A compass operates based on Earth's magnetic field. The needle in a compass is a small, lightweight magnet that aligns itself with the magnetic north pole of the Earth. This alignment allows the needle to point towards the north, enabling users to find directions and navigate accordingly. For more CRead more
A compass operates based on Earth’s magnetic field. The needle in a compass is a small, lightweight magnet that aligns itself with the magnetic north pole of the Earth. This alignment allows the needle to point towards the north, enabling users to find directions and navigate accordingly.
For more CBSE Class 6 Science Curiosity Chapter 4 Exploring Magnets Extra Questions & Answer:
To create an electromagnet, wrap a coil of insulated copper wire tightly around a ferromagnetic core, such as a nail. When an electric current flows through the wire, it generates a magnetic field around the core, making the nail act as a magnet. The strength of the electromagnet depends on the numbRead more
To create an electromagnet, wrap a coil of insulated copper wire tightly around a ferromagnetic core, such as a nail. When an electric current flows through the wire, it generates a magnetic field around the core, making the nail act as a magnet. The strength of the electromagnet depends on the number of wire turns and the current flowing through it.
For more CBSE Class 6 Science Curiosity Chapter 4 Exploring Magnets Extra Questions & Answer:
Magnetic declination refers to the angular difference between magnetic north, which a compass needle points to, and true north, which is the direction of the Earth's rotational axis. This variation occurs because Earth's magnetic field is not perfectly aligned with its geographic poles. DeclinationRead more
Magnetic declination refers to the angular difference between magnetic north, which a compass needle points to, and true north, which is the direction of the Earth’s rotational axis. This variation occurs because Earth’s magnetic field is not perfectly aligned with its geographic poles. Declination varies by location and affects accurate navigation.
For more CBSE Class 6 Science Curiosity Chapter 4 Exploring Magnets Extra Questions & Answer:
Magnets can lose their magnetism if exposed to extreme conditions such as high temperatures, physical impact, or strong opposing magnetic fields. Heating a magnet can disrupt the alignment of its magnetic domains, reducing its magnetic strength. Similarly, physical shocks or exposure to strong exterRead more
Magnets can lose their magnetism if exposed to extreme conditions such as high temperatures, physical impact, or strong opposing magnetic fields. Heating a magnet can disrupt the alignment of its magnetic domains, reducing its magnetic strength. Similarly, physical shocks or exposure to strong external magnetic fields can also weaken a magnet.
For more CBSE Class 6 Science Curiosity Chapter 4 Exploring Magnets Extra Questions & Answer:
Magnetic field lines are used to visually represent the direction and strength of a magnetic field. They originate from the north pole and curve around to the south pole. The density of these lines indicates the field's strength, with closely spaced lines showing a stronger magnetic field. Field linRead more
Magnetic field lines are used to visually represent the direction and strength of a magnetic field. They originate from the north pole and curve around to the south pole. The density of these lines indicates the field’s strength, with closely spaced lines showing a stronger magnetic field. Field lines help in understanding the behavior of magnets and their interactions with other magnetic materials.
For more CBSE Class 6 Science Curiosity Chapter 4 Exploring Magnets Extra Questions & Answer:
How does a compass work?
A compass operates based on Earth's magnetic field. The needle in a compass is a small, lightweight magnet that aligns itself with the magnetic north pole of the Earth. This alignment allows the needle to point towards the north, enabling users to find directions and navigate accordingly. For more CRead more
A compass operates based on Earth’s magnetic field. The needle in a compass is a small, lightweight magnet that aligns itself with the magnetic north pole of the Earth. This alignment allows the needle to point towards the north, enabling users to find directions and navigate accordingly.
For more CBSE Class 6 Science Curiosity Chapter 4 Exploring Magnets Extra Questions & Answer:
https://www.tiwariacademy.com/ncert-solutions-class-6-science-curiosity-chapter-4/
See lessHow can you make an electromagnet?
To create an electromagnet, wrap a coil of insulated copper wire tightly around a ferromagnetic core, such as a nail. When an electric current flows through the wire, it generates a magnetic field around the core, making the nail act as a magnet. The strength of the electromagnet depends on the numbRead more
To create an electromagnet, wrap a coil of insulated copper wire tightly around a ferromagnetic core, such as a nail. When an electric current flows through the wire, it generates a magnetic field around the core, making the nail act as a magnet. The strength of the electromagnet depends on the number of wire turns and the current flowing through it.
For more CBSE Class 6 Science Curiosity Chapter 4 Exploring Magnets Extra Questions & Answer:
https://www.tiwariacademy.com/ncert-solutions-class-6-science-curiosity-chapter-4/
See lessWhat is magnetic declination?
Magnetic declination refers to the angular difference between magnetic north, which a compass needle points to, and true north, which is the direction of the Earth's rotational axis. This variation occurs because Earth's magnetic field is not perfectly aligned with its geographic poles. DeclinationRead more
Magnetic declination refers to the angular difference between magnetic north, which a compass needle points to, and true north, which is the direction of the Earth’s rotational axis. This variation occurs because Earth’s magnetic field is not perfectly aligned with its geographic poles. Declination varies by location and affects accurate navigation.
For more CBSE Class 6 Science Curiosity Chapter 4 Exploring Magnets Extra Questions & Answer:
https://www.tiwariacademy.com/ncert-solutions-class-6-science-curiosity-chapter-4/
See lessCan magnets lose their magnetism?
Magnets can lose their magnetism if exposed to extreme conditions such as high temperatures, physical impact, or strong opposing magnetic fields. Heating a magnet can disrupt the alignment of its magnetic domains, reducing its magnetic strength. Similarly, physical shocks or exposure to strong exterRead more
Magnets can lose their magnetism if exposed to extreme conditions such as high temperatures, physical impact, or strong opposing magnetic fields. Heating a magnet can disrupt the alignment of its magnetic domains, reducing its magnetic strength. Similarly, physical shocks or exposure to strong external magnetic fields can also weaken a magnet.
For more CBSE Class 6 Science Curiosity Chapter 4 Exploring Magnets Extra Questions & Answer:
https://www.tiwariacademy.com/ncert-solutions-class-6-science-curiosity-chapter-4/
See lessWhat is the significance of the magnetic field lines?
Magnetic field lines are used to visually represent the direction and strength of a magnetic field. They originate from the north pole and curve around to the south pole. The density of these lines indicates the field's strength, with closely spaced lines showing a stronger magnetic field. Field linRead more
Magnetic field lines are used to visually represent the direction and strength of a magnetic field. They originate from the north pole and curve around to the south pole. The density of these lines indicates the field’s strength, with closely spaced lines showing a stronger magnetic field. Field lines help in understanding the behavior of magnets and their interactions with other magnetic materials.
For more CBSE Class 6 Science Curiosity Chapter 4 Exploring Magnets Extra Questions & Answer:
https://www.tiwariacademy.com/ncert-solutions-class-6-science-curiosity-chapter-4/
See less