#Electron Cloud Model Atom Visualization

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#Electron Cloud Model Atom Visualization Reel by @modernsciencex - What Does an Atom Really Look Like? 👉 Let's explore the difference between these two atomic models and why the second one is considered more accurate
79.0K
MO
@modernsciencex
What Does an Atom Really Look Like? 👉 Let’s explore the difference between these two atomic models and why the second one is considered more accurate structure of an atom: The first part of the video depicts the atomic model proposed by Niels Bohr in 1913. While most of us are only familiar with this atomic structure, but it isn’t entirely accurate. It portrays electrons as tiny particles following well-defined paths around the nucleus, which isn’t quite how it works. The Bohr model was a stepping stone in our understanding of atoms, but it has limitations. And the second part of the video depicts the Electron Cloud Model. This model suggests electrons occupy regions or orbitals around the nucleus with a certain probability. We can’t pinpoint an electron’s exact location but predict the probability of finding it in a specific region. This explains the cloud-like appearance. The second atomic model, the electron cloud model, is considered more scientifically accurate than the Bohr model for two reasons: 1. Electron Behavior: Electrons don’t behave like miniature planets following precise paths. The electron cloud model acknowledges their wave-like nature, explaining their existence within probabilistic regions around the nucleus. 2. Spectral Lines: The electron cloud model explains the observed spectral lines of elements better than the Bohr model. These lines arise from electron transitions between energy levels within the electron cloud. 😊Did you find this fact interesting? Then, leave a ❤️ and a comment! 🎯Follow @modernsciencex for more interesting Videos!! 🌐CREDIT COMPOSITION/FORMATTING/ EDITING @glamour_physics @modernsciencex Reposted from: @glamour_physics Follow @modernsciencex For more insightful content on Science and Astronomy Video credit of Atomic Orbitals animation: Sci Pills ( YouTube channel) ☆`☆•☆ CONTENT USED FOR EDUCATIONAL PURPOSES ONLY ☆•☆•☆ #space #atom #nuclearphysics #particlephysics #quantummechanics #electron #atomic #astronomy #timetravel #universe #quantumphysics
#Electron Cloud Model Atom Visualization Reel by @go_atomico - What Does an Atom Really Look Like? 👉 Let's explore the difference between these two atomic models and why the second one is considered more accurate
41.6K
GO
@go_atomico
What Does an Atom Really Look Like? 👉 Let’s explore the difference between these two atomic models and why the second one is considered more accurate structure of an atom: The first part of the video depicts the atomic model proposed by Niels Bohr in 1913. While most of us are only familiar with this atomic structure, but it isn’t entirely accurate. It portrays electrons as tiny particles following well-defined paths around the nucleus, which isn’t quite how it works. The Bohr model was a stepping stone in our understanding of atoms, but it has limitations. And the second part of the video depicts the Electron Cloud Model. This model suggests electrons occupy regions or orbitals around the nucleus with a certain probability. We can’t pinpoint an electron’s exact location but predict the probability of finding it in a specific region. This explains the cloud-like appearance. The second atomic model, the electron cloud model, is considered more scientifically accurate than the Bohr model for two reasons: 1. Electron Behavior: Electrons don’t behave like miniature planets following precise paths. The electron cloud model acknowledges their wave-like nature, explaining their existence within probabilistic regions around the nucleus. 2. Spectral Lines: The electron cloud model explains the observed spectral lines of elements better than the Bohr model. These lines arise from electron transitions between energy levels within the electron cloud. 😊Did you find this fact interesting? Then, leave a ❤️ and a comment! Reposted from @modernsciencex & @glamour_physics (Original creators of this video) 🎯Follow @go_atomico for more interesting Videos!! 🌐CREDIT COMPOSITION/FORMATTING/ EDITING @glamour_physics @modernsciencex Video credit of Atomic Orbitals animation: Sci Pills ( YouTube channel) ☆`☆•☆ CONTENT USED FOR EDUCATIONAL PURPOSES ONLY ☆•☆•☆ #space #atom #universe #nuclearphysics #particlephysics #quantummechanics #electron #atomic #astronomy #timetravel #universe #quantumphysics
#Electron Cloud Model Atom Visualization Reel by @diversephysics - What Does an Atom Really Look Like? Let's explore the difference between these two atomic models and why the second one is considered more accurate st
62.4K
DI
@diversephysics
What Does an Atom Really Look Like? Let's explore the difference between these two atomic models and why the second one is considered more accurate structure of an atom: The first part of the video depicts the atomic model proposed by Niels Bohr in 1913. While most of us are only familiar with this atomic structure, but it isn't entirely accurate. It portrays electrons as tiny particles following well-defined paths around the nucleus, which isn't quite how it works. The Bohr model was a stepping stone in our understanding of atoms, but it has limitations. And the second part of the video depicts the Electron Cloud Model. This model suggests electrons occupy regions or orbitals around the nucleus with a certain probability. We can't pinpoint an electron's exact location but predict the probability of finding it in a specific region. This explains the cloud-like appearance. The second atomic model, the electron cloud model, is considered more scientifically accurate than the Bohr model for two reasons: 1. Electron Behavior: Electrons don't behave like miniature planets following precise paths. The electron cloud model acknowledges their wave-like nature, explaining their existence within probabilistic regions around the nucleus. 2. Spectral Lines: The electron cloud model explains the observed spectral lines of elements better than the Bohr model. These lines arise from electron transitions between energy levels within the electron cloud. Did you find this fact interesting? Then, leave a and a comment! Follow @diversephysics for more interesting Videos!! CREDIT COMPOSITION/FORMATTING/EDITING @glamour_physics @modernsciencex Reposted from: @glamour_physics Follow @modernsciencex For more insightful content on Science and Astronomy Video credit of Atomic Orbitals animation: Sci Pills (YouTube channel) ☆☆☆ CONTENT USED FOR EDUCATIONAL PURPOSES ONLY ☆☆☆ #physics #Physicist #physicslovers #cosmos #STEM #stemeducation #space #atom #universe #nuclearphysics #particlephysics #quantummechanics #electron #atomic #astronomy #timetravel #universe #quantumphysics #philosophy #philosopher #neildegrassetyson #atomicstructure #bohr #insta #instareels
#Electron Cloud Model Atom Visualization Reel by @glamour_physics (verified account) - ✨️What does an atom look like?✨️ ⬇️⬇️ Did you know? The structure of the atom, according to Bohr's model and other early 20th-century models, can b
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GL
@glamour_physics
✨️What does an atom look like?✨️ ⬇️⬇️ Did you know? The structure of the atom, according to Bohr's model and other early 20th-century models, can be described in physical terms quite simply: Atomic Nucleus: At the center of the atom is the nucleus, composed of protons (positively charged particles) and neutrons (neutral particles). This nucleus contains most of the atom's mass. Electrons: Electrons are negatively charged particles that orbit the nucleus in specific layers or energy levels. In Bohr's model, these levels are well-defined, and electrons can move between levels by absorbing or emitting energy in the form of photons. Quantum Models: Following Bohr's model, more advanced models incorporating quantum mechanics principles were developed. Let's start discussing atomic orbitals, wave functions, eigenstates, Hilbert space, Heisenberg's uncertainty principle, radial distribution functions, etc. Etc. All of these were introduced following Bohr's atomic model and Scattering Rutherford . These models treat the positions of electrons not as precise orbits but as "probability clouds" that indicate where an electron is most likely to be found at any given time. These initial physical models of the atom laid the groundwork for modern understanding of atomic structure, which continues to evolve with further research and technological developments. ✨️✨️✨️ 🌐Music: Gangsta - Nobody knows (Remixed) 🌐Clips used in this uploaded editing:Atomic Orbitals animation credit: Sci Pills ( YouTube channel) ☆•☆•☆ ☆▪︎☆▪︎☆ 🌐CREDIT COMPOSITION/FORMATTING/ EDITING/FURTHER PROCESSING @glamour_physics @modernsciencex CONTENT USED FOR EDUCATIONAL PURPOSES ONLY ☆•☆•☆ For more insightful content on Science and Astronomy 🌐FOLLOW @glamour_physics ☆▪︎☆▪︎☆ For the pics/clips used in this uploaded editing: All Rights And Credits Reserved To Respected Owner (s) No copyright infringement intended . Copyright issues? DM us. ☆▪︎☆▪︎☆ ⚠️IMPORTANT⚠️ Don't repost without our permission #atom #nuclearphysics #atomic #atomicphysics #fisica #bohr #quantumtheory #quantummechanics #particlephysics Atomo Atoms
#Electron Cloud Model Atom Visualization Reel by @bestchemclub - ATOMIC MODEL THROUGH HISTORY 1. John Dalton's Model (1803) - Solid Sphere Model Overview: Dalton proposed that all matter is made up of indivisible
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BE
@bestchemclub
ATOMIC MODEL THROUGH HISTORY 1. John Dalton’s Model (1803) – Solid Sphere Model Overview: Dalton proposed that all matter is made up of indivisible particles called atoms. He imagined atoms as tiny, solid spheres—like billiard balls. Key Ideas: Atoms of the same element are identical in mass and properties. Atoms cannot be created, divided, or destroyed. Compounds form when atoms of different elements combine in fixed ratios. Importance: First scientific model of the atom based on experimental evidence (like gas laws). Laid the groundwork for modern chemistry. --- 2. J.J. Thomson’s Model (1904) – Plum Pudding Model Overview: After discovering the electron, Thomson proposed that atoms are made of a positively charged substance with negatively charged electrons scattered within it—like raisins in pudding. Key Ideas: Atoms are divisible. Electrons are negatively charged subatomic particles. The rest of the atom is a blob of positive charge to balance the electrons. Importance: First model to show that atoms have internal structure. Introduced the idea of subatomic particles. --- 3. Ernest Rutherford’s Model (1911) – Nuclear Model Overview: Conducted the gold foil experiment where alpha particles were fired at a thin sheet of gold. Most passed through, but some were deflected at large angles. Key Ideas: Atoms are mostly empty space. A small, dense, positively charged nucleus is at the center. Electrons orbit around this nucleus. Importance: Disproved the plum pudding model. Introduced the concept of a nucleus. --- 4. Niels Bohr’s Model (1913) – Planetary Model Overview: Bohr expanded on Rutherford’s model using discoveries from quantum theory. Key Ideas: Electrons orbit the nucleus in fixed paths or “energy levels.” Each level has a specific amount of energy. Electrons can jump to higher levels when energy is absorbed and fall back down when energy is released (as light). Importance: Explained why atoms emit light in specific colors (atomic spectra). Added the concept of quantized energy levels. --- 5. Erwin Schrödinger’s Model (1926) – Quantum Mechanical Model (Electron Cloud Model) Overview: Schrödinger used complex
#Electron Cloud Model Atom Visualization Reel by @thedeepastronomy - The first-ever direct visualization of an electron's orbit inside a hydrogen atom. It's not a single particle captured in motion, but rather a represe
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TH
@thedeepastronomy
The first-ever direct visualization of an electron’s orbit inside a hydrogen atom. It's not a single particle captured in motion, but rather a representation of the electron's probability cloud—the area where it is most likely to be found. This groundbreaking image offers a tangible glimpse into the strange world of quantum mechanics and a powerful testament to the advancements in modern physics. It's a profound reminder of the unseen universe that exists on a subatomic scale. Check the study - Stodolna, Aneta S., et al. “Hydrogen Atoms under Magnification: Direct Observation of the Nodal Structure of Stark States.” Physical Review Letters, vol. 110, no. 21, 2013
#Electron Cloud Model Atom Visualization Reel by @tuneintospace - The first-ever direct visualization of an electron's orbit inside a hydrogen atom. It's not a single particle captured in motion, but rather a represe
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TU
@tuneintospace
The first-ever direct visualization of an electron’s orbit inside a hydrogen atom. It's not a single particle captured in motion, but rather a representation of the electron's probability cloud—the area where it is most likely to be found. This groundbreaking image offers a tangible glimpse into the strange world of quantum mechanics and a powerful testament to the advancements in modern physics. It's a profound reminder of the unseen universe that exists on a subatomic scale. Check the study - Stodolna, Aneta S., et al. “Hydrogen Atoms under Magnification: Direct Observation of the Nodal Structure of Stark States.” Physical Review Letters, vol. 110, no. 21, 2013
#Electron Cloud Model Atom Visualization Reel by @observatory - The first-ever direct visualization of an electron's orbit inside a hydrogen atom. It's not a single particle captured in motion, but rather a represe
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OB
@observatory
The first-ever direct visualization of an electron’s orbit inside a hydrogen atom. It’s not a single particle captured in motion, but rather a representation of the electron’s probability cloud—the area where it is most likely to be found. This groundbreaking image offers a tangible glimpse into the strange world of quantum mechanics and a powerful testament to the advancements in modern physics. It’s a profound reminder of the unseen universe that exists on a subatomic scale. Check the study - Stodolna, Aneta S., et al. “Hydrogen Atoms under Magnification: Direct Observation of the Nodal Structure of Stark States.” Physical Review Letters, vol. 110, no. 21, 2013
#Electron Cloud Model Atom Visualization Reel by @alchemist_kovalev - This is a real photograph of a single atom - not a model, not a simulation, and not an artist's impression. What you are seeing is the light emitted b
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AL
@alchemist_kovalev
This is a real photograph of a single atom — not a model, not a simulation, and not an artist’s impression. What you are seeing is the light emitted by one trapped ion, held in place using electromagnetic fields and illuminated with laser cooling techniques. The atom itself does not appear as a solid object. Instead, the camera captures the photons scattered by the atom, making its presence visible. Atoms are often taught as abstractions — equations, probability clouds, and wavefunctions. Yet under extremely precise laboratory conditions, a single atom can interact with light strongly enough to be directly photographed. This groundbreaking image was captured by David Nadlinger at the University of Oxford, revealing a part of reality that exists far below the scale our senses evolved to perceive. Every once in a while, science allows us to glimpse the invisible. Follow this page for more accurate, mind-expanding science stories that reveal how reality truly works beyond what the eye can see. 🔬📸✨ Follow for more real science, not science fiction. @alchemist_kovalev
#Electron Cloud Model Atom Visualization Reel by @futuregenquantum (verified account) - The first-ever direct visualization of an electron's orbit inside a hydrogen atom. It's not a single particle captured in motion, but rather a represe
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FU
@futuregenquantum
The first-ever direct visualization of an electron’s orbit inside a hydrogen atom. It’s not a single particle captured in motion, but rather a representation of the electron’s probability cloud—the area where it is most likely to be found. This groundbreaking image offers a tangible glimpse into the strange world of quantum mechanics and a powerful testament to the advancements in modern physics. It’s a profound reminder of the unseen universe that exists on a subatomic scale. Check the study - Stodolna, Aneta S., et al. “Hydrogen Atoms under Magnification: Direct Observation of the Nodal Structure of Stark States.” Physical Review Letters, vol. 110, no. 21, 2013
#Electron Cloud Model Atom Visualization Reel by @singularityorbit - This is a real photograph of a single atom - not a model, not a simulation, and not an artist's impression. What you are seeing is the light emitted b
957.9K
SI
@singularityorbit
This is a real photograph of a single atom — not a model, not a simulation, and not an artist’s impression. What you are seeing is the light emitted by one trapped ion, held in place using electromagnetic fields and illuminated with laser cooling techniques. The atom itself does not appear as a solid object. Instead, the camera captures the photons scattered by the atom, making its presence visible. Atoms are often taught as abstractions — equations, probability clouds, and wavefunctions. Yet under extremely precise laboratory conditions, a single atom can interact with light strongly enough to be directly photographed. This groundbreaking image was captured by David Nadlinger at the University of Oxford, revealing a part of reality that exists far below the scale our senses evolved to perceive. Every once in a while, science allows us to glimpse the invisible. Follow this page for more accurate, mind-expanding science stories that reveal how reality truly works beyond what the eye can see. 🔬📸✨ Follow for more real science, not science fiction. Image credit: David Nadlinger, University of Oxford Usage: Educational purposes only

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