Gordon Moore observed in the early 1960s that the number of transistors that could be successfully integrated on a single integrated circuit chip was growing at an exponential rate over time. He then quantified this observation into an equation. This equation has come to be called "Moore's Law" and the growth in the number of transistors in a single integrated circuit chip has continued to follow that equation since then (even though many potential problems that could have stalled the growth have come and gone).
Leslie Hendrix played Dr. Elizabeth Rodgers in 142 episodes of Law and Order, 104 episodes of Law and Order Criminal Intent, 1 episode of Law and Order: Trial by Jury, and the Law and Order movie 'Exiled'.
Actor Jerry Orbach appeared as Detective Lenny Briscoe in:274 episodes of Law and Order3 episodes of Law and Order: SVU3 episodes of Homicide: Life on the Street3 Law and Order video games2 episodes of Law and Order: Trial by Jury1 episode of Law and Order: Criminal Intentand Exiled, the Law and Order TV movie
He was not on Law and ORrder, however he was on both Law and Order SVU and CI.
yes only in Law & Order SVU
The rate law for a zero-order reaction is rate k, where k is the rate constant. In a zero-order reaction, the rate of the reaction is independent of the concentration of the reactants.
In a zero-order reaction, the rate of the reaction is independent of the concentration of the reactants. The rate law for a zero-order reaction is rate k, where k is the rate constant. This means that the rate of the reaction is constant and does not change with the concentration of the reactants.
The zero-order rate law equation is Rate k, where k is the rate constant. In a zero-order reaction, the rate of the reaction is independent of the concentration of the reactants. This means that the rate of the reaction remains constant over time, regardless of changes in reactant concentrations.
A rate constant
The zero order reaction rate law states that the rate of a chemical reaction is independent of the concentration of the reactants. This means that the rate of the reaction remains constant over time. The rate of the reaction is determined solely by the rate constant, which is specific to each reaction. This rate law is expressed as: Rate k, where k is the rate constant.
The zero order rate law in chemical kinetics is significant because it shows that the rate of a reaction is independent of the concentration of reactants. This means that the rate of the reaction remains constant regardless of how much reactant is present. This can be useful in determining the overall reaction rate and understanding the reaction mechanism.
The order of a reaction with respect to ClO2 is determined by the exponent of ClO2 in the rate law expression. If the rate law is of the form rate = k[ClO2]^n, then the order with respect to ClO2 is n. This value can be determined experimentally by measuring how changes in the concentration of ClO2 affect the reaction rate. If the concentration of ClO2 does not appear in the rate law, then the order with respect to ClO2 is zero.
I believe it is a first order reaction. So the integrated rate law would be: ln[A]final = -kt + ln[A]inital
If the order of a reactant is zero, its concentration will not affect the rate of the reaction. This means that changes in the concentration of the reactant will not change the rate at which the reaction proceeds. The rate of the reaction will only be influenced by the factors affecting the overall rate law of the reaction.
To determine the rate constant for a second-order reaction, one can use the integrated rate law for a second-order reaction, which is: 1/At kt 1/A0. By plotting 1/At against time and finding the slope, which is equal to the rate constant k, one can determine the rate constant for the second-order reaction.
To determine the rate constant for a first-order reaction, one can use the integrated rate law for first-order reactions, which is ln(At/A0) -kt. By plotting the natural logarithm of the concentration of the reactant versus time, one can determine the rate constant (k) from the slope of the line.
The rate law expression for a first-order reaction is: Rate kA, where Rate is the reaction rate, k is the rate constant, and A is the concentration of the reactant.