https://qbase.texpertssolutions.com/index.php?action=history&feed=atom&title=QuantumQuantum - Revision history2026-05-15T11:17:24ZRevision history for this page on the wikiMediaWiki 1.43.1https://qbase.texpertssolutions.com/index.php?title=Quantum&diff=79&oldid=prevThakshashila: Created page with "= Quantum: Definition and Mathematical Representation = == Introduction == In physics, the term '''quantum''' refers to the smallest possible discrete unit of any physical property. The concept originates from '''quantum mechanics''', a fundamental theory that describes the behavior of matter and energy on atomic and subatomic scales. The term "quantum" (plural: "quanta") was first introduced in the early 20th century to explain phenomena that classical physics could n..."2025-05-23T07:15:53Z<p>Created page with "= Quantum: Definition and Mathematical Representation = == Introduction == In physics, the term '''quantum''' refers to the smallest possible discrete unit of any physical property. The concept originates from '''quantum mechanics''', a fundamental theory that describes the behavior of matter and energy on atomic and subatomic scales. The term "quantum" (plural: "quanta") was first introduced in the early 20th century to explain phenomena that classical physics could n..."</p>
<p><b>New page</b></p><div>= Quantum: Definition and Mathematical Representation =<br />
<br />
== Introduction ==<br />
In physics, the term '''quantum''' refers to the smallest possible discrete unit of any physical property. The concept originates from '''quantum mechanics''', a fundamental theory that describes the behavior of matter and energy on atomic and subatomic scales.<br />
<br />
The term "quantum" (plural: "quanta") was first introduced in the early 20th century to explain phenomena that classical physics could not, such as blackbody radiation and the photoelectric effect.<br />
<br />
== Key Concepts ==<br />
<br />
=== 1. Quantization ===<br />
Many physical quantities, such as energy or angular momentum, are not continuous but occur in discrete levels. For example, the energy of an electron in a hydrogen atom is quantized.<br />
<br />
<math><br />
E_n = -\frac{13.6\, \text{eV}}{n^2}, \quad n = 1, 2, 3, \ldots<br />
</math><br />
<br />
Where:<br />
* <math>E_n</math> is the energy of the <math>n</math>-th level,<br />
* <math>n</math> is the principal quantum number.<br />
<br />
=== 2. Planck’s Quantum Hypothesis ===<br />
Energy is emitted or absorbed in discrete packets (quanta), given by:<br />
<br />
<math><br />
E = h f<br />
</math><br />
<br />
Where:<br />
* <math>E</math> is the energy of a quantum,<br />
* <math>h</math> is Planck’s constant <math>(6.626 \times 10^{-34}\, \text{Js})</math>,<br />
* <math>f</math> is the frequency of the radiation.<br />
<br />
=== 3. Wave-Particle Duality ===<br />
Particles such as electrons exhibit both wave-like and particle-like properties.<br />
<br />
* de Broglie wavelength:<br />
<br />
<math><br />
\lambda = \frac{h}{p}<br />
</math><br />
<br />
Where:<br />
* <math>\lambda</math> is the wavelength,<br />
* <math>p</math> is momentum,<br />
* <math>h</math> is Planck’s constant.<br />
<br />
=== 4. Heisenberg Uncertainty Principle ===<br />
It is impossible to simultaneously know the exact position and momentum of a particle:<br />
<br />
<math><br />
\Delta x \cdot \Delta p \geq \frac{\hbar}{2}<br />
</math><br />
<br />
Where:<br />
* <math>\Delta x</math> is the uncertainty in position,<br />
* <math>\Delta p</math> is the uncertainty in momentum,<br />
* <math>\hbar = \frac{h}{2\pi}</math> is the reduced Planck’s constant.<br />
<br />
== Schrödinger Equation ==<br />
<br />
The central equation of non-relativistic quantum mechanics describes how the quantum state evolves over time:<br />
<br />
<math><br />
i\hbar \frac{\partial}{\partial t} \Psi(x, t) = \hat{H} \Psi(x, t)<br />
</math><br />
<br />
Where:<br />
* <math>\Psi(x, t)</math> is the wavefunction,<br />
* <math>\hat{H}</math> is the Hamiltonian operator,<br />
* <math>i</math> is the imaginary unit.<br />
<br />
The solution <math>\Psi</math> gives the probability amplitude. The probability density is:<br />
<br />
<math><br />
P(x, t) = |\Psi(x, t)|^2<br />
</math><br />
<br />
== Quantum Numbers ==<br />
<br />
Each quantum system is described using a set of quantum numbers:<br />
<br />
* Principal quantum number <math>n</math><br />
* Angular momentum quantum number <math>l</math><br />
* Magnetic quantum number <math>m_l</math><br />
* Spin quantum number <math>m_s</math><br />
<br />
These define the allowed states of electrons in atoms.<br />
<br />
== Applications of Quantum Theory ==<br />
<br />
* Atomic structure and spectra<br />
* Semiconductors and transistors<br />
* Quantum computing<br />
* Superconductivity<br />
* Lasers<br />
* Nuclear and particle physics<br />
<br />
== See Also ==<br />
* [[Quantum Mechanics]]<br />
* [[Wave-Particle Duality]]<br />
* [[Planck's Constant]]<br />
* [[Heisenberg Uncertainty Principle]]<br />
* [[Schrödinger Equation]]<br />
* [[Quantum Numbers]]<br />
* [[Photon]]<br />
* [[Electron Configuration]]</div>Thakshashila