ENERGY-DEPENDENCE OF HADRONIC ACTIVITY

Two features of high-energy hadronic cascades have long been known to shielding specialists: a) in a high-energy hadronic cascade in a given material (incident E greater than or similar to 10 GeV), the relative abundance and spectrum of each hadronic species responsible for most of the energy deposition is independent of the energy or species of the incident hadron, and b) because pi(0) production bleeds off more and more energy into the electromagnetic sector as the energy of the incident hadron increases, the absolute level of this low-energy hadronic activity (E less than or similar to 1 GeV) rises less rapidly than the incident energy, and in fact rises very nearly as a power of the incident energy. Both features are of great importance in hadron calorimetry, where it is the ''universal spectrum'' which makes possible the definition of an intrinsic e/h, and the increasing fraction of the energy going into pi(0)'s which leads to the energy dependence of e/pi. We present evidence for the ''universal spectrum,'' and use an induction argument and simulation results to demonstrate that the low-energy activity scales as E(m), with 0.80 less than or similar to m less than or similar to 0.85. The hadronic activity produced by incident pions is 15-20% less than that initiated by protons.