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Chapter 23: Problem 18

Which type of magnetic material cannot be used to make permanent magnets, a ferromagnetic substance, an antiferromagnetic substance, or a ferrimagnetic substance?

Short Answer

Expert verified
An antiferromagnetic substance cannot be used to make permanent magnets because it has a net magnetization of zero, resulting from the alignment of neighboring magnetic moments in opposite directions. Ferromagnetic and ferrimagnetic substances can form permanent magnets due to their strong attraction to magnetic fields and non-zero net magnetization.

Step by step solution

01

Understand the properties of ferromagnetic substances

A ferromagnetic substance is a material that has a strong attraction to magnetic fields. It can form permanent magnets when its magnetic domains are aligned in one direction. Examples of ferromagnetic materials include iron, nickel, and cobalt.
02

Understand the properties of antiferromagnetic substances

An antiferromagnetic substance is a material in which neighboring magnetic moments (spins) align in opposite directions, resulting in a net magnetization of zero. These materials do not exhibit a strong attraction to magnetic fields and cannot form permanent magnets. Examples of antiferromagnetic materials include manganese oxide and chromates.
03

Understand the properties of ferrimagnetic substances

A ferrimagnetic substance is a material in which neighboring magnetic moments (spins) align in opposite directions, but with different magnitudes. The net magnetization is non-zero, and these materials can exhibit strong attraction to magnetic fields and can form permanent magnets. Examples of ferrimagnetic materials include magnetite and some ferrites.
04

Identify the magnetic material that cannot be used to make permanent magnets

Based on the properties of the three magnetic materials, we can conclude that an antiferromagnetic substance cannot be used to make permanent magnets, as its net magnetization is zero. Ferromagnetic and ferrimagnetic substances, on the other hand, can be used to make permanent magnets due to their strong attraction to magnetic fields and non-zero net magnetization.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Ferromagnetic
Ferromagnetic materials have a unique property. They are strongly attracted to magnetic fields. This is due to their atomic structure, where their magnetic domains align in one direction. Now, what are magnetic domains? Think of them as tiny magnets within a substance. When many tiny magnets align in the same direction, they create a strong overall magnetic field.

You can find ferromagnetic materials in everyday objects, such as:
  • Iron
  • Nickel
  • Cobalt
These materials are quite useful in making permanent magnets. This is because their aligned magnetic domains do not lose orientation easily. Thus, once magnetized, they retain their magnetism for a long time.

In summary, ferromagnetic substances are ideal for creating permanent magnets due to their strong attraction to magnets and ability to maintain their magnetic alignment.
Antiferromagnetic
Antiferromagnetic materials have an interesting feature where neighboring magnetic moments, or spins, align in opposite directions. This opposite alignment leads to a net magnetization of zero. In simpler terms, it's like two people pushing against each other with equal strength. The result? They don't move at all.

This zero net magnetization means that these materials do not exhibit a strong attraction to magnetic fields. Therefore, they cannot be used in making permanent magnets.

Common examples of antiferromagnetic materials include:
  • Manganese oxide
  • Chromates
Despite their lack of usefulness in permanent magnet creation, antiferromagnetic materials are significant in other areas, such as spintronics. Spintronics is a field that takes advantage of the electron's spin to store and process information.
Ferrimagnetic
Ferrimagnetic materials share some similarities with both ferromagnetic and antiferromagnetic substances. They have neighboring magnetic moments aligned in opposite directions, similar to antiferromagnetic materials. However, the magnitude of these moments is different, leading to a non-zero net magnetization.

Because of this, ferrimagnetic materials can exhibit a strong attraction to magnetic fields, making them capable of forming permanent magnets. They are used in applications where ferrites perform better than pure metals due to their electrical insulative properties.

Some typical ferrimagnetic materials include:
  • Magnetite
  • Some ferrites (used in transformers and inductors)
To sum up, ferrimagnetic substances, with their non-zero net magnetization, offer a combination of benefits for both electrical insulation and permanent magnet formation.

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Most popular questions from this chapter

Write the formula for each of the following compounds, being sure to use brackets to indicate the coordination sphere: (a) triamminetriaquachromium(III) nitrate (b) dichlorobis(ethylenediamine)platinum(II) (c) pentacarbonyliron(0) (d) ammonium diaquabis(oxalato)Co(II) (e) tris(bipyridyl)cobalt(III) sulfate

Crystals of hydrated chromium(III) chloride are green, have an empirical formula of \(\mathrm{CrCl}_{3} \cdot 6 \mathrm{H}_{2} \mathrm{O},\) and are highly soluble, (a) Write the complex ion that exists in this compound. (b) If the complex is treated with excess \(\mathrm{AgNO}_{3}(a q)\), how many moles of AgCl will precipitate per mole of \(\mathrm{CrCl}_{3} \cdot 6 \mathrm{H}_{2} \mathrm{O}\) dissolved in solution? (c) Crystals of anhydrous chromium(III) chloride are violet and insoluble in aqueous solution. The coordination geometry of chromium in these crystals is octahedral, as is almost always the case for \(\mathrm{Cr}^{3+}\). How can this be the case if the ratio of \(\mathrm{Cr}\) to Cl is not \(1: 6 ?\)

Explain why the transition metals in periods 5 and 6 have nearly identical radii in each group.

Draw the crystal-field energy-level diagrams and show the placement of \(d\) electrons for each of the following: (b) \(\left[\mathrm{Mn}\left(\mathrm{H}_{2} \mathrm{O}\right)_{6}\right]^{2+}\), (a) \(\left[\mathrm{Cr}\left(\mathrm{H}_{2} \mathrm{O}\right)_{6}\right]^{2+}\) (four unpaired electrons), (a high-spin complex), (c) \(\left[\mathrm{Ru}\left(\mathrm{NH}_{3}\right)_{5}\left(\mathrm{H}_{2} \mathrm{O}\right)\right]^{2+}\) (a low-spin complex), (d) \(\left[\mathrm{IrCl}_{6}\right]^{2-}\) (a low-spin complex), (e) \(\left[\mathrm{Cr}(\mathrm{en})_{3}\right]^{3+}\), (f) \(\left[\mathrm{NiF}_{6}\right]^{4-}\).

A classmate says, “A weak-field ligand usually means the complex is high spin." Is your classmate correct? Explain.
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