Formation of Ions

In order to achieve special stability, atoms tend to lose or acquire electrons to achieve the electronic configuration of inert gas atoms.

In the last article, I briefly introduced the data format ION, an integral part of the Nanosai.com project. In this article I will explain the lighter technical information on ION and how it helps developers build a better distributed system ecosystem. But first you need to clarify that there is a possibility of confusion. Before Amazon publicly announced the ION format, we announced the ION data format. Therefore, because it is similar to Amazon's ION, I never chose the name ION. Indeed, after designing and naming the ION format, similarities were found. The acronym ION is derived from "IAP Object Notation". IAP of this open network protocol stands for "Internet Application Protocol". Simple proof is as follows.

FIG. 1 shows a sample mechanism for adding halogen to an olefin. First, there is a pro-electron attack on halogen molecules, resulting in the formation of halide and halide ions. The halide ion is a three-membered ring having a positive charge on the halogen. The halide ion acts as a nucleophile, attacking the halide ion from behind and opening it and attaching itself to the carbon. This results in an overall reverse addition of halogen to the double bond. Figure 3: General sample reaction mechanism of free radical halogenation. The mechanism is divided into a series of steps including start and distribution. During initiation, halogen (bromine) radicals are formed. Light provides sufficient energy to split the bromine molecule to form two bromo radicals. The spread is divided into two steps. In the first step, one of the bromine radicals reacts with the alkane to extract hydrogen and form HBr (strong acid) with the alkyl group.