What is the Difference Between Ferroelectric and Ferromagnetic Materials?
🆚 Go to Comparative Table 🆚Ferroelectric and ferromagnetic materials are two distinct types of materials that exhibit different properties. The main differences between them are:
- Permanent field: Ferroelectric materials have a permanent electric field, while ferromagnetic materials have a permanent magnetic field.
- Dipoles: Ferroelectricity is related to electric dipoles, while ferromagnetism is related to magnetic dipoles.
- Material composition: Most ferroelectric materials do not contain any iron, and they are typically a special class of crystals, such as barium titanate (BaTiO3) or lead titanate (PbTiO3). Ferromagnetic materials, on the other hand, are often strongly attracted to an external magnetic field.
- Piezoelectricity: Ferroelectric materials are also piezoelectric, meaning that when mechanical stress is applied, they generate voltage, and when a voltage is applied, they create mechanical deformation.
Despite these differences, researchers have suggested that the characteristics of both materials could become almost identical at small enough scales, although they are caused by different elements of physics. Both classes of material have uses in electronics, particularly in data storage.
Comparative Table: Ferroelectric vs Ferromagnetic Materials
The main difference between ferroelectric and ferromagnetic materials lies in their properties and behavior. Here is a table comparing the two:
| Property | Ferroelectric Materials | Ferromagnetic Materials |
|---|---|---|
| Definition | Materials exhibiting ferroelectricity, with a spontaneous electric polarization that can be changed or reversed. | Materials that are strongly attracted to magnetic fields and exhibit a permanent magnetic moment. |
| Polarization | Can switch between polarized and non-polarized states, allowing for energy storage and piezoelectric effects. | Atoms have a permanent dipole moment, and atomic dipoles are oriented in a direction similar to the external magnetic field. |
| Magnetic Behavior | Do not exhibit permanent magnetization. | Exhibit a large magnetic dipole moment, high intensity of magnetization, and high positive magnetic susceptibility. |
| Examples | Barium titanate (BaTiO3), lead titanate (PbTiO3), and lead zirconate titanate (LZT). | Iron, nickel, and cobalt, as well as some alloys and compounds containing these elements. |
In summary, ferroelectric materials have a spontaneous electric polarization that can be reversed, while ferromagnetic materials exhibit a permanent magnetic moment. Ferroelectric materials do not exhibit permanent magnetization, whereas ferromagnetic materials have a large magnetic dipole moment and high magnetic susceptibility.
- Ferromagnetism vs Ferrimagnetism
- Magnetic Materials vs Non Magnetic Materials
- Ferromagnetism vs Antiferromagnetism
- Dia Para vs Ferromagnetic Materials
- Piezoelectric Pyroelectric vs Ferroelectric
- Hard vs Soft Magnetic Materials
- Ferrous vs Ferric
- Neodymium vs Ferrite Magnets
- Ferrous Metals vs Non Ferrous Metals
- Magnetic Force vs Electric Force
- Electromagnetism vs Magnetism
- Ferrous vs Non-Ferrous Minerals
- Electrostatic vs Electromagnetic
- Electromagnet vs Permanent Magnet
- Electrostatics vs Magnetostatics
- Electric Field vs Magnetic Field
- Magnetostriction vs Piezoelectric Effect
- Bar Magnet vs Electromagnet
- Ferrous vs Nonferrous Alloys