Test: Magnetism and Electronics - SSC CGL MCQ

A magnetic field is defined as the space surrounding a magnet or a current-carrying conductor where its magnetic effect can be experienced. It is an important concept in physics that helps us understand the interactions between magnets, electric currents, and charged particles. Magnetic field lines provide a visual representation of the direction and strength of the magnetic field at various points in space.

When a tangent is drawn at any point on a magnetic line of force, it represents the direction of the magnetic field at that specific point. This concept is crucial for understanding how magnetic fields behave and interact with magnets, electric currents, and other magnetic materials. The direction of the magnetic field at a given point determines how magnetic objects or charged particles will experience magnetic forces in that region.

The Earth's magnetic field plays a crucial role in protecting living beings from harmful charged particles coming from space. By deflecting these particles towards the poles, the magnetic field helps prevent them from reaching the surface of the Earth in large quantities, thus safeguarding life on the planet. This protective function of the Earth's magnetic field is essential for the preservation of life as we know it.

A moving coil galvanometer is primarily used to detect the presence of current and determine the direction of current flow in any given circuit. When current passes through the coil in a magnetic field, a torque is exerted on it, causing the coil to rotate. This rotation is then used to indicate the presence and direction of the current flowing through the circuit.

To convert a galvanometer into an ammeter, a low resistance needs to be connected in parallel with it. This additional low resistance allows the galvanometer to measure higher currents by effectively bypassing most of the current away from the galvanometer itself. This modification enables the galvanometer to function as an ammeter, measuring current within the circuit.

An ideal voltmeter is characterized by having infinite resistance. When connected in parallel to measure the potential difference between two points in a circuit, the high resistance of the voltmeter ensures that it draws negligible current from the circuit being measured, thus minimizing any impact on the voltage being measured.

Paramagnetic substances are those materials that are feebly magnetized in the direction of a magnetic field when placed in a strong magnetic field. This magnetism decreases with an increase in temperature. Examples of paramagnetic substances include aluminum, platinum, and solutions of salts of iron and nickel.

A paramagnetic substance becomes diamagnetic at a particular temperature known as the Curie temperature. For iron, this temperature is 770°C, and for nickel, it is 358°C. At the Curie temperature, the magnetism produced in the substance changes characteristics.

The 2016 Nobel Prize in Physics was awarded for insights into the odd behavior of matter in unusual phases, such as superconductors, superfluid films, and certain types of magnets. The laureates discovered the peculiar changes that occur with extremely thin layers of matter or under intense magnetic fields, contributing significantly to the understanding of these phenomena.

According to Faraday's Law of Electromagnetic Induction, when there is a change in the magnetic flux linked with a circuit, an induced electromotive force (emf) is produced in the circuit. This induced emf is a crucial concept in understanding how electromagnetic induction works. It's important to note that this induced emf will continue as long as the change in magnetic flux persists, showcasing the dynamic relationship between magnetism and electrical circuits.

Lenz's Law dictates that the direction of the induced emf or induced current is always such that it opposes the cause due to which it is produced. This principle is in harmony with the conservation of energy, ensuring that the system resists changes that could disrupt the equilibrium. Understanding Lenz's Law is essential in analyzing the consequences of electromagnetic induction and the subsequent effects on electrical circuits.

When a piece of metal is subjected to a varying magnetic field or rotated rapidly in a uniform magnetic field, it gives rise to what is known as eddy currents. Eddy currents manifest as swirling currents within the material, akin to a whirlpool of air. These currents have various practical applications, including their utilization in devices such as dead beat galvanometers, induction furnaces, and induction motors. Understanding eddy currents is pivotal in comprehending how magnetic fields interact with conductive materials, leading to unique phenomena and applications in various technological fields.

An AC generator, also known as a dynamo, is a device that converts mechanical energy into alternating current. Its operation relies on the principle of electromagnetic induction, where a changing magnetic field induces an electric current in a conductor. This process is fundamental in the generation of electricity in power plants and various electrical systems.

The primary operation of a DC motor is based on the torque that acts on the rotating coils when they are placed in a uniform magnetic field. This torque causes the armature to rotate, converting electrical energy into mechanical energy. The rotation of the armature generates back emf within the coil, which is a key aspect of the motor's efficiency and operation.

The primary function of a transformer is to change voltage levels in an electrical circuit. Transformers operate based on the principle of mutual induction, where changing current in one coil induces a voltage in another coil. This enables the conversion of high voltage to low voltage (step-down transformer) or low voltage to high voltage (step-up transformer) as required in electrical systems.