状态到状态的反应散射$<trans data-src="F+H">F+H</trans><trans data-src="2">2</trans>$在超音速喷气机中：新生的旋转运动$<trans data-src="HF">高频</trans><trans data-src="(v,J)">（v，J）</trans>$通过直接红外激光吸收的分布

超音速冷却F自由基的脉冲放电源与超音速冷却的F自由基交叉$<trans data-src="H">H（H）</trans><trans data-src="2">2</trans>$研究$<trans data-src="F">F类</trans><trans data-src="(">(</trans><trans data-src="2">2</trans><trans data-src="P">P（P）</trans><trans data-src="3/2">3/2</trans><trans data-src=",">,</trans><trans data-src="2">2</trans><trans data-src="P">P（P）</trans><trans data-src="1/2">1/2</trans><trans data-src=")+">)+</trans><trans data-src="H">H（H）</trans><trans data-src="2">2</trans><trans data-src="→">→</trans><trans data-src="HF">高频</trans><trans data-src="(v,J)+">（v，J）+</trans><trans data-src="H">H（H）</trans>$单碰撞条件下的反应，碰撞能量为1.8（2）kcal/mol$<trans data-src="HF">高频</trans><trans data-src="(v,J)">（v，J）</trans>$通过垂直于两个射流轴相交平面的单模可调谐近红外激光器的直接吸收来探测产物状态。高光谱分辨率$<trans data-src="(Δν≈0.0001 ">(Δν≈0.0001 </trans><trans data-src="cm">厘米</trans><trans data-src="−1">−1</trans><trans data-src=")">)</trans>$允许量子态$<trans data-src="HF">高频</trans><trans data-src="(v,J)">（v，J）</trans>$以最终振动水平的完全分辨率确定分布。这个$<trans data-src="J">J型</trans>$-相关积分截面$<trans data-src="HF">高频</trans><trans data-src="(v=3,J)">（v=3，J）</trans>$与Castillo和Manolopoulos在Stark和Werner的地面绝热势能面上的精确量子散射计算进行了比较。理论和实验之间的一致性对于低$<trans data-src="J">J型</trans>$（<3）个状态。然而，理论大大低估了高$<trans data-src="J">J型</trans>$地自旋轨道态能量截止点附近的（⩾3）态$<trans data-src="F">F类</trans><trans data-src="(">(</trans><trans data-src="2">2</trans><trans data-src="P">P（P）</trans><trans data-src="3/2">第3页，共2页</trans><trans data-src=")">)</trans>$原子，这可能表明存在涉及自旋轨道激发的非绝热反应通道$<trans data-src="F">F类</trans><trans data-src="*">*</trans><trans data-src="(">(</trans><trans data-src="2">2</trans><trans data-src="P">P（P）</trans><trans data-src="1/2">1/2</trans><trans data-src=")">)</trans>$原子。