A chemical reaction will be spontaneous when its change in Gibbs free energy, or , is negative. This value can be represented numerically by the equation:

First, let's look at the value for . The equation is more likely to yield a negative  value if this variable is below zero, so we want a negative value for . , however, is being subtracted, so a positive  value will give us a more negative . In combination, these conditions give us a negative value minus a positive one, which will always yield a negative answer.

If a reaction with a negative and a positive is always spontaneous, we can reason that a reaction with a positive and negative can never be spontaneous. This combination will yield a positive value minus a negative value, always resulting in a positive solution.

The first law of thermodynamics is the conservation of energy law. A cell that produces energy indefinitely is functionally a perpetual motion machine, and is prohibited by the first law.

The first law of thermodynamics states that the energy of the universe is constant because energy cannot be created or destroyed; however, it is possible for energy to be converted from one form to another. In this question the chair has kinetic energy in the beginning, but it loses all of this energy once it stops. This doesn’t mean that the kinetic energy is destroyed; it means that the kinetic energy is converted to another form of energy. Since it is sliding on a floor with a lot of friction (rough floor), the chair converts the kinetic energy to heat.

The second law of thermodynamics states that the entropy of the universe is always increasing. This law is irrelevant to the question.

In thermodynamics, no heat is exchanged in an adiabatic process, so heat is neither gained, nor lost. In an adiabatic compression temperature increases, but in an expansion temperature decreases.

A reaction with a zero free energy change is at equilibrium. At standard conditions, not at equilibrium, this reaction would have a Gibbs free energy change of –43 kJ/mol, would be spontaneous, and would be able to produce 43 kJ of useful work for every mole that reacts.

The first law of thermodynamics, conservation of energy, is not violated since the refrigerator is merely transforming electrical energy into work.

The second law of thermodynamics, increase of entropy, is violated since the entropy of a cooled house is lower, but there is no corresponding increase in entropy elsewhere. In order to cool an object in the system, and object in the surroundings must be heated.

The third law of thermodynamics deals with absolute zero and is not relevant.

The question states that the change in Gibbs free energy, , is negative. This means that the reaction is spontaneous. Second law of thermodynamics states that a spontaneous process always increases the entropy of the universe. Note that the second law only addresses the entropy of the universe; the change in entropy of a reaction could be either positive or negative. 

This reaction is exergonic (spontaneous) because the change in Gibbs free energy () is negative. It is also endothermic because the change in enthalpy () is positive.

Heat is a form of energy resulting from molecular velocity. Temperature is a scale to measure the amount of internal energy stored as heat, known as enthalpy. Entropy is the relative disorder of a system.

In order for a heat transfer to occur, the system must not be in equilibrium. In other words, there must be a difference in heat energy between two regions of the system, which will allow heat energy to travel from the region of high energy to the region of low energy. This condition is easily identified by a temperature gradient, in which heat will from the region of high temperature to the region of low temperature until the system is at an equilibrium temperature.

This question asks about the zeroth law of thermodynamics which states if two systems are in thermal equilibrium with another system, then all three systems will be in thermal equilibrium with each other.

The other answer choices in this question talk about the other three laws of thermodynamics. First law of thermodynamics states that energy of the universe is constant and that energy cannot be created or destroyed. The second law states that the entropy of the universe is constantly increasing, even if local entropy decreases. The third law states that a pure crystal at absolute zero  has zero entropy.

The Second Law of Thermodynamics states that entropy of the universe always increases. The loss of heat energy to the lake due to friction leads to an increase in the entropy of the universe, and thus the return of that energy to move the child would lead to a decrease in the entropy of the universe.

Nevertheless, the hypothetical movement of the child with this energy is allowed by the First Law of Thermodynamics.