Alloys of iron, chromium, and aluminum, known under the trade name Kanthal (A1, APM, AF, D, E), are used for electric resistance heaters and structural elements which are usually exposed to high temperatures. Their resistance to high-temperature oxidation is linked to the formation of an aluminum oxide film on the alloy's surface, which is almost impermeable to oxygen and protects the alloy from further oxidation. Despite their good resistance to high-temperature oxidation, their lifespan can be limited when exposed to rapid high temperature cycling. Because we cannot indefinitely increase the mass percentage of aluminum, due to the increasing brittleness of these alloys when the aluminum percentage exceeds 7.5 mass%, they can no longer be rolled into strips or drawn into wires. The primary goal of our research was to investigate whether it is possible to increase the aluminum concentration only in the subsurface layer of the product. This could extend the ability to regenerate the oxide layer and consequently prolong the product's lifespan. For this purpose, we modified the surface of the alloy using pack aluminization and dipping into sol-gels of Al2O3 and SiO2. In conventional pack aluminization, aluminum-rich layers resistant to certain aggressive atmospheres forms on the alloy's surface (of steel, nickel superalloys). While dipping into sol-gels results in oxide layers forming on the surface at relatively low temperatures (< 200 °C). This layer is either protecting the material from further oxidation or altering the surface's physical properties. Previous research indicated that the formation of aluminum-rich phases on the surface negatively affects the lifespan of cyclically loaded FeCrAl alloys at high temperatures. Therefore, we adjusted the pack aluminization to enrich only the subsurface layer with aluminum by using AlFe as the aluminum source in the pack and adapting the heat treatment temperature regime. The work describes the influence of the percentage of AlFe in the pack and the influence of the heat treatment regime on the thickness of the modified layer, aluminum concentration gradient, and their impact on changes in the alloy's electrical resistance. In the second part of the study, we explored the influence of the T4 plasticizer (2,4,6,8-tetramethyl-2,4,6,8-tetrakis[2-(diethoxymethylsilyl)ethyl]cyclo-tetrasiloxane), drying temperature, and technological parameters on the formation of oxide layers by the dipping sol-gel method using sol-gels of Al2O3 and SiO2. The synthesis of sol-gels and the immersion application process are described. In all cases, a thin oxide layer was formed, albeit always partially cracked. Challenges in the application of sol-gels are highlighted, along with suggested improvements.