Fog, for many, carries an air of romance, transforming landscapes and captivating the imagination. This ethereal phenomenon often shrouds the sea in a mystical veil, prompting us to delve into the intriguing world of sea fog.


In the mid and low latitudes of the ocean, where seasonal temperature variations are minimal, the potent influence of solar radiation prevails. This leads to robust evaporation of seawater, creating warm and humid weather conditions.


However, the entrance of a cold current disrupts this equilibrium, causing a drop in the temperature near the ocean surface. As temperatures decline, the moisture in the air condenses, giving rise to the formation of sea fog.


The dissipation of sea fog unfolds within a temporal spectrum, varying from a few fleeting minutes to extensive durations, ranging from dozens to hundreds of hours. The duration of fog dissipation is intricately linked to the local climate's dryness and humidity. Arid regions typically witness fog dissipating within an hour, whereas more humid areas may experience lingering fog persisting for around six hours.


Regional and temporal disparities in the appearance and distribution of sea fog are strikingly evident. Some areas are prone to frequent bouts of fog, while others seem immune to its embrace. Similarly, the timing of fog occurrence exhibits seasonal variations, with some regions enveloped in mist during summer and others experiencing foggy conditions in winter.


To comprehend these distinctive characteristics in fog formation and distribution, an analysis of the conditions conducive to fog emergence is imperative. The formation of sea fog hinges on three primary factors:


1. Sea Surface Temperature:


Advection fog predominantly materializes over colder sea surface waters. This is particularly true in areas where the sea surface temperature rapidly decreases along the airflow direction, such as in the confluence area of cold and warm currents or at the sea-land junction with a significant horizontal temperature gradient. Warm and humid air traversing over these cooler waters is more prone to denaturation and cooling, leading to frequent fog occurrences.


2. Sea Temperature Difference:


The collaboration between sea surface temperature and meteorological conditions is crucial for advective fog formation. Besides having a surface water temperature lower than a specific threshold, the coordination between water and air temperatures is essential.


3. Airflow Wind Field:


The sustained presence of warm and humid air plays a pivotal role in sea fog formation and development. This air continuously supplies the requisite water vapor and heat for fog creation within the affected area. The prevailing wind direction conducive to fog formation varies with the sea region. Typically, sea fog is most prevalent in the eastern sea area when a southerly wind prevails, whereas, in southern areas, it occurs more frequently with an easterly wind.


Sea fog, while captivating, poses significant challenges as a maritime hazard. Reduced visibility, a consequence of sea fog, adversely impacts transportation, fishing, offshore oil and gas exploration, breeding, and other activities. Additionally, the diminished sunshine time, coupled with low temperatures and high humidity, detrimentally affects crop growth. The corrosive impact of salt in fog water on buildings is another concern. Among marine accidents arising from oceanic and meteorological causes, those attributed to sea visibility issues constitute a considerable proportion.


In navigating the intricate relationship between natural elements and the human environment, understanding sea fog becomes imperative for managing its impacts and ensuring the safety and productivity of maritime activities.