Science. 1990 Jul 13;249(4965):133-9. doi: 10.1126/science.249.4965.133.
It is becoming increasingly apparent that chemistry at surfaces, whether it be heterogeneous catalysis, semiconductors etching, or chemical vapor deposition, is controlled by much more than the nature and structure of the surface. Recent experiments that principally make use of molecular beam techniques have revealed that the energy at which an incident molecule collides with a surface can be the key factor in determining its reactivity with or on the surface. In addition, the collision energy of an incident particle has proven essential to the finding of new mechanisms for reaction or desorption of molecules at surfaces, collision-induced activation and collision-induced desorption. These phenomena are often responsible for the different surface chemistry observed under conditions of high reactant pressure, such as those present during a heterogeneous catalytic reaction, and of low pressure of reactants (< 10(-4) torr), such as those present in an ultrahigh vacuum surface science experiment. This knowledge of the microscopic origins of the effect of pressure on the chemistry at surfaces has allowed the development of a scheme to bypass the high-pressure requirement. Reactions that are normally observed only at high reactant pressures, and which are the ones most often of practical importance, can now be carried out in low-pressure, ultrahigh vacuum environments.
越来越明显的是,表面化学(无论是多相催化、半导体刻蚀还是化学气相沉积)的控制因素远不止表面的性质和结构。最近主要利用分子束技术的实验表明,入射分子与表面碰撞的能量可能是决定其在表面上反应活性的关键因素。此外,入射粒子的碰撞能量对于发现表面分子反应或解吸的新机制、碰撞诱导激活和碰撞诱导解吸至关重要。这些现象通常是在反应物高压(如多相催化反应中存在的条件)和反应物低压(<10(-4)托)(如超高真空表面科学实验中存在的条件)下观察到不同表面化学的原因。这种对压力对表面化学影响的微观起源的认识,使得开发一种绕过高压要求的方案成为可能。现在,通常只在反应物高压下观察到的、且通常具有实际重要性的反应,可以在低压、超高真空环境中进行。
