Complete equilibrium refers to a state in which there is a balance or equality between opposing forces or influences. In a complete equilibrium, there is no net change or tendency for change in the system, resulting in stability. This concept is often used in fields such as chemistry, physics, and economics to describe a system that has reached a state of balance.
No, equilibrium is reached when a system has the lowest free energy. At equilibrium, the system is in a stable state with no net change occurring, as the forward and reverse reactions are proceeding at the same rate.
A body is in complete equilibrium when the net force acting on it is zero and the net torque around any point is also zero. This means the body is at rest or moving at a constant velocity with no rotations occurring.
When the velocity of a contraction is zero, the contraction is at a complete stop or in a state of static equilibrium.
For complete equilibrium of a body, the sum of all forces acting on the body must be zero (ΣF = 0) and the sum of all torques acting on the body about any point must also be zero (Στ = 0). This means that both the translational and rotational aspects of equilibrium are satisfied, ensuring that the body remains stationary and does not rotate.
Using partial differential equations, you can estimate how long it will take to get within some difference between equilibrium and near-equilibrium. The mathematics predict that it will take infinite time to reach complete equilibrium, but for us humans we can settle for some difference that is so close as to make no difference to us.
no
when vector sum of all forces and all torques is zero.
Leakages = Injections
No, equilibrium is reached when a system has the lowest free energy. At equilibrium, the system is in a stable state with no net change occurring, as the forward and reverse reactions are proceeding at the same rate.
A body is in complete equilibrium when the net force acting on it is zero and the net torque around any point is also zero. This means the body is at rest or moving at a constant velocity with no rotations occurring.
When the velocity of a contraction is zero, the contraction is at a complete stop or in a state of static equilibrium.
The first condition of equilibrium can be applied on concurrent forces that are equal in magnitude, since these produce translational equilibrium. But if the forces are equal in magnitude but are non concurrent then even first condition of equilibrium is satisfied but torque is produced which does not maintain rotational equilibrium. Hence for complete equilibrium that is, both translational and rotational , both the conditions should be satisfied.
Equilibrium expressions cannot be written for complete reactions, because you have to have the forward rate, as well as a reverse rate. Complete reactions do not have reverse rates, because they become complete, and all of the reactants are used up. Complete reactions only produce products, and the products don't produce reactants. word count for answer: 52
For complete equilibrium of a body, the sum of all forces acting on the body must be zero (ΣF = 0) and the sum of all torques acting on the body about any point must also be zero (Στ = 0). This means that both the translational and rotational aspects of equilibrium are satisfied, ensuring that the body remains stationary and does not rotate.
Field of one phase (compared to two phase field, etc)
No, internal equilibrium is not the same as quasi equilibrium. Internal equilibrium refers to a system being in a state where there is no net change in composition, while quasi equilibrium refers to a process that occurs almost at equilibrium, but not necessarily at the exact equilibrium point.
equilibrium conversion is that which is at equilibrium concentration