pyroelectric. In the ferroelectric materials, with the application of an electrostatic field, the
polarization can be inverted, while in the pyroelectrics not, where the polarization is par
allel to the low symmetry axis of the crystal [19]. Thus, III-nitrides are pyroelectric materials
with spontaneous polarization. This property is naturally intrinsic and it corresponds to
the bonding nature, where the geometric center of the negative and positive charges of the
crystal are not coincident. In other words, the bonding between the atoms in these com
pounds should be asymmetric, and usually, in the hexagonal crystals, the bond along the
c-axis shows to be longer and with different ionicity compared to other ones. On the other
hand, the cubic crystal structure with tetrahedral coordination shows four equivalent bonds
due to the sp3 hybridization, explaining why most of the binary III–V and II-VI semi
conductors do not have spontaneous polarization, only a piezoelectric effect.
When a mechanical strain induces a change in the electrical resistivity of a material this
phenomenon is denoted by the piezoresistive effect, and the SiC compounds are the most
favorable choice among the WBG materials. The piezoresistance also has a strong de
pendence on the crystal orientation, and it is quantified by the parameter gauge factor
(GF). This change of resistance in response to applied stress is a function of geometry and
resistivity changes.
In other words, the GF is the ratio of the per unit change in the resistance to the per unit
change in length. The gauge factor for SiC compounds is considerable, where 3C-SiC
showed to be ca. 30 for both p-type and n-type, increasing the importance of this class of
WBG semiconductors for applications in bioelectronics, such as radiofrequency wireless
communication devices [2].
13.3.2 Direct Bandgap and High Optical Transmittance
Semiconductors can have direct or indirect band gaps. In semiconductors with a direct
bandgap, the momentum of the electrons in the highest states of the valence band is
practically the same as the momentum of the holes in the lowest states of the conduction
band. In this case, the optical transitions occur right after the photon energy exceeds the
bandgap energy, and it is observed that the absorption coefficient increase together with the
photon energies. On the other hand, in the materials with indirect bandgap, the momentum
of the electrons in the valence band does not match the momentum of the holes in the
conduction band, requiring an additional emission of a phonon (collective motion of atoms
in a crystal) for change the electron momentum, and allowing the recombination.
The II–VI and III-nitride materials are known for their direct band gaps, allowing their
application in UV photosensors and optogenetics LED [2]. The possibility of synthesizing
different nanostructures of ZnO enables tuning and broadening its emission and ab
sorption wavelength. Further in ZnO nanostructures, combining the direct bandgap and
the large optical absorption can result in an efficient and sensitive photodetector over the
UV spectral range [2]. Additionally, III-nitrides and their alloys (e.g., InAlN and AlGaN)
also exhibit a tunable bandgap that can vary from the visible spectrum to infrared,
highlighting the GaN-based materials that show to be an efficient UV photodetector [2].
Materials with a bandgap greater than ca. 3.1 eV usually is considered transparent [1].
Optical transmittance can be defined as the ability for light to be conducted through a
material. Therefore, a material with high optical transmittance is essential for applications
in optoelectronics, including in optogenetics. However, it is important to keep in mind
that transmittance is dependent on the thickness, which can result in different accessible
dynamic ranges for measurements of the absorption coefficient [1]. Some WBG materials
have shown good transparency, such as ZnO [20]. From the III-nitride family, bulk GaN
Wide Bandgap Semiconductors
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