initial pressures of 0.06, 0.1, and 0.16 MPa, the corresponding transition distances are approximately 100, 150, and 150 mm, respectively, with detonation pressures of about 3.625, 3.855, and 4.532 MPa, and detonation velocities of approximately 1530.4, 1455, and 1360.2 m/s.

UR - https://www.scopus.com/pages/publications/105028154680

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DO - 10.1063/5.0303305

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The physical and chemical mechanisms in detonation of isopropyl nitrate gas–liquid two-phase mixtures

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