Typically, an equilibrium equation has arrows pointing in both directions (instead of an "=" sign, the top line has an arrow pointing right and the bottom line has an arrow pointing left) suggesting that it can shift in one direction or the other based on circumstances, for example, a given equation may shift toward the right if the pH rises but shift to the left if pH falls; there are many mitigating factors that can alter equilibrium equations, pH being only one of these factors, others might be voltage, oxygen saturation, atmospheric pressure, presence of enzymes/catalysts, etc.
A situation equation follows the order of the story problem.For instance:Johnny has 8 apples, he eats some, and has 3 left.The situation equation would be: 8 - a = 3A solution equation is the equation that would help you find the solution. Your brain doesn't automatically know what "a" is, it has to rearrange the order of the equation and then solve.The solution equation would be: 8 - 3 = a, then you would solve it.
Actually it is the change in the equilibrium expenditure divided by the change in autonomous expenditure. That will equal the expenditure multiplier.
No powers also, no x times y i.e. xy = 1 is not linear
You know if an equation is linear if it is a straight line. You can also know if the equation is y = mx + b where there are no absolute values nor exponents.
An equation is equivalent to another equation, if they have the same solution.
The balanced equation for this reaction is: 2NO(g) + O2(g) ⇌ 2NO2(g) At equilibrium, the equilibrium constant, Kc, would be equal to [NO2]^2 / ([NO]^2 * [O2]).
Yes, use the Hardy-Weinburg equilibrium equation.
You can calculate the equilibrium constant (Kc) of the reaction. This constant gives you information about the extent of the reaction at equilibrium and helps predict the direction in which a reaction will proceed.
This depends on the type of equation you want. Some teachers prefer an "ionic equation", where all of the ions are shown. Others prefer a "net ionic equation" where ions which are found on the left and right sides of the reaction are taken away. KF ---H2O---> K+ + F- would be the net ionic equation.
The equilibrium potential refers to the electrochemical potential at equilibrium of a particular ion, as calculated by the Nernst equation. The resting potential refers to the weighted average based upon membrane permeabilities of all the equilibrium potentials of the various ions in a given cell, as calculated by the Goldman equation.
Phosphine is not very soluble in water compared to nonpolar substances. If you were to write a balanced equation for the reaction of PH3 with water, it would be an equilibrium reaction.
The equation ΣF = 0 represents the principle of equilibrium in physics. It states that the vector sum of all forces acting on an object is zero when the object is in a state of static equilibrium, meaning it is not accelerating. This equation is derived from Newton's second law of motion.
the concentration of the specific ion inside and outside the cell, as well as the temperature and the valence of the ion. The Nernst equation is used to determine the equilibrium potential for a particular ion across a membrane.
C + i + g + ( x-m) > y
To write an equilibrium constant expression using a balanced chemical equation, you need to identify the reactants and products involved in the equilibrium and write the expression as a ratio of the products raised to their stoichiometric coefficients divided by the reactants raised to their stoichiometric coefficients. The general format is [products]/[reactants]. The coefficients from the balanced equation become the exponents in the expression.
If the temperature of a system at equilibrium changed, the equilibrium position would shift to counteract the change. If the temperature increased, the equilibrium would shift in the endothermic direction to absorb the excess heat. If the temperature decreased, the equilibrium would shift in the exothermic direction to release more heat.
the equilibrium constant would change