B
Si
Ge
As
Sb
Te
Po
SEMIMETALS • SEMICONDUCTORS

METALLOIDS

The semiconductor revolution starts here - from silicon chips powering billions of devices to solar panels harvesting the sun's energy

7
Elements
1.1 eV
Si Band Gap
90%
Tech Uses Si

The Bridge Between Worlds

Metalloids occupy a unique position in the periodic table, exhibiting properties intermediate between metals and non-metals. This duality makes them the perfect semiconductors - materials that can conduct electricity under some conditions but not others. This controllable conductivity forms the foundation of all modern electronics, from the simplest diode to the most complex microprocessor.

Silicon, the second most abundant element in Earth's crust, has become the backbone of the digital age. Combined with germanium's early transistor applications, arsenic and boron as dopants, and emerging technologies using antimony and tellurium, metalloids have enabled the information revolution that defines our modern world.

The Metalloid Elements

5
B
Boron
10.81 u
14
Si
Silicon
28.085 u
32
Ge
Germanium
72.63 u
33
As
Arsenic
74.922 u
51
Sb
Antimony
121.76 u
52
Te
Tellurium
127.60 u
84
Po
Polonium
209 u

Semiconductor Band Gaps

Conduction Band
Band Gap
(0.7-2.0 eV)
Valence Band

The band gap energy determines a semiconductor's electrical and optical properties. Silicon's 1.1 eV gap makes it ideal for electronic devices, while larger gaps enable high-frequency and high-power applications.

Key Properties Comparison

Element Symbol Band Gap (eV) Melting Point (°C) Primary Use Conductivity Type
Boron B 1.5 2076 P-type dopant Semiconductor
Silicon Si 1.1 1414 Microchips, Solar cells Semiconductor
Germanium Ge 0.7 938 Fiber optics, IR optics Semiconductor
Arsenic As 1.2 817 N-type dopant Semimetal
Antimony Sb 0.2 631 Flame retardants Semimetal
Tellurium Te 0.3 450 Solar panels, Thermoelectrics Semiconductor

Powering the Digital Age

Silicon Chips
Modern processors contain billions of transistors etched onto silicon wafers, with features as small as 3 nanometers - thousands of times thinner than human hair.
Solar Technology
Silicon photovoltaic cells convert sunlight directly into electricity, with modern panels achieving over 26% efficiency in laboratory conditions.
Fiber Optics
Germanium-doped silica fibers transmit data at the speed of light, enabling global internet connectivity with minimal signal loss over thousands of kilometers.
LED Technology
Gallium arsenide and other III-V semiconductors produce efficient light emission, revolutionizing lighting and display technologies worldwide.

Silicon Solar Cell

Each solar cell contains a p-n junction where boron-doped (p-type) and phosphorus-doped (n-type) silicon meet, creating an electric field that separates electron-hole pairs generated by sunlight.

Future Technologies

Quantum Computing

Silicon quantum dots and germanium nanowires are being developed for quantum bits (qubits) in next-generation quantum computers.

2D Materials

Borophene (2D boron) and silicene (2D silicon) promise revolutionary electronic properties for flexible electronics and ultra-fast transistors.

Thermoelectrics

Tellurium-based materials convert waste heat directly into electricity, potentially revolutionizing energy recovery in industrial processes.

Phase-Change Memory

Germanium-antimony-tellurium alloys enable non-volatile memory that's faster than flash storage and more durable than traditional RAM.

Explore More

View Periodic Table Explore Non-Metals