formation nor the potential improvement in the quality of the frozen product has yet been totally clarified.Water is a dipolar molecule and, therefore, when subjected to an electric field (EF), molecules are oriented, lining up their molecular dipoles along the direction of the field. This wellknown effect could be a solid starting point to explain the effects of EFs on water freezing. However, things get a little more complicated when looking for arguments to explain the potential effects of magnetic fields (MFs) on water freezing. Water has no net magnetic moment. When subjected to an external MF, the orbital motion of electrons is altered in such a way that the induced magnetic moments oppose the external field and water is, therefore, a diamagnetic substance. The magnetic susceptibility of water, that is, its magnetic response to the applied MF, is rather low (χ v = −9.035 × 10 6 ) and, therefore, little effects of weak MFs must be expected on water.It is, therefore, in some way striking that, nowadays, the only electromagnetic freezers existing at the market are those that generate magnetic fields, and not EFs, to assist the freezing process. This has happened even though the effectivity of MFs in improving freezing has not yet been proved. Several companies have patented and/or marketed freezers that apply different types of MFs to tentatively improve the quality of frozen food. Such is the case of ABI Co., Ltd. (Chiba, Japan) that sells BCAS (Cells Alive System) freezers^that combine static and oscillating MFs. On the other hand, Ryoho Freeze Systems Co., Ltd. (Nara, Japan) commercializes BProton freezers^that use static MFs and EM waves [1,50]. These innovative freezers actually consist of a MF generator attached to a conventional quick-freezing unit. Additionally, in Proton freezers, an EM wave generator is also added. Depending on the application, the MF or the EM waves may be ceased after certain Bsupercooling period^to quickly induce the immediate freezing of the product, or they may be kept throughout the whole preservation period for a better control of the crystallization mechanism [41]. Many videos that publicize the benefits of both CAS and Proton freezers can be found on the Internet [37]. According to commercial advertisements, both CAS and Proton freezers are able to generate tiny ice crystals throughout the whole frozen product. Besides, they are claimed to prevent cell destruction and preserve the quality of fresh products intact after thawing [1,17]. Consequently, many food processors, restaurants, hotels, hospitals, and research centers, not only in Japan but also all over the world [19,23], have acquired these magnetic freezers. Different food products such as fish (tuna, salmon, or cod, among others), sea urchin, shrimps, sashimi grade seafood and sushi, meat (Wagyu beef, Sufflok lamb, or duck, for example), foie gras, fruits (green mango, lychee, and so on), delicate doughs, and milk products are nowadays magnetically frozen and commercialized as superior-quality food products. Freezing...
