The number of CO2 molecules that could be formed from any reaction depends on a few things. Quantity of reactants are essential information.
You cannot post the question this way. There is ADDITIONAL important information with the question- the images that show different amounts of each reactant. You must include that to get an answer to your question. If you want to do it yourself, check to see which part is the limiting reactant, and go from there or do the equations to find how much Co2 you'd get from each initial amount of reactant. (Look at the RATIOS of the molecules in each picture)
Fermentation.
Hreaction = Hf products - Hf reactants
An endothermic reaction requires heat to form products. An exothermic reaction produces heat when it forms products.
Hreaction = Hf, products - Hf, reactants
These substances are called reactants, the reaction produces products. This type of reaction is called exothermic. As in the following reaction with the burning of methane: CH4 +2O2 ---> CO2 + 2H2O (reactants) (products)
chemical reaction
Zero
Glycolysis produces a net gain of 2 ATP molecules for each reaction
Fermentation.
The light independent reaction produces Glucose
Exothermic
Hreaction = Hf products - Hf reactants
It depends on the reaction. Also, only the products are produced by a chemical reaction; the reactants produce the reaction and are changed in the reaction to the products. (If you have a chemical equation, the number of distinct molecules and/or isolated element symbols on the right side of the equation will show how many distinct products are formed in the reaction.)
The coefficients in front of the reactants and products tell you how many atoms or molecules take part in a reaction. For example, the chemical equation 2 H2 plus O2 produces 2 H2O means that two hydrogen atoms react with one oxygen atom to produce two water molecules.
An endothermic reaction requires heat to form products. An exothermic reaction produces heat when it forms products.
Main products are ATP and NADH.Oxygen is a bi product.
uniaxial rotation