We use molecular dynamics simulations to describe the chemical reactions following shock-induced collapse of cylindrical pores in the high-energy density material RDX. For shocks with particle velocities of 2 km/s we find that the collapse of a 40 nm diameter pore leads to a deflagration wave. Molecular collisions during the collapse lead to ultrafast, multistep chemical reactions that occur under nonequilibrium conditions. Exothermic products formed during these first few picoseconds prevent the nanoscale hotspot from quenching. Within 30 ps, a local deflagration wave develops; it propagates at 0.25 km/s and consists of an ultrathin reaction zone of only nm, thus involving large temperature and composition gradients. Contrary to the assumptions in current models, a static thermal hotspot matching the dynamical one in size and thermodynamic conditions fails to produce a deflagration wave indicating the importance of nonequilibrium loading in the criticality of nanoscale hot spots. These results provide insight into the initiation of reactive decomposition.
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机译:我们使用分子动力学模拟来描述高能密度材料RDX中圆柱孔的冲击诱导塌陷后的化学反应。对于粒子速度为2 km / s的冲击,我们发现直径为40 nm的孔隙坍塌会导致爆燃波。坍塌过程中的分子碰撞导致在非平衡条件下发生的超快速,多步化学反应。在最初的几皮秒内形成的放热产物阻止了纳米级热点的淬灭。在30 ps内,会产生局部爆燃波;它以0.25 km / s的速度传播,由仅nm的超薄反应区组成,因此涉及较大的温度和组成梯度。与当前模型中的假设相反,在尺寸和热力学条件上与动态条件匹配的静态热热点无法产生爆燃波,这表明非平衡负载对纳米级热点的重要性非常重要。这些结果提供了对反应分解引发的见解。
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