Metal surfaces exposed to air environments invariably undergo various surface modifications, altering their secondary electron emission coefficient (SEEC). However, the physical mechanisms underlying these surface modifications differ across metals, yielding distinct effects on SEEC. To investigate the SEEC properties of silver oxide and the impact of surface oxidation on the SEEC of silver, silver oxide and silver coatings were prepared by sputtering, followed by studies of their physical properties and SEEC. Results indicate that under conditions where preparation, storage, and testing were kept as consistent as possible, the SEEC of oxidized silver surfaces is not much different from that of silver-coated surfaces. The SEEC maximum values of silver oxide and silver coatings are 1.7 and 1.6, and the values decreased to 1.5 and 1.4 after ion-sputtering treatment. To validate the impact of surface oxidation on the SEEC of silver, various surface states were achieved on silver substrates. Elemental analysis revealed that vacuum heating effectively removes contaminants from silver coating surfaces, resulting in a significant reduction in SEEC values. Ion sputtering removed contaminants, etched the oxidation layer, and modified the morphology of the silver surface effectively. After 5 min of ion sputtering, the SEEC maximum of the original silver sample decreased from 2.6 to 1.73, and after 15 min of ion sputtering, it further decreased to 1.7. This result indicates that surface oxidation contributes minimally to the SEEC variation of silver exposed to air. The findings revealed in this work hold engineering significance for understanding alterations in the SEEC properties of silver surfaces under different surface conditions.
Gu et al. (Wed,) studied this question.