Taking a Closer Look at Reaction Rate

Reaction rate is an indication of the communication rate or reaction rate between neuron and stimulator. In other words, how fast a living thing neuron can send a signal to the brain and brain. Classical neuron anatomy is very simple. Classical neurons consist of a body and a tail. The body has an outwardly protruding nucleus called dendrite. Dendrites are postsynaptic postsynaptic neurons that receive neurotransmitters from presynaptic neurons.

The reaction rate or reaction rate is the rate at which the reactants are converted to products. For example, the oxidative rust of iron in the atmosphere of the earth is a slow reaction that may take years, but the combustion of cellulose in a flame occurs within only a few seconds. In most reactions, the rate decreases as the reaction progresses. The reaction rate is always positive. The presence of a minus sign indicates that the reactant concentration is decreasing. The time unit recommended by IUPAC is always seconds. The reaction rate differs from the rate of increase in the concentration of product P by a constant factor (reciprocal of its stoichiometry), and reactant A is subtracted from the reciprocal of stoichiometry. Contain stoichiometry so that the defined rate is independent of the type of reactant or product selected for measurement

The reaction rate is the rate at which the chemical reaction takes place. A slow reaction rate means that the molecule will bind at a slower rate than the fast reaction. Some reactions take hundreds or thousands of years, but other reactions occur within one second. If you think of a very slow reaction, think about the time it takes for plants and old fish to turn into fossils (carbonization). The reaction rate also depends on the type of molecule to be combined. The lower the concentration of essential elements and compounds, the slower the reaction

Reaction kinetics is a study of chemical reaction rates and reaction rates can vary widely over a wide range of times. Some of the reactions take place at an explosive rate like fireworks explosion (Figure 17.1 "fireworks on the river in the night"), like other barbed wire exposed to rusty strands Other reactions are slow for many years (Figure 17.2 rusty barbed wire). In order to understand the factors that influence the kinetics and kinetics of chemical reactions we first show what happens during the reaction at the molecular level According to reactive collision theory the reaction occurs when the reactant molecules "collide effectively". In order for "effective collision" to occur, the reactant molecules must be properly oriented in space to promote bond breakage and formation as well as atom rearrangement. Leading to the formation of product molecules (Figure 17.3 "Visualization of Collisions")