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P700, or photosystem I primary donor, is the reaction-center molecule in association with photosystem I. Its name is derived from the word “pigment”, and the maximal wavelength of light it can absorb, 700nm, at which the phenomenon of photobleaching would occur. Its absorption spectrum peaks at 700 nm. The structure of P700 consists of a heterodimer with two distinct chlorophyll molecules, most notably, chlorophyll a and chlorophyll a’, giving it an additional name of “special pair”. Inevitably, however, the special pair of P700 behaves as if it were just one unit. This species is vital due to its ability to absorb light energy with a wavelength approximately between 430nm-700nm, and transfer high-energy electrons on to enzymes that are situated subsequent to it. Photosystem I operates with the intention of producing the reduced form of NADP+ at the end of the photosynthetic reaction through electron transferring. When photosystem I absorbs light, an electron is excited to a higher energy level in the P700 chlorophyll. The resulting P700 with excited electron is designated P700*, which is a strong reducing agent due to its high negative redox potential of -1.2V. Following the excitation of P700, an electron is passed on to an electron acceptor, A­­­o, triggering charge separation to occur producing an anionic A­­­o and cationic P700. Furthermore, electron transfer continues from A­­­o to a phylliquinone molecule known as A1, which is then passed on to a three iron-sulfur molecules (iron-sulfur clusters). Type I photosystems use iron-sulfur cluster proteins as terminal electron acceptors. Thus, the electron is then transferred from F­­­x to another iron sulfur molecule, F­­­A, and then passed on the last iron-sulfur molecule serving as an electron acceptor, F­­­B. Eventually, the electron is transferred to the protein, Ferredoxin, causing it to transform into its reduced form. The electron carrier, Ferredoxin, finalizes the process by reducing NADP+, completing the initial purpose of Photosystem I. The rate of electrons being passed on to subsequent electron acceptors is highly rapid, stopping the electron to be transferred back to the cationic form of the special pair P700. In most cases, the electrons transferring within Photosystem I follow a linear or non-cyclic pathway, consisting of the excitation of the P700 special pair to the production of NADPH. However, in certain situations, it is vital for the photosynthetic organism to recycle the electrons being transferred, resulting in the electron from the terminal iron-sulfur cluster F­­­B transferring to the Cytochrome b6f complex (adaptor between both photosystems). The cyclic pathway creates a proton gradient useful for the production of ATP. However, it is important to note that no NADPH is produced through the cyclic electron-transferring pathway in Photosystem I, since the protein Ferredoxin does not become reduced.