how does the rate law show how concentration changes after the rate of reaction
8.314 J/mol K
Rate of flow varies as R^4 where R is the radius or Rate of flow = (k) x (R^4)
Boltzmann's constant (not bolt'z man's!) is 1.38064852*10-23 m2 kg s-2 K-1
The value of the constant, better known as the Stefan–Boltzmann constant is given, in SI units byσ = 5.670373×10^−8 W m^−2 K^−4W = Wattsm = metresK = Kelvin
how does the rate law show how concentration changes after the rate of reaction
Dynamite exploding
how does the rate law show how concentration changes after the rate of reaction
Paper burning
The relative rate constant is a ratio of the rate constants of two reactions in a chemical reaction mechanism. It is used to determine the rate of reaction between different reactants in relation to each other.
First order rate constant k is described in V=k[EA] while second order rate constant is given as V=k[E][A]. For reactions that do not have true order, k is the apparent rate constant.
A rate constant
The rate constant (k) of a reaction is temperature-dependent according to the Arrhenius equation. Therefore, specifying the temperature is necessary to accurately determine the rate constant and predict the reaction rate at that specific temperature. Changes in temperature can significantly influence the rate constant and overall reaction kinetics.
The reaction is first order with respect to the reactant. The rate constant k can be determined by using the rate equation in the form rate = k [A]. By plugging in the values for rate and concentration at both conditions, you can solve for k. The rate constant k in this case would be 1.59 × 10^3 M^-1 s^-1.
A relative rate constant the rate at which a reaction will take place. Ex. V = k [A][B] the constant ,k, is a constant value for the rate of the reaction in said equation.
A formula involving a constant K typically represents a relationship where K is a fixed value, such as a proportionality constant or a parameter in an equation. The formula may use K to scale or modify the output based on the specific context or condition in which it is applied.
The rate law for this reaction is rate = k[A][B], where the rate constant k is doubled along with the concentrations of A and B.