Question

A chemical system has three particles that can have energies of \(0,5,10,15,\) or \(20 \mathrm{~J}\). If the total energy of the system is \(30 \mathrm{~J}\), how many different ways can the particles be organized?

Short answer

There are 10 different ways the particles can be organized to have a total energy of 30 J.

Step-by-step solution

Understand the Problem

We need to find the number of different ways three particles can be arranged to sum up to a total energy of 30 J, given that each particle can only have energies of 0, 5, 10, 15, or 20 J.

Enumerate the Possible Combinations

List all combinations of energies for the three particles that add up to 30 J without concern for the order of the particles.

Calculate the Total Number of Distinct Combinations

Each particle is indistinguishable from the others. Calculate the total number of distinct energy combinations that result in a total energy of 30 J.

Key concepts

Combinatorics in Chemistry

The exploration of chemical systems often involves a branch of mathematics known as combinatorics, which delves into the counting, arrangement, and combination of elements within a particular set. This concept plays a crucial role in chemistry when predicting the possible outcomes of molecular reactions, the distribution of particles among energy levels, or the formation of compounds from a given set of elements.

For example, consider a chemical system with a set energy level that particles can occupy. If we have a variety of energy states available, combinatorics allows us to calculate the number of different ways particles can be distributed among these states, taking into account the fundamental principle that energy is quantized and conserved.

When it comes to the exercise at hand, understanding combinatorics allows us to determine the possible configurations for the three particles within the system. Here, indistinguishable particles and distinct energy levels introduce the concept of partitions in combinatorics, as we seek to understand how many unique ways we can sum up to the total energy using the given energy states.

Common Combinatorial Techniques in Chemistry

To solve problems like the one presented, chemists often use:

• Permutations: Arranging elements where order matters.
• Combinations: Choosing elements without regard to order.
• Partitions: Dividing into parts according to some rule, often with sets of indistinguishable items.

These techniques help chemists predict phenomena such as reaction rates, equilibrium configurations, and molecular formations with considerable accuracy.

Chemical System Energy Levels

Energy levels in a chemical system are defined as the discrete amounts of energy that particles within that system can possess. These can refer to electrons in an atom, molecules in a gas, or other kinds of particles in different phases of matter. The distribution of particles across various energy levels is governed by the principles of quantum mechanics and thermodynamics.

The concept of quantization is paramount; energy can only be held at certain levels, resembling steps on a ladder rather than a continuous slope. In the context of our exercise, energy levels are discrete (0, 5, 10, 15, 20 Joules), and particles within the system can only exist at these specified intervals. Thermochemical principles tell us that the total energy in an isolated system remains constant, so the total energy of the three particles must sum up to 30 Joules, as stated in the problem.

The study of energy levels is important for understanding how particles achieve stability by occupying the lowest available energy states, a concept commonly referred to as the 'ground state'. The ways in which energy can be distributed among particles has profound implications on the system's properties, such as temperature, phase, and reactivity.

Implications for Chemical Reactions

In a reaction, particles will transition between different energy levels. Calculating the different ways energy can be distributed among particles allows chemists to predict:

• Reaction pathways.
• Activation energies required.
• Most stable configurations of products.

Using energy levels, chemists and physicists can model reactions and transitions precisely, allowing for predictions about reaction kinetics and dynamics.

Thermochemistry Principles

Thermochemistry is the branch of chemistry that involves the study of the heat energy associated with chemical reactions and physical transformations. The principles of thermochemistry are based on the first law of thermodynamics, which states that energy cannot be created or destroyed, only transformed from one form to another. This is also known as energy conservation.

For chemical systems, understanding these principles allows scientists to measure and predict how energy transfers during reactions, be it as heat, work, or light. When analyzing a chemical system's energy distribution, it's essential to acknowledge that energy exchange with the surroundings will influence the system's internal energy.

Another key concept in thermochemistry is enthalpy, which is the total heat content of a system. It reflects the energy needed to create a system and the energy required to allow the system to expand against its surroundings. In the context of our exercise, if allowed to exchange heat with the environment, the enthalpy of the system might change, affecting how the energy is distributed among the particles.

Relevance to Chemical Reactions

Thermochemistry principles help predict how energy changes will influence the direction and extent of chemical reactions. By considering factors such as:

• Heat of reaction (whether energy is absorbed or released).
• Changes in enthalpy and internal energy.
• Temperature effects on reaction rates.

chemists can control conditions to favor the formation of desired products or calculate the energy yield of a particular process. This understanding is fundamental in industries ranging from pharmaceuticals to energy production.