Gibbs Free Energy (\(\Delta G\)) is a crucial thermodynamic quantity used to determine the spontaneity of a chemical reaction. Simply put, it tells us whether a reaction can occur by itself. For a reaction to be spontaneous, \(\Delta G\) must be negative, indicating that the process can release free energy and proceed without any external input.
In contrast, when \(\Delta G\) is positive, as derived from \(\Delta G = -nFE\), the reaction is non-spontaneous under standard conditions. Here, the negative sign before the equation suggests that when the cell potential \((E)\) is negative, \(\Delta G\) becomes positive. Hence, the reaction requires energy input to proceed, making it less favorable. Understanding Gibbs Free Energy helps predict the direction and feasibility of chemical processes.

The Equilibrium Constant (\(K\)) plays a fundamental role in predicting the extent of a reaction at equilibrium. It is a ratio that compares the concentrations of products to reactants for a reaction at equilibrium. A key equation linking Gibbs Free Energy to \(K\) is \(\Delta G = -RT\ln(K)\), where \(R\) is the gas constant and \(T\) is temperature in Kelvin.
When \(\Delta G\) is positive, as discovered, this leads to \(\ln(K) < 0\), implying that \(K < 1\). Meaning, at equilibrium, reactant concentrations are higher than those of the products. This tells us that the reaction does not go significantly towards the products, aligning with its non-spontaneous nature. The equilibrium constant thus provides valuable insight into the equilibrium position and overall reaction tendencies.

Cell Potential (\(E\)), measured in volts, is a measure of the electromotive force of an electrochemical cell. It determines the ability of a redox reaction to push electrons through a circuit, doing useful work. The expression \(\Delta G = -nFE\) links cell potential with Gibbs Free Energy, showing how a positive or negative \(E\) influences the reaction's spontaneity.
A negative cell potential, as given, implies that the reaction is not self-sustaining—the system must receive energy input rather than providing energy. Consequently, this contributes to a positive \(\Delta G\), further affirming that the cell cannot effectively perform its intended task of generating electricity or doing mechanical work. Understanding cell potential helps in designing and predicting the performance of electrochemical cells.

An Electrochemical Cell is a device that converts chemical energy into electrical energy through redox reactions. It consists of two half-cells connected by a salt bridge and an external circuit. The cell potential (\(E\)) is crucial for determining the cell's ability to perform work.
Naturally, when \(E\) is positive, the electrochemical cell can perform work, such as powering electronic devices or triggering chemical reactions. However, with a negative cell potential as given in this exercise, it is concluded that the cell is inefficient in producing work. Instead, it might require energy input to function, highlighting its limitation in this particular reaction. Understanding the workings of electrochemical cells is essential for applications in batteries and fuel cells.

Thermodynamics is the branch of chemistry that deals with energy changes, particularly focusing on heat and work involved during chemical reactions and physical processes. It is built upon laws that predict the direction and feasibility of a process.
The link between thermodynamics and Gibbs Free Energy in electrochemical cells is central. The relationship expressed in \(\Delta G = -nFE\) provides a thermodynamic view of how energy transformations occur in electrochemical reactions. When cell potential is negative—and thus thermodynamically unfavorable—a deeper thermo understanding sheds light on why such cells need an external energy source.

• First Law: Energy can't be created or destroyed.
• Second Law: Every energy transfer leads to increased entropy.

These laws among others guide the study and application of electrochemical cells and their energy-related behaviors.