Grade 7
  1. Introduction to Physics  1.1. Definition and scope of physics  1.2. Importance of Physics in Daily Life and Technology  1.3. Scientific method and its applications in physics  1.4. Measurement and Experiments in Physics  1.5. Branches of Physics and their Applications  1.6. Relation of physics with other sciences
  2. Measurement and units  2.1. Fundamental and derived quantities  2.2. SI units and unit conversions  2.3. Length measuring instruments and tools used  2.4. Measuring the difference between mass and weight  2.5. Measuring time with accuracy  2.6. Measuring the Volume of Regular and Irregular Objects  2.7. Measuring Temperature and Temperature Scales  2.8. Accuracy, Precision, and Significant Figures  2.9. Errors in Measurement and How to Reduce Them  2.10. Estimates and approximations in scientific calculations  2.11. Standard form and order of magnitude
  3. Speed and Force  3.1. Introduction to motion and rest  3.2. Types of motion - uniform and non-uniform  3.3. Scalars and vectors in motion  3.4. Speed, Velocity, and Acceleration  3.5. Distance-time and velocity-time graphs  3.6. Newton's first law of motion (law of inertia)  3.7. Newton's second law of motion (force and acceleration)  3.8. newton's third law of motion  3.9. Types of forces - contact and non-contact forces  3.10. Effect of forces on motion  3.11. Friction – types, effects and applications  3.12. Gravity, free fall and gravitational acceleration  3.13. Circular motion and centripetal force  3.14. Application of Newton's laws in real life
  4. Energy, Work and Power  4.1. Definition and forms of energy  4.2. Potential and Kinetic Energy  4.3. Law of conservation of energy  4.4. Energy transformations in everyday life  4.5. Work done by force and its calculation  4.6. Power - Definition and Calculation  4.7. Simple Machines and Mechanical Advantage  4.8. Efficiency and energy losses of machines  4.9. Renewable and non-renewable energy sources
  5. Heat and temperature  5.1. Difference Between Heat and Temperature  5.2. Thermometer and temperature scale (Celsius, Kelvin, Fahrenheit)  5.3. Expansion and contraction of solids, liquids and gases  5.4. Heat transfer methods – conduction, convection and radiation  5.5. good and bad conductors of heat  5.6. Applications of heat transfer in daily life  5.7. Specific heat capacity and its applications  5.8. Latent heat and change of state  5.9. Thermal equilibrium and heat exchange  5.10. effect of heat on matter
  6. Lighting and Optics  6.1. Nature and properties of light  6.2. Reflection of light and laws of reflection  6.3. Image formation by plane and curved mirrors  6.4. Refraction of light and the laws of refraction  6.5. Lenses – convex and concave, image formation  6.6. Optical instruments – microscope, telescope, camera  6.7. Dispersion of light and formation of spectrum  6.8. Human eye, vision defects and their correction  6.9. Applications of optics in daily life  6.10. Total internal reflection and its applications
  7. Sound and waves  7.1. Nature and properties of waves  7.2. Production and propagation of sound  7.3. Characteristics of sound waves – frequency, amplitude, wavelength  7.4. Speed of sound in different mediums  7.5. Reflection of sound – echo and reverberation  7.6. Ultrasound and its applications  7.7. Doppler effect in sound waves  7.8. Noise pollution and its effects  7.9. Applications of sound in medicine and industry
  8. Electricity and Magnetism  8.1. Electric charge and static electricity  8.2. Electrical conductors and insulators  8.3. Electric current, voltage and resistance  8.4. Ohm's law and its applications  8.5. Electrical Circuits - Series and Parallel Circuits  8.6. Electric power and energy consumption  8.7. Safety precautions in the use of electricity  8.8. Properties of magnets and magnetic fields  8.9. Electromagnets - How They Work and Their Uses  8.10. Relation between electricity and magnetism (electromagnetic induction)  8.11. Applications of electromagnetism in technology  8.12. Earth's magnetic field and its effects
  9. Matter and its properties  9.1. Classification of matter- solid, liquid and gas  9.2. Properties of different states of matter  9.3. Kinetic theory of matter  9.4. Changes in the state of matter and their causes  9.5. Expansion and contraction of substances  9.6. Density and its calculation  9.7. Pressure in solids, liquids and gases  9.8. Atmospheric pressure and its effects  9.9. Applications of pressure in daily life  9.10. Buoyancy and Archimedes' principle
  10. Space Science and Solar System  10.1. Introduction to Astronomy  10.2. Solar System - Planets and their Characteristics  10.3. Sun - structure and energy production  10.4. Moon - phases and its effect on Earth  10.5. Rotation and revolution of the earth  10.6. Solar and lunar eclipses  10.7. Gravity in space and its role in orbits  10.8. Artificial satellites and their uses  10.9. Space exploration and modern discoveries  10.10. Asteroids, comets and meteors  10.11. Life beyond Earth - Possibilities and Theories
  11. Environmental Physics  11.1. Impact of physics on environmental science  11.2. Renewable and non-renewable energy sources  11.3. Energy conservation and efficiency  11.4. Climate change and its effects on Earth  11.5. Air, water and soil pollution – causes and effects  11.6. Greenhouse effect and global warming  11.7. Sustainable development and environmental protection  11.8. Role of Physics in Weather and Climate Studies

Grade 7Measurement and units


Measuring the difference between mass and weight


In grade 7 physics, it is important to understand the concepts of mass and weight and how they differ. These two concepts are often used interchangeably in everyday language, but in physics, they have different meanings and implications. Both mass and weight relate to the amount of matter in an object, but there is more to it than meets the eye.

Understanding mass

Mass is a measure of the amount of matter in an object. It is an intrinsic property of the object, meaning it does not change regardless of the object's location. In the International System of Units (SI) mass is measured in kilograms (kg), but grams (g) and milligrams (mg) are also commonly used, especially for lighter objects.

Example: Consider a bag of apples that weighs 2 kilograms. This weight represents the mass of the apples, which will remain 2 kilograms no matter where you take the bag, whether on Earth, on the Moon, or in space.

Weight of apples: 2 kg

Mass characteristics

  • Mass is a scalar quantity, which means it has magnitude but no direction.
  • Mass is independent of gravity. It does not change with changes in gravity.

Explore weight

Weight is the force exerted on an object due to gravity. Unlike mass, weight is not constant and can change depending on the gravitational force acting on the object. Weight is measured in newtons (N), which indicates the force exerted on the object.

The relation between weight and mass is given by the formula:

Weight = Mass × Gravitational Acceleration

The gravitational acceleration on Earth is about 9.8 m/s2. It will be different if you are on another planet or celestial body.

Example: Suppose you have a 5 kg book. You can use the above formula to find its weight on Earth:

Weight = 5 kg × 9.8 m/s2 = 49 N
5 kg book 49 N (weight)

Weight characteristics

  • Weight is a vector quantity, which means it has both magnitude and direction. The direction of weight is always toward the center of a gravitating body, such as the Earth.
  • Weight depends on the force of gravity and can vary by location (for example, the weight on the Moon is less than on Earth).

Comparison of mass and weight

Now that we've defined mass and weight, it's easy to see how they differ. Here are some key differences:

Property Mass Weight
Definition The amount of matter in an object The force of gravity acting on the object
SI unit Kilogram (kg) Newton (N)
Scalar or Vector Scalar Vector
Variation with location Constant everywhere Varies by location

Real-world applications

Understanding the difference between mass and weight is important in various fields of science and engineering. Here are some examples:

Space probes

In space exploration, knowing the mass of spacecraft and equipment is important for design calculations and efficiencies. Engineers must consider the changing weight of equipment based on gravitational changes in different celestial bodies.

Medical field

In medicine, devices require accurate mass measurements for drugs, which must be administered in specific doses to ensure patient safety. The mass of some items, such as prosthetic limbs, is critical for proper functionality.

Agriculture

Farmers need to know the mass of fertilizers and other inputs so they can distribute them evenly across their fields. These mass measurements are essential to ensure a healthy and productive crop.

Experiments to describe mass and weight

Let us look at some simple experiments to visualise the concepts of mass and weight.

Experiment 1: Using a spring scale

A simple way to measure weight is to use a spring scale. You can use this device to:

  1. Attach an object to the spring scale.
  2. Read the force measurement (in Newtons) shown on the scale. This is the weight of the object.
  3. Recalculate your weight on different surfaces, such as standing on a hill, in an elevator or in other environments, to notice any differences.

Experiment 2: Measuring mass with a scale

The scales measure mass. This is done like this:

  1. Place an object on one side of the scale.
  2. Add the known masses to the other side until the scales balance. The sum of the known masses equals the mass of the object.

Gravitational effects

To understand the concept of weight further, we need to deeply understand the gravitational effects on various celestial bodies. Let us find out how weight differs:

Weight on the moon

The gravitational acceleration of the moon is about 1/6th of the gravitational acceleration of the earth, that is, about 1.6 m/s2. If a person weighs 60 kg on the earth, his weight on the moon will be:

60 kg × 1.6 m/s2 = 96 N
Earth's weight: 60 kg × 9.8 m/s² = 588 newtons Moon's mass: 60 kg × 1.6 m/s² = 96 m.

Weight on Mars

The gravitational force on Mars is about 3.7 m/s2. If the same person stood on Mars, they would calculate their weight as follows:

60 kg × 3.7 m/s2 = 222 N

This shows that weight is not an immutable property of an object, but varies with different gravitational forces.

Conclusion

Understanding the difference between mass and weight and how each is measured is essential to understanding fundamental physics concepts. While mass is an intrinsic property of an object, weight is the force resulting from gravity. Recognizing these differences is important in applications ranging from daily life scenarios to complex scientific explorations.


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