The Calvin Benson cycle uses ATP (adenosine triphosphate), NADPH (Nicotinamide adenine dinucleotide phosphate), and CO2 (carbon dioxide) to create glucose.
RuBP, PGA, ATP
RuBP, PGA, ATP
RuBP, PGA, ATP
RuBP, PGA, ATP
RuBP, PGA, ATP
RuBP, PGA, ATP
There can be up to 12 PGAL molecules during the Calvin cycle
the Calvin cycle will produce less glucose
The Calvin cycle uses ATP and NAPDH from light-dependent reactions to produce high-energy sugars.
RuBP, PGA, ATP
RuBP, PGA, ATP
RuBP, PGA, ATP
RuBP, PGA, ATP
RuBP, PGA, ATP
RuBP, PGA, ATP
RuBP, PGA, ATP
the calvin cycle uses 6 molecules of carbon dioxide to produce a singe 6carbon sugar molecule
The final product of one turn of Calvin cycle is 2 molecules of glyceraldehyde-3-phosphate (G3P) molecules. For each G3P synthesized, the cycle spends nine molecules of ATP and six molecules of NADPH2. The light reactions sustain the Calvin cycle by regenerating the ATP and NADPH2.
There can be up to 12 PGAL molecules during the Calvin cycle
== == Technically speaking, three turns of the Calvin cycle produce one Glyceraldehyde-3-phosphate (G3P). Each turn of the Calvin Cycle uses 1 CO2. So three CO2 (3 cycles) for 1 G3P. Since 2 G3P are needed for 1 molecule of glucose = six molecules of CO2. As a side note, for one molecule of glucose= requires 6 CO2 + 18 molecules of ATP + 12 molecules of NADPH. (Source: Campbell and Reece, 2005)
The Calvin Cycle uses ATP and NADPH from light-dependent reactions to produce high-energy sugars.