beacause it's a fact!
y = a(x - h)2 + k
H. H. T. Cleife has written: 'England's greatest national sin'
1.4 written in word form is one and four tenths or one point four.
h-45 but not sure about "standard form".
H
In Photosynthesis, in Non- Cyclic Photophosphorylation, NADP- is produced but is then reduced to NADPH2 which is a reduced coenzyme. The reactions to get from NADP- to NADPH2 are shown below:NADP- + H+ ---> NADPH (The H+ came from the hydrolysed water molecule from PSII)NADPH + e- ---> NADPH-NADPH- + H+ ---> NADPH2
ATP (adenine triphosphate) and NADPH + hydrogen ion (H+) (NADPH2 for short). That's just the basics.
NADP+ accepts and holds 2 high-energy electrons along with a hydrogen ion (H+).
The reduced NADPH2 made during light dependent stage of photosynthesis carries thehydrogen ion
Product produce are ATP, NADPH + H+ and O2
nadph,atp, oxygen
NADPH, which is reduced, is in a high form of free energy. Its low from of free energy is NADP+, which is oxidized. NADPH reaches its high state of free energy through the light reaction phase of photosynthesis. After photosystem 1 (PSI) Fd, which is an electron acceptor, reduces NADP+ turing it into NADPH by adding one proton (H+) and two electrons on to it. It is a more versatile energy source during the Calvin Cycle, the second stage of photosynthesis, than water because it has higher free energy and its energy is more accessible.
The electrons come from water. In the light dependent stage water is split into hydrogen ions (H+), electrons and oxygen. The electrons are passed on to chlorophyll, the H+ ions combine with NADP to form NADPH and the oxygen is released.
H D F. Kitto has written: 'Form and meaning in drama'
NADPH and H+
Electrons provide the energy to be used in the electron transport chain which pumps H+ into the lumen, creating a concentration gradient. ATP is made when the H+ inside the lumen travel into the stroma through ATP synthase.
Inside the cell, NAD is mostly oxidized. The ready availability of the NAD+ will help to speed up the oxidative reactions in the TCA and glycolysis. In contrast, NADP is mainly found in the reduced state. The high level of NADPH will promote reductive reactions in biosynthesis. (http://watcut.uwaterloo.ca/webnotes/Metabolism/page-8.2.html) NAD+ is reduced to NADH in respiration, and NADPH is produced from NADP+ in the light stage of photosynthesis and is not involved in respiration. Remember P (NADP+ and Photosynthesis).