4.1: Introduction

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Three Laws of Thermodynamics describe the flow and transfer of energy in the universe:

Energy can neither be created nor destroyed. The rule is also stated as “universal energy is constant.”
Universal entropy (disorder) is always increasing.
Entropy declines with temperature—as temperatures approach absolute zero, so goes entropy.

In living systems, we do not have to worry about the third law because the equations for energy exchange in living systems already reflect the temperature dependence of entropy change during reactions. In this chapter we will look at how we came to understand the basic thermodynamic principles and how they apply to living systems. First, we will look at different kinds of energy and at how redox reactions govern the flow of energy through living things. Next, we’ll look at some simple arithmetic statements of the laws of thermodynamics for closed systems and at how they apply to chemical reactions conducted under standard conditions. Finally, since there is really no such thing as a closed system, we look at the energetics of reactions occurring in open systems. For an excellent discussion about the application of basic thermodynamic principles to living things, check out Lehninger A. (1971) Bioenergetics: The Molecular Basis of Biological Energy Transformation. Benjamin Cummings, San Francisco.

Learning Objectives

When you have mastered the information in this chapter, you should be able to:

explain the difference between energy transfer and energy transduction.
compare and contrast potential vs. kinetic as well as other categories of energy (e.g., mass, heat, light…, etc.).
explain the reciprocal changes in universal free energy and entropy.
derive the algebraic relationship between free energy, enthalpy and entropy.
state the difference between exothermic, endothermic, exergonic, and endergonic reactions
predict changes in free energy based on changes in the concentrations of reactants and products in closed systems and open systems.
explain how the same reaction can be endergonic but will (under appropriate conditions) release free energy.
predict whether a biochemical reaction will release free energy if it is exothermic, and if so, under what conditions (you should be able to do this after working some sample problems of closed system energetics).
distinguish between the equilibrium and steady-state of reactions and explain how an endergonic reaction could also be spontaneous (i.e., could release free energy).

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