The Circuit Board - Your Ultimate Guide to Electronics and VLSI Design
Welcome to The Circuit Board – a knowledge hub dedicated to VLSI, semiconductors, and electronics. Our mission is to simplify complex concepts and share clear, engaging insights into the world of electronics engineering. From foundational principles to the latest industry trends, we cover a wide spectrum of topics to help learners, professionals, and enthusiasts stay informed.
In the fascinating world of electronics, semiconductors form the foundation of all modern devices — from the smallest microchips to the most complex integrated circuits. To understand how electronic components like diodes, transistors, and amplifiers work, it’s essential to first grasp what semiconductors are and how their conductivity can be controlled.
Semiconductors
Atoms may combine to form a solid crystalline material through covalent bonding. In silicon, each atom forms covalent bonds with four neighboring silicon atoms, creating a strong and stable crystal lattice. A pure silicon crystal, without any impurities, is called intrinsic silicon.
At room temperature, intrinsic silicon has very limited conductivity. Some valence electrons gain sufficient thermal energy to jump from the valence band to the conduction band. When this happens, free electrons are generated in the conduction band, and vacancies are created in the valence band. These vacancies are called holes.
If a voltage source is applied across intrinsic silicon, the thermally generated free electrons in the conduction band will move toward the positive terminal of the voltage source. This movement produces current in the material, which is called electron current. Simultaneously, holes in the valence band contribute to conduction. When an electron from a neighboring atom moves to fill a hole, it leaves behind a new hole. This movement of holes generates hole current.
Thus, intrinsic silicon shows conduction through both free electrons and holes, but the conductivity is very low.
Extrinsic Semiconductors
The conductivity of semiconductors can be greatly improved by a process called doping, in which controlled amounts of impurities are added to pure silicon. Depending on the type of impurity added, the resulting material can be either n-type or p-type semiconductor.
N-Type Semiconductor (Pentavalent Impurity)
When a pentavalent impurity (an atom with five valence electrons, such as arsenic, phosphorus, bismuth, or antimony) is added to silicon, four of its valence electrons form covalent bonds with four neighboring silicon atoms. The fifth electron, however, does not participate in bonding and remains loosely bound to the dopant atom.
This extra electron requires very little energy (about 0.01 eV) to move into the conduction band, which is far less than the 1.1 eV required to break a silicon-silicon covalent bond. At room temperature, almost all these donor electrons are free to move, creating a large number of charge carriers without disturbing the crystal lattice.
As a result, n-type semiconductors exhibit much higher electrical conductivity at room temperature compared to intrinsic silicon, where only a few valence electrons can thermally jump to the conduction band. In n-type semiconductors, electrons are the majority carriers, while holes are the minority carriers.
P-Type Semiconductor (Trivalent Impurity)
When a trivalent impurity (an atom with three valence electrons, such as boron, indium, or gallium) is added to silicon, each dopant atom forms covalent bonds with three neighboring silicon atoms. This leaves one bond incomplete, resulting in the creation of a hole.
At room temperature, electrons from neighboring silicon atoms can move to fill this hole, which in turn creates a new hole at the position from where the electron moved. In this way, holes effectively move through the crystal lattice and act as charge carriers.
Thus, in a p-type semiconductor, holes are the majority carriers, while electrons are the minority carriers.
Summary
Intrinsic semiconductors are pure crystals with very low conductivity, where current is generated only by thermally excited electrons and holes. Extrinsic semiconductors are doped with impurities to enhance conductivity.
Pentavalent impurities create n-type semiconductors, where electrons are the majority carriers.
Trivalent impurities create p-type semiconductors, where holes are the majority carriers.
Conclusion
Semiconductors are the backbone of modern electronics. By understanding the difference between intrinsic and extrinsic types, we unlock how materials can be engineered to conduct electricity in controlled ways — forming the base for diodes, transistors, and integrated circuits.
Welcome back to my series on Analog Electronics! In my previous blogs, we explored the fundamental building blocks of matter — atoms, electrons, protons, and neutrons — and how these tiny particles form the foundation of all electronic materials.
Today, we take the next step in understanding how materials conduct electricity by diving into valence bands, conduction bands, and band gaps. These concepts are crucial for explaining why some materials are conductors, semiconductors, insulators, or dielectrics — and how they behave in electronic devices. By the end of this blog, you’ll understand how electrons move, what limits their motion, and why certain materials can carry current while others cannot.
Valence Band
The valence band is the outermost energy band of an atom that contains electrons. The electrons in this band, called valence electrons, are not completely free but can participate in chemical bonding or jump to the conduction band if they gain sufficient energy.
Example: Silicon (Si)
Atomic Number: 14
Electron Configuration: 1s² 2s² 2p⁶ 3s² 3p²
Total Electrons in Outer Shell (n = 3): 4 → These 4 electrons occupy the valence band.
Valence Electrons: 4 → These determine silicon’s bonding and electrical properties.
In short: For silicon, the valence band contains 4 electrons from the outermost shell, and these are the electrons that can participate in conduction or bonding.
Valence Electrons
Valence electrons occupy the valence band and are located in the outermost shell of an atom. These electrons are critical in determining an element’s bonding behavior, reactivity, and electrical properties.
Conduction Band
The conduction band lies just above the valence band. When a valence electron gains enough energy from an external source — like heat, light, or an electric field — it can move from the valence band into the conduction band.
Once in the conduction band, electrons are free to move within the material and contribute to electrical current. At absolute zero, the conduction band is empty, but as temperature or energy input increases, more electrons make this transition.
Simply put: The conduction band is where electrons become free charge carriers, enabling the conduction of electricity.
Band Gap (Energy Gap)
The band gap (Eg) is the energy difference between the valence band and the conduction band. For an electron to move from the valence band to the conduction band, it must gain energy equal to or greater than Eg.
Let’s explore the band gap for different types of materials:
1. Conductors
In conductors, the valence and conduction bands overlap, or the conduction band is partially filled. There is effectively no forbidden energy gap, so electrons can move freely to the conduction band even at room temperature. This is why metals like copper, silver, and aluminum conduct electricity so easily.
2. Semiconductors
Semiconductors, such as silicon and germanium, have a small band gap — typically between 0.5 and 3 eV. At absolute zero, the conduction band is empty and the valence band is full. At room temperature, or with a small energy input (heat, light, or voltage), electrons can jump to the conduction band.
This property makes semiconductors unique, as their conductivity can be controlled.
Example band gaps:
Silicon → ~1.1 eV
Germanium → ~0.7 eV
Gallium Arsenide → ~1.4 eV
3. Insulators
Insulators, like glass, rubber, and diamond, have a large band gap, usually greater than 3 eV. The energy required for an electron to move from the valence band to the conduction band is far higher than what is available from thermal energy at room temperature.
As a result, electrons cannot become free, and insulators do not conduct electricity under normal conditions.
4. Dielectrics
Dielectrics are materials that do not conduct electricity under normal conditions but can support an electric field. Unlike conductors, electrons in dielectrics are tightly bound and cannot move freely to create current. When an external electric field is applied, charges shift slightly, creating polarization.
This allows dielectrics to store electrical energy, making them essential in devices like capacitors. Common dielectric materials include mica, ceramic, glass, and certain plastics.
Dielectrics typically have a very large band gap > 3 eV same as insulators:
Valence Band: Fully filled with electrons
Conduction Band: Completely empty
Forbidden Energy Gap: Extremely wide, preventing electron movement under normal conditions
In short: Dielectrics do not conduct electricity but act as excellent insulators while storing energy through polarization.
Summary Table
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Difference Between Insulators and Dielectrics
Insulators block unwanted current. Their electrons are tightly bound, and the large band gap prevents conduction. Examples include rubber coatings on wires or glass layers in electrical equipment.
Dielectrics are a special type of insulator. While they also do not conduct electricity, they can store energy when exposed to an electric field due to polarization. Dielectrics are widely used in capacitors, transformers, and other devices requiring energy storage or insulation.
Key Point: All dielectrics are insulators, but not all insulators are dielectrics. The main difference is that dielectrics actively store energy through polarization, while ordinary insulators only prevent current flow.
Conclusion
Understanding the valence band, conduction band, and band gap gives us a clear picture of how materials behave electrically. We’ve seen how:
Valence electrons in the outermost shell determine bonding and reactivity.
Conduction bands allow electrons to move freely, enabling current.
The band gap explains why conductors, semiconductors, insulators, and dielectrics behave differently.
This knowledge forms the foundation for exploring more complex electronic devices, like diodes, transistors, and operational amplifiers, which we will cover in upcoming blogs.
By connecting the atomic-level view from my previous posts to the electrical behavior of materials, you now have the full picture of how electrons and energy bands shape the world of electronics.
In the last blog, we explored the structure of an atom. But what is an atom really made of? At its heart, three tiny particles form the foundation of everything around us: electrons, protons, and neutrons. Let’s go step by step to understand them in the simplest way possible.
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Electrons — The Tiny Travelers Around the Nucleus
An electron is a tiny, fundamental particle that carries a negative electric charge. It is one of the basic building blocks of matter. Electrons are the lightest of the three particles. They move around the nucleus in regions called orbitals.
Nature: Electrons belong to a family of particles called leptons. This means they are fundamental — not made of anything smaller that we know of.
Charge: Each electron carries a negative charge (–1e ≈ –1.6 × 10⁻¹⁹ C). This is an intrinsic property, like a built-in tag of the particle.
Mass: Very light — Almost 1836 times lighter than a proton.
👉 Without electrons, there would be no chemical bonding, no electricity, and no electronics. They are the real “workers” of the atomic world.
Why are Electrons Negative?
The electron’s negative charge is a fundamental property of nature. It is not made up of smaller parts that give it this charge — instead, the electron itself is a lepton, a type of elementary particle. That means its negative charge is intrinsic and cannot be broken down or explained in terms of smaller components, unlike the proton whose positive charge comes from the combination of quarks inside it.
What are Leptons?
Leptons are one of the two main families of fundamental particles (the other being quarks). They are elementary, meaning they are not made of smaller building blocks.
Types of Leptons
There are six leptons in total, grouped in three generations:
1] First Generation (stable, found in everyday matter)
Electron (e⁻) → charge = –1
Electron neutrino (νₑ) → neutral
2] Second Generation (heavier, unstable)
Muon (μ⁻) → like a heavy electron
Muon neutrino (ν_μ) → neutral
3] Third Generation (even heavier, unstable)
Tau (Ï„⁻) → very heavy lepton
Tau neutrino (ν_Ï„) → neutral
Key Properties of Leptons
They do not feel the strong nuclear force (the force that binds quarks inside protons and neutrons).
They interact through the weak force, gravity, and (if charged) electromagnetism.
Stability: Only the electron is stable in ordinary matter. The others decay quickly.
Why are Leptons Important?
Electrons form atoms, flow as electric current, and make chemistry possible.
Neutrinos play a vital role in nuclear reactions (like those in the Sun).
Muons and tau leptons help scientists test the laws of physics in high-energy experiments.
✅ In summary: Electrons are negative simply because that’s their fundamental identity as leptons. Unlike protons, whose charge comes from quarks, the electron’s charge is intrinsic — it is “born negative” and cannot be divided further.
The Role of Electrons
Electrons are far more than just “orbiting particles.” Their arrangement defines almost everything about matter and electronics:
Chemical Properties: The number and arrangement of electrons decide how atoms bond together. For example, silicon forms stable bonds that make it a perfect semiconductor.
Electrical Conductivity: In metals, outer electrons (valence electrons) are loosely held and move freely → good conductors. In insulators, electrons are tightly bound → poor conductors. In semiconductors, electrons can move only under certain conditions → basis of modern electronics.
Electronics and Current Flow: Electric current in circuits is the movement of electrons per unit time in the conductor.
✅ In summary: Electrons revolve around the nucleus because the balance between attractive force from the nucleus and their quantum-mechanical energy keeps them in stable orbitals. They cannot exist inside the nucleus since they don’t feel the strong nuclear force. Their arrangement determines an element’s chemistry, conductivity, and role in electronics — making electrons the real “players” in both physics and technology
Protons — The Positive Pillars of the Nucleus
A proton is a positively charged particle found at the heart of every atom, sitting tightly inside the nucleus along with neutrons. Unlike electrons, protons are not fundamental — they are made up of smaller particles called quarks. Protons give an atom its identity, since the number of protons decides which element it is.
Nature: Protons are composite particles, made up of three quarks (two “up” quarks and one “down” quark) held together by the strong nuclear force.
Charge: Each proton carries a positive charge (+1e ≈ +1.6 × 10⁻¹⁹ C), exactly equal in size but opposite in sign to the charge of an electron.
Mass: Much heavier than an electron — about 1836 times more massive. This makes them contribute significantly to the atom’s weight.
Why Are Protons Positive?
To understand why protons carry a positive charge, we need to look deeper inside them — into their building blocks called quarks.
What are Quarks?
Quarks are one of the two main families of fundamental particles (the other being leptons). Unlike leptons, quarks do feel the strong nuclear force, which makes them the building blocks of protons and neutrons. In fact, without quarks, atoms could not exist at all. Quarks are never found alone in nature; they are always “confined” together inside particles such as protons, neutrons, and many others.
Types of Quarks (Flavors)
There are six types (flavors) of quarks, grouped in three generations:
First Generation (stable, form everyday matter) Up quark (u) → charge = +2/3e Down quark (d) → charge = –1/3e 👉 Protons and neutrons are made from up and down quarks.
Third Generation (very heavy, unstable) Top quark (t) → charge = +2/3e Bottom quark (b) → charge = –1/3e
How Do Quarks Form Protons and Neutrons?
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Proton = 2 up quarks + 1 down quark Charge = (2 × +2/3) + (–1/3) = +1e
Neutron = 1 up quark + 2 down quarks Charge = (+2/3) + (2 × –1/3) = 0
👉 That’s why protons are positive, neutrons are neutral.
Key Properties of Quarks
Charge: Fractional charges (either +2/3 or –1/3 of an electron’s charge).
Forces: Feel all four fundamental forces: strong force, weak force, electromagnetism, gravity. Strong force is the most important, as it “glues” quarks together using particles called gluons.
Confinement: Quarks are never observed alone; they are always locked inside groups (like protons/neutrons).
Stability: Only up and down quarks make stable matter.
Why are Quarks Important?
They form protons and neutrons, the core of atoms.
Their combinations give rise to all atomic matter in the universe.
Understanding quarks helps scientists study the universe at its most fundamental level through particle physics and collider experiments.
The Role of Protons
Protons are not just “particles inside the nucleus.” They define the very identity and stability of every atom:
Element Identity: The number of protons in an atom’s nucleus is called the atomic number, and this uniquely defines the element. 👉 1 proton = Hydrogen, 6 protons = Carbon, 14 protons = Silicon.
Positive Charge & Attraction: Protons provide the positive charge that holds negatively charged electrons in orbit around the nucleus. Without this attraction, atoms could not form.
Stability with Neutrons: Protons alone would repel each other due to like charges. Neutrons act as buffers, but protons are still the essential “anchors” of the nucleus, tied together by the strong nuclear force.
Mass Contribution: Along with neutrons, protons account for nearly all of an atom’s mass, giving matter its “weight.”
Role in Chemistry and Electronics: The number of protons decides how many electrons an atom can hold, which in turn sets its chemical behavior. In semiconductors, protons in the nucleus indirectly determine how electrons arrange in energy bands.
✅ In summary: Protons are the identity holders of atoms, the positive anchors that attract electrons, and a key part of nuclear stability. Without protons, there would be no distinct elements, no stable nuclei, and no framework for chemistry or electronics to exist.
Neutrons — The Neutral Guardians of the Nucleus
A neutron is one of the two heavy particles (along with protons) found inside the nucleus of an atom. As the name suggests, neutrons are electrically neutral — they carry no charge at all. Despite being neutral, they play a vital role in stabilizing the atom.
Nature of Neutrons
Unlike electrons, neutrons are not fundamental particles.
They are composite particles, made up of smaller particles called quarks (just like protons).
Quark Structure of Neutrons
Neutron = 1 up quark (+2/3e) + 2 down quarks (–1/3e each)
Total charge = (+2/3) + (–1/3) + (–1/3) = 0 👉 This is why neutrons are neutral.
Properties of Neutrons
Charge: 0 (neutral).
Mass: Very slightly heavier than a proton. (~1.675 × 10⁻²⁷ kg).
Location: Always found in the nucleus, never orbiting outside.
Forces: Feel all four fundamental forces: strong force, weak force, electromagnetism, and gravity. Strong force binds them with protons to keep the nucleus together.
Role of Neutrons in Atoms
Stabilizers: Neutrons act as a “buffer” between positively charged protons. Without neutrons, the repulsive force between protons would make the nucleus unstable and break apart.
Isotopes: Different numbers of neutrons in the nucleus create isotopes of the same element (like Carbon-12 and Carbon-14).
Nuclear Reactions: Free neutrons (outside the nucleus) are unstable and decay in about 15 minutes into a proton, electron, and antineutrino. But inside nuclei, they are stable and essential for nuclear fission and fusion.
Why Are Neutrons Important?
They make atoms stable and diverse.
They enable nuclear reactions that power the Sun, nuclear reactors, and nuclear medicine.
Without neutrons, complex matter — and life itself — could not exist.
Why Do Electrons Revolve Around the Nucleus and Not Stay Inside It?
At the heart of every atom is the nucleus, containing positively charged protons and neutral neutrons. Around this dense center move the negatively charged electrons. But why don’t electrons just fall into the nucleus, or stay trapped inside with the protons?
The answer comes from a combination of forces and quantum mechanics:
Electrostatic Attraction (Pulling Inward) - Protons are positive, electrons are negative. - Opposite charges attract, so naturally electrons are pulled toward the nucleus. - If this were the only effect, electrons would collapse into the nucleus.
Electron’s Energy and Motion (Keeping Away) - Electrons are not static — they have energy and behave more like moving waves than tiny balls. - This energy keeps them from simply “falling” into the nucleus, much like Earth doesn’t fall into the Sun because of its orbital motion.
Quantum Mechanics (Allowed Energy Levels) - Quantum mechanics tells us that electrons cannot exist at just any distance from the nucleus. - They are restricted to specific energy levels (or orbitals). - These orbitals act like “permitted zones” where electrons are most likely to be found. - Going inside the nucleus would require energy states that simply don’t exist for electrons.
Why Not Inside the Nucleus? - Inside the nucleus, the strong nuclear force binds protons and neutrons. - But electrons are leptons — they don’t feel the strong force, only the electromagnetic one. - Without the strong force, electrons cannot stay bound inside the nucleus. Instead, they remain outside, held by electric attraction at allowed energy levels.
Why Do Protons Stay Inside the Nucleus and Not Drift Outside?
The nucleus of an atom is a dense core containing protons and neutrons. While electrons orbit outside, protons remain tightly packed inside. But why don’t protons escape, given that they repel each other due to like charges?
The answer lies in the strong nuclear force and the nature of quarks:
Electrostatic Repulsion (Pushing Outward) - Protons are all positively charged, so they naturally repel each other. - If electrostatic force were the only effect, the nucleus would fly apart.
Strong Nuclear Force (Holding Together) - Protons are made of quarks, and quarks feel the strong nuclear force, the strongest force in nature at short distances. - This force acts like a “glue,” holding quarks tightly together inside protons, and holding protons and neutrons together inside the nucleus. - At the distances inside the nucleus, the strong force overpowers the electrostatic repulsion between protons.
Quark Confinement (Why They Can’t Escape) - Quarks are never found alone in nature — they are always confined inside protons and neutrons. - This means protons themselves cannot simply leave the nucleus without breaking the quark bonds, which requires enormous energy.
Role of Neutrons - Neutrons help reduce proton-proton repulsion by providing additional strong-force binding without adding more positive charge. - Together, protons and neutrons form a stable, tightly bound nucleus.
✅ In summary: Protons stay inside the nucleus because the strong nuclear force holds them together at extremely short distances, overpowering their natural repulsion. Without this force, atomic nuclei — and all matter — would not exist.
✨ What’s Next?
In the next blog, we’ll dive deeper into the behavior of electrons in materials. We’ll explore conductors, semiconductors, and insulators, and understand how valence electrons and conduction electrons determine the flow of electricity in different substances.
✅ Conclusion
We’ve now uncovered the building blocks of atoms — electrons, protons, and neutrons — and seen how their structure, charge, and interactions define the very nature of matter. Electrons orbit and carry current, protons anchor the nucleus and define elements, and neutrons stabilize the atom while allowing for isotopes. Understanding these tiny particles is the first step toward grasping the fascinating world of electronics, chemistry, and physics.