NEET-CHEMISTRY Thermodynamics

Free vector two thermometers for winter and summer

Thermodynamics is a branch of chemistry that deals with the study of energy and its transformations, particularly in relation to physical systems. It is concerned with the relationships between heat, work, and the properties of a system, including temperature, pressure, volume, and entropy.

Thermodynamics is based on a few fundamental laws, known as the laws of thermodynamics, which describe the behavior of energy in physical systems. These laws are:

  1. The first law of thermodynamics: Also known as the law of conservation of energy, this law states that energy cannot be created or destroyed, but it can be transformed from one form to another. In other words, the total amount of energy in a closed system remains constant.
  2. The second law of thermodynamics: This law describes the concept of entropy, which is a measure of the disorder or randomness of a system. It states that the total entropy of a closed system always increases over time, and that energy transformations always result in an increase in entropy.
  3. The third law of thermodynamics: This law states that as the temperature of a system approaches absolute zero, the entropy of the system also approaches zero.

Thermodynamics has many practical applications, particularly in the areas of energy production and utilization, such as in the design of engines, power plants, refrigeration systems, and chemical processes. It is also used to study phase transitions, chemical reactions, and the behavior of materials under different conditions of temperature and pressure.

Thermodynamics is a fundamental topic in NEET chemistry, and a thorough understanding of its principles and laws is important for many aspects of chemical and materials science. of NEET-CHEMISTRY Thermodynamics

Introduction

A portrayal of any thermodynamic framework utilizes the four laws of thermodynamics that structure a proverbial premise. The primary regulation indicates that energy can be moved between actual frameworks as intensity, as work, and with move of matter. The subsequent regulation characterizes the presence of an amount called entropy, that portrays the course, thermodynamically, that a framework can develop and measures the condition of request of a framework and that can be utilized to evaluate the valuable work that can be removed from the system.

In thermodynamics, communications between enormous troupes of items are contemplated and arranged. Key to this are the ideas of the thermodynamic framework and its environmental factors. A framework is made out of particles, whose typical movements characterize its properties, and those properties are thusly connected with each other through conditions of state. Properties can be consolidated to communicate inside energy and thermodynamic possibilities, which are helpful for deciding circumstances for harmony and unconstrained cycles.

With these apparatuses, thermodynamics can be utilized to depict how frameworks answer changes in their current circumstance. This can be applied to a wide assortment of subjects in science and designing, for example, motors, stage changes, compound responses, transport peculiarities, and, surprisingly, dark openings. The consequences of thermodynamics are fundamental for different fields of physical science and for science, substance designing, erosion designing, aviation design, mechanical designing, cell science, biomedical designing, materials science, and financial matters, to name a few.

This article is centered essentially around old style thermodynamics which principally concentrates on frameworks in thermodynamic balance. Non-harmony thermodynamics is much of the time treated as an expansion of the traditional treatment, yet measurable mechanics has carried many advances to that field.

History of NEET-CHEMISTRY Thermodynamics

The development of thermodynamics as a field of study can be traced back to the 17th century, with the work of scientists such as Robert Boyle, who studied the properties of gases, and Evangelista Torricelli, who invented the barometer. However, the formalization of the field of thermodynamics began in the 19th century, with the work of several prominent scientists.

One of the most influential figures in the development of thermodynamics was Sadi Carnot, a French engineer who published a paper in 1824 on the theoretical efficiency of steam engines. Carnot’s work laid the foundation for the concept of the heat engine, which is a device that converts thermal energy into mechanical work.

In the mid-19th century, scientists such as James Prescott Joule, Hermann von Helmholtz, and Rudolf Clausius made important contributions to the understanding of thermodynamics. Joule conducted experiments to establish the relationship between heat and mechanical work, while Helmholtz and Clausius independently developed the concept of energy conservation.

The laws of thermodynamics were first formulated in the mid-19th century. The first law of thermodynamics was formulated by Joule in 1847, and the second law of thermodynamics was developed by Clausius in the 1850s. The third law of thermodynamics was formulated in the early 20th century, by scientists such as Walther Nernst and Max Planck.

Thermodynamics has had a significant impact on science and engineering, and has led to the development of many practical applications, such as the steam engine, refrigeration systems, and internal combustion engines. Today, thermodynamics continues to be an active area of research, with scientists and engineers working to develop new technologies and improve existing ones.

Branches of NEET-CHEMISTRY Thermodynamics

Thermodynamics is a broad field that encompasses several branches, each with its own specific focus and applications. Some of the major branches of thermodynamics include:

  1. Classical thermodynamics: This branch of thermodynamics deals with macroscopic systems and their properties, such as temperature, pressure, and volume. Classical thermodynamics is concerned with the relationships between these properties and the energy in a system, and is primarily concerned with the behavior of macroscopic systems.
  2. Statistical thermodynamics: This branch of thermodynamics deals with the behavior of systems at the molecular or atomic level. It is concerned with the statistical properties of large groups of particles, such as their distribution of energies or velocities, and uses mathematical models to describe the behavior of these systems.
  3. Chemical thermodynamics: This branch of thermodynamics is concerned with the study of chemical reactions and their relationship to energy. Chemical thermodynamics is used to predict the behavior of chemical systems under different conditions, such as temperature and pressure, and is used to design and optimize chemical reactions.
  4. Engineering thermodynamics: This branch of thermodynamics deals with the design and optimization of energy systems, such as engines, power plants, and refrigeration systems. Engineering thermodynamics applies the principles of thermodynamics to practical problems and is focused on developing efficient and sustainable energy systems.
  5. Non-equilibrium thermodynamics: This branch of thermodynamics deals with systems that are not in equilibrium, such as systems undergoing chemical reactions or phase changes. Non-equilibrium thermodynamics is concerned with the time-dependent behavior of these systems and is used to predict the behavior of complex systems under dynamic conditions.

These branches of thermodynamics are all interconnected, and an understanding of the principles and applications of each is important for a complete understanding of thermodynamics as a whole.

Laws of NEET-CHEMISTRY Thermodynamics

Thermodynamics is a branch of science that deals with the study of energy and its transformations in physical and chemical processes. The fundamental principles of thermodynamics are based on a set of laws that govern the behavior of energy in various systems. There are four laws of thermodynamics, which are:

  1. Zeroth Law of Thermodynamics: This law states that if two systems are each in thermal equilibrium with a third system, then they are in thermal equilibrium with each other. In other words, this law establishes the concept of temperature and the fact that heat flows from a higher temperature to a lower temperature.
  2. First Law of Thermodynamics: This law is also known as the law of conservation of energy. It states that energy cannot be created or destroyed, but it can be converted from one form to another. This law establishes the concept of internal energy and the fact that any change in the internal energy of a system must be accounted for by the transfer of energy into or out of the system.
  3. Second Law of Thermodynamics: This law states that the total entropy of a closed system always increases over time. Entropy is a measure of the disorder or randomness of a system, and the second law of thermodynamics establishes the fact that all natural processes lead to an increase in the entropy of the universe.
  4. Third Law of Thermodynamics: This law states that it is impossible to reach absolute zero temperature (0 Kelvin) through any finite number of processes. The third law establishes the concept of entropy at absolute zero and sets a limit to the minimum possible temperature that can be reached.

These laws of thermodynamics are fundamental to the understanding of energy and its transformations in physical and chemical processes. They are used to explain many phenomena in the natural world and are applied in a variety of fields, including physics, chemistry, engineering, and materials science.

System models NEET-CHEMISTRY Thermodynamics

In thermodynamics, a system refers to any portion of the universe that is being studied. A system can be anything from a single molecule to an entire planet, and is usually separated from its surroundings by a boundary. Based on the nature of the system, it can be classified into different types of system models. Here are some commonly used system models in thermodynamics:

  1. Open system: An open system is one that can exchange both matter and energy with its surroundings. For example, a pot of boiling water with steam escaping is an open system, as it exchanges both heat and water vapor with its surroundings.
  2. Closed system: A closed system is one that can exchange energy with its surroundings but not matter. For example, a sealed container with a fixed amount of gas is a closed system, as it can exchange heat with its surroundings but not gas molecules.
  3. Isolated system: An isolated system is one that cannot exchange either matter or energy with its surroundings. For example, the universe can be considered an isolated system, as it cannot exchange matter or energy with any external system.
  4. Homogeneous system: A homogeneous system is one in which the properties of the system are uniform throughout. For example, a gas mixture that is well mixed is a homogeneous system.
  5. Heterogeneous system: A heterogeneous system is one in which the properties of the system vary throughout. For example, a mixture of oil and water is a heterogeneous system, as the properties of the two liquids are different and they do not mix.

These system models are useful in thermodynamics as they help to simplify the study of complex systems by defining their boundaries and characterizing the exchange of energy and matter with their surroundings. By defining the system and its properties, thermodynamic analysis can be performed to understand the behavior of the system and predict its response to changes in its environment.

Classical NEET-CHEMISTRY Thermodynamics

Classical thermodynamics is a branch of thermodynamics that deals with the macroscopic behavior of systems in equilibrium, without considering the microscopic behavior of individual particles. It was developed in the 19th century based on the work of scientists such as Carnot, Clausius, and Kelvin.

Classical thermodynamics is concerned with the study of the relationships between the properties of a system, such as temperature, pressure, volume, and energy. It uses a set of mathematical equations and relationships to describe the behavior of these properties under different conditions.

The key concepts of classical thermodynamics include:

  1. State variables: These are properties of a system that are independent of how the system reached its current state. Examples of state variables include temperature, pressure, and volume.
  2. Processes: These are the changes that occur in a system as it goes from one state to another. Examples of processes include heating, cooling, and expansion.
  3. Laws of thermodynamics: These are fundamental principles that govern the behavior of energy in systems. The four laws of thermodynamics, as discussed in a previous answer, are central to classical thermodynamics.
  4. Equations of state: These are mathematical relationships that describe the behavior of the state variables of a system under different conditions. Examples of equations of state include the ideal gas law and the van der Waals equation.
  5. Work and heat: These are the two ways in which energy can be exchanged between a system and its surroundings. Work is the energy transfer that occurs as a result of a force acting through a distance, while heat is the energy transfer that occurs due to a temperature difference.

Classical thermodynamics is still widely used today to study the behavior of large systems in equilibrium, such as engines, refrigerators, and power plants. It provides a powerful framework for understanding energy transformations in a variety of physical and chemical systems.

Career Opportunities of NEET-CHEMISTRY Thermodynamics

A deep understanding of thermodynamics, including classical and statistical thermodynamics, is critical for many careers in chemistry and related fields. Here are a few examples of career opportunities that involve the application of thermodynamics:

  1. Chemical engineer: Chemical engineers use principles of thermodynamics to design and optimize processes for the production of chemicals and other materials. They work in a variety of industries, including pharmaceuticals, energy, and materials science.
  2. Materials scientist: Materials scientists study the properties of materials, such as polymers and metals, and use thermodynamics to understand and predict their behavior. They may work in academia or industry, developing new materials for use in products ranging from electronics to construction.
  3. Environmental scientist: Environmental scientists use thermodynamics to understand the behavior of pollutants and other chemicals in the environment. They may work for government agencies or private organizations, monitoring and managing pollution levels in air and water.
  4. Aerospace engineer: Aerospace engineers use thermodynamics to design and optimize propulsion systems for aircraft and spacecraft. They may work for government agencies or private aerospace companies.
  5. Energy analyst: Energy analysts use thermodynamics to evaluate and optimize energy systems, such as power plants and renewable energy sources. They may work for government agencies or private organizations, helping to develop more efficient and sustainable energy systems.
  6. Computational chemist: Computational chemists use computer simulations to model the behavior of chemical systems, often using principles of thermodynamics. They may work in academia or industry, developing new drugs or materials.

Overall, a strong understanding of thermodynamics is critical for many careers in chemistry and related fields, and can lead to exciting and rewarding opportunities in a variety of industries.