Secondary emission calorimetry R&D

Electromagnetic calorimetry in high-radiation environments (e.g. forward regions of lepton and hadron collider detectors) is quite challenging. Although the total absorption crystal calorimeters have superior performance as electromagnetic calorimeters, the availability and the cost of the radiation-hard crystals are the two limiting factors in terms of radiation-tolerant implementations. Sampling calorimeters utilizing Silicon sensors as the active media are also favorable in terms of performance but are challenged by high radiation environments. In order to provide a solution for such implementations, we developed a radiation-hard, fast and cost effective technique, secondary emission calorimetry, and tested prototype secondary emission sensors in test beams. In a secondary emission detector module, secondary emission electrons are generated from a cathode when charged hadron or electromagnetic shower particles penetrate the secondary emission sampling module that is placed between absorber materials. The generated secondary emission electrons are then multiplied in a similar way as the photoelectrons in photomultiplier tubes. Here we report on the principles of secondary emission calorimetry, the results from recent test beams as well as the Monte Carlo simulations for the test beam setup, and the performance of a projected, large-scale secondary emission electromagnetic calorimeter.