Moisture damage severely compromises the material properties, structural integrity, and decorative layer integrity of historic buildings, presenting a critical technical challenge in architectural heritage conservation. Electromagnetic wave dehumidification technology has garnered attention for its minimal intervention, low cost, and high efficiency, yet its practical engineering applications remain limited. This paper categorizes electromagnetic wave dehumidification devices into two main types based on their active moisture removal capability: “water-blocking type” and “dewatering type”. Research indicates that electromagnetic wave dehumidification devices utilizing electroosmosis principles require precise control of electric field strength (≥40 V/m) and Joule effect, making them more suitable for historic buildings where the material surface carries a net negative charge and low salt content. Among moisture-blocking devices, those neutralizing water molecules perform best during humidity maintenance phases. Devices that primarily alter the structure of water molecules struggle to meet heritage dehumidification requirements. Experimental analysis indicates that external factors like moisture sources and seasonal environments significantly influence technical evaluations. This paper recommends that future research should optimize experimental design, strengthen comparative studies, and explore composite mechanisms to enhance the systematic reliability of electromagnetic wave dehumidification technology in architectural heritage conservation. This research helps to clarify some of the conceptual uncertainties associated with the use of electromagnetic wave dehumidification technology. Furthermore, it proposes a principle-based experimental framework that can be used to guide future experimental designs and the application of this technology in the field of cultural heritage preservation.
Cheng et al. (Thu,) studied this question.