Keshu

1. What is an atom?

An atom is the smallest unit of matter that still keeps the properties of an element. Everything around us — air, water, plants, metals, and even our bodies — is made of atoms.

Atoms are extremely small and cannot be seen with the naked eye.

2. Structure of an atom (basic idea)

An atom has two main parts:

1. Nucleus (center of the atom)

   • Contains protons (positive charge)

   • Contains neutrons (no charge)

   • Almost all the mass of the atom is here

2. Electrons (around the nucleus)

   • Have negative charge

   • Move around the nucleus in the surrounding space

3. What is an atom like?

• Most of an atom is empty space

• The nucleus is very small but very dense

• Electrons are much lighter than protons

• Atoms are electrically neutral, meaning:

  • Number of protons = number of electrons

4. How did scientists come up with models of the atom?

Scientists could not see atoms directly, so they:

• Performed experiments

• Observed results

• Created models to explain atomic behavior

Each new experiment improved the atomic model.

Rutherford’s Gold Foil Experiment

Scientist

The experiment was performed by Ernest Rutherford in 1911. He was studying the structure of the atom and wanted to test whether J. J. Thomson’s Plum Pudding Model was correct.

Aim of the Experiment

The main aim of Rutherford’s experiment was to understand how positive charge and mass are distributed inside an atom.

Materials and Apparatus Used

• A radioactive source (such as radium or polonium) that emitted alpha particles

• A lead block with a narrow slit to form a thin beam

• A very thin sheet of gold foil

• A fluorescent zinc sulfide screen surrounding the gold foil

• A microscope to observe flashes on the screen

What are Alpha Particles?

• Alpha particles are positively charged

• They are heavy and fast-moving

• They have high energy

• They were chosen because they can penetrate thin metal sheets

Procedure of the Experiment

1. Alpha particles were released from the radioactive source.

2. The lead slit focused them into a narrow beam.

3. This beam was directed toward the thin gold foil.

4. The particles struck the gold foil.

5. After passing through the foil, the particles hit the zinc sulfide screen.

6. When alpha particles hit the screen, small flashes of light were seen.

Observations of the Experiment

Rutherford observed three main results:

1. Most alpha particles passed straight through the foilThis showed that most of the atom is empty space.

2. Some alpha particles were deflected through small anglesThis showed that there is a positive charge inside the atom.

3. A very few alpha particles were deflected backThis showed that the positive charge and mass are concentrated in a very small and dense region.

Conclusions Drawn by Rutherford

From these observations, Rutherford concluded:

• An atom is mostly empty space

• All the positive charge of the atom is concentrated in a tiny central nucleus

• The nucleus is very small but very dense

• Almost all the mass of the atom is in the nucleus

• Electrons move around the nucleus

Why Gold Foil Was Used

• Gold is highly malleable

• It can be beaten into extremely thin sheets

• Thin foil allows alpha particles to pass through easily

Rutherford’s Atomic Model (Result of the Experiment)

Based on the experiment, Rutherford proposed:

• A small, positively charged nucleus at the center

• Electrons revolving around the nucleus

• Large empty space between nucleus and electrons

This model is called the Nuclear Model of the Atom.

Limitations of Rutherford’s Experiment and Model

• Could not explain why electrons do not fall into the nucleus

• Could not explain atomic spectra

• Needed improvement, which later came from Bohr’s model

Importance of the Experiment

• Proved that Thomson’s model was incorrect

• Discovered the nucleus

• Changed the understanding of atomic structure

• Laid the foundation for modern atomic theory

J. J. Thomson’s Atomic Model

(Plum Pudding Model)

Background

After discovering the electron in 1897, J. J. Thomson realized that atoms were not indivisible. Since electrons carry a negative charge, he concluded that there must also be some positive charge inside the atom to balance it.

To explain this, he proposed a new atomic model.

Name of the Model

Thomson’s model is called the Plum Pudding Model.

• In some books, it is also compared to a raisin cake model

• The name comes from a popular English dessert called plum pudding

Description of Thomson’s Model

According to J. J. Thomson:

• The atom is a uniform sphere of positive charge

• The positive charge is spread evenly throughout the atom

• Electrons (negative charges) are embedded inside this positive sphere

• The total positive charge is equal to the total negative charge

Because of this balance, the atom is electrically neutral.

Explanation Using the Plum Pudding Analogy

• The positive charge is like the soft pudding

• The electrons are like plums or raisins

• The electrons are fixed in position, not moving freely

• The atom has no empty space according to this model

Important Features of Thomson’s Model

1. Atom is spherical in shape

2. Positive charge is spread uniformly

3. Electrons are scattered throughout the atom

4. No nucleus is present

5. Atom as a whole is electrically neutral

Why Thomson Proposed This Model

• To explain the presence of electrons inside atoms

• To explain how atoms remain neutral

• To improve the idea of atoms being indivisible solid spheres

Significance of Thomson’s Model

• First atomic model to include subatomic particles

• Proved atoms have internal structure

• Important step in the development of atomic theory

Limitations of Thomson’s Model

Thomson’s model failed to explain several observations:

• Could not explain Rutherford’s Gold Foil Experiment

• Failed to explain the concentration of positive charge

• Did not explain atomic stability correctly

• No explanation for the nucleus

Because of these limitations, Thomson’s model was later replaced by Rutherford’s model.

Final Short Summary

• J. J. Thomson discovered the electron

• He proposed the Plum Pudding Model

• Atom = positive sphere + embedded electrons

• Model explained neutrality but failed in experiments

• Led to the discovery of the nucleus

J. J. Thomson’s Experiment

(Cathode Ray Tube Experiment)

Aim of the Experiment

The aim of J. J. Thomson’s experiment was to study the nature of cathode rays and to find out whether atoms contain smaller particles.

Apparatus Used

• A glass discharge tube

• Two metal electrodes:

  • Cathode (negative electrode)

  • Anode (positive electrode)

• A high-voltage power supply

• A vacuum pump (to remove air from the tube)

• Electric and magnetic fields

Description of the Cathode Ray Tube

• The tube was sealed at both ends

• Most of the air inside the tube was removed

• Low pressure allowed electricity to pass through the gas

• Electrodes were connected to a high voltage source

Procedure of the Experiment

1. A very high voltage was applied across the electrodes.

2. When electricity passed through the tube, rays were produced from the cathode.

3. These rays traveled in straight lines toward the anode.

4. When the rays hit the glass wall, a greenish glow appeared.

These rays were called cathode rays.

Observations Made by J. J. Thomson

1. Cathode rays always originated from the cathode.

2. They traveled in straight lines.

3. They produced fluorescence when they struck the glass.

4. When an electric field was applied:

   • Rays bent toward the positive plate.

5. When a magnetic field was applied:

   • Rays were deflected again.

6. The behavior of the rays was the same:

   • For different gases

   • For different electrode materials

Conclusions of the Experiment

From these observations, J. J. Thomson concluded:

• Cathode rays are made of negatively charged particles

• These particles are present in all atoms

• These particles are much smaller than atoms

• These particles have a very small mass

He named these particles electrons.

Importance of Thomson’s Experiment

• Proved that atoms are divisible

• Discovered the first subatomic particle

• Changed the idea of atoms being indivisible

• Laid the foundation for modern atomic theory

8. Limitations of Thomson’s model

• Could not explain:

  • How positive charge is arranged

  • Results of later experiments

• No nucleus included

Because of this, a new experiment was needed.

9. Rutherford’s Gold Foil Experiment

Scientist:

• Ernest Rutherford (1911)

Experiment setup:

• Thin sheet of gold foil

• Beam of alpha particles directed at the foil

• Screen around foil to detect particles

10. Observations of the experiment

1. Most alpha particles passed straight through

2. Some were deflected slightly

3. A very few were reflected back

11. Conclusions from the experiment

Rutherford concluded:

• Atom is mostly empty space

• Positive charge and mass are concentrated in a tiny nucleus

• Electrons move around the nucleus

12. Rutherford’s Atomic Model

• Nucleus at the center (positive, dense)

• Electrons revolve around the nucleus

• Replaced Thomson’s model