To determine how much product is produced in a chemical reaction, one typically uses stoichiometry based on the balanced chemical equation for the reaction. By knowing the amounts of reactants present and their molar ratios from the equation, you can calculate the theoretical yield of the product. Additionally, experimental measurements, such as mass or concentration changes, can provide insights into the actual yield. Comparing the actual yield to the theoretical yield allows for the calculation of the reaction's efficiency.
The amount of heat produced in a reaction is not fixed. It depends upon the total amount of energy change that has taken place in the reaction altogether. Not only this, all reactions do not produce heat. In some cases we have to supply energy from external sources to get the reaction started.
A glucose molecule is used.It contains about 2880 Kj
In a nuclear bomb temperatures of 10 million centigrade or more are produced. In a nuclear reactor temperatures of 100 centigrade to about 1000 centigrade are produced depending on type and design of reactor.
In anaerobic respiration one glucose molecule produces a net gain of two ATP molecules (four ATP molecules are produced during glycolysis but two are required by enzymes used during the process). In aerobic respiration a molecule of glucose is much more profitable in that a net worth of 34 ATP molecules are generated (32 gross with two being required in the process).
To determine the expected yield of C2H4N2 from the reaction of CO2, NH3, and CH4, we first need to identify the balanced chemical equation for the reaction. Assuming the reaction is balanced, we would calculate the moles of each reactant (CO2, NH3, and CH4) and identify the limiting reagent. The limiting reagent will dictate the maximum amount of C2H4N2 that can be produced. Since specific stoichiometric coefficients are not provided, you would need to perform these calculations based on the balanced equation to find the exact mass of C2H4N2 produced.
The coefficients and molar masses are used to calculate amounts of molecules.
The coefficients and molar masses are used to calculate amounts of molecules.
the coefficients of a balanced reaction
about 36 to 38 ATP molecules are produced for every glucose molecule.
The amount of heat produced in a reaction is not fixed. It depends upon the total amount of energy change that has taken place in the reaction altogether. Not only this, all reactions do not produce heat. In some cases we have to supply energy from external sources to get the reaction started.
The enthalpy of reaction
A glucose molecule is used.It contains about 2880 Kj
A glucose molecule is used.It contains about 2880 Kj
The exponents determine how much concentration changes affect the reaction rate
The exponents determine how much concentration changes affect the reaction rate
The exponents determine how much concentration changes affect the reaction rate
The Krebs cycle produces a total of 2 ATP molecules per glucose molecule.