@gen.with.a.g: 🫶🏽🧚🏽‍♀️💓

Genevieve
Genevieve
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Friday 06 January 2023 05:43:40 GMT
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its_teta
its_teta :
Top 2 and she not 2
2023-01-06 06:12:29
4
robertcougar
RobertCougar :
My favorite TikToker 🥰❤️😍
2023-01-06 05:44:58
1
bashplay
Bash :
Tassive Mits!
2023-01-19 06:55:55
2
dan_sf3
Dan :
Wow! Gorgeous!!!
2023-01-20 00:21:24
2
adamangel44
Adam Angel :
The perfect 👀
2023-01-15 03:13:42
3
bahanevzat
AHAB :
Where are you life
2023-01-08 09:06:11
1
scubatom1
Tom Franklin :
amazing model
2023-01-15 02:53:39
2
joshuaengel1
Josh🤍🌹 :
Hey beautiful
2023-01-15 03:03:53
2
viler73
Viler73 :
My god!! 🥰🥰😂
2023-01-09 14:04:11
3
alexstinson355
alexstinson355 :
Absolutely gorgeous 🥰🥰🥰🥰
2023-01-20 16:16:15
2
sickey1512
SiCkEy75 :
hello my name is Robin WooD.. 🤣😂🤣😂
2023-01-08 10:36:20
1
popopopopolopolo
popopopopolopolo :
proud parents
2023-01-07 16:24:42
3
r.33.g
Alibi :
Elle a changé Geneviève
2023-01-06 21:00:11
4
philimon63
user827317234376 :
Amazing 😳
2023-01-09 13:13:52
3
eddymccormack1
Edward McCormack :
Yes yes yes my girl
2023-01-16 12:38:02
3
ginoarciero
ginoarciero :
Wow very very pretty ❤️
2023-01-15 03:25:13
2
benjile1
benjile :
what do you need?
2023-01-11 12:24:57
1
alexfdezruizz
Alejandro Fernández :
Es alucinantemente bonita
2023-01-09 13:22:15
1
neilcarter2448
Neil Carter2448 :
have a look 😉
2023-01-15 11:42:45
2
tahokid
LC :
So beautiful 😉
2023-01-09 18:57:46
1
user2778885528183
Purtangius :
You just have no idea how hard I wanted to you 😮‍💨 fml
2023-01-13 04:09:01
1
thebadcreditmortgageguy
thebadcreditmortgageguy :
2-10
2023-01-18 22:54:15
0
the_timtam_slammer
The Tim Tam Slammer :
Howly shiiiiet 😳
2023-01-19 12:41:20
0
loveyoubigbrother
Thomas :
Got damn absolutely perfection
2023-01-15 03:03:06
3
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I updated my Schrödinger Equation visuals. This time, I included the unbounded inner product Gaussian in the first 2 animations, and used the more familar localized inner product on the last. To review: The Schrödinger equation is one of the cornerstones of quantum mechanics, describing how the quantum state of a physical system changes over time. Here's a detailed explanation without using any equations: ### **Core Idea:** The Schrödinger equation governs the behavior of quantum systems, much like Newton's laws govern classical mechanics. Instead of predicting exact positions and velocities of particles, it tells us how the *probability amplitude* (a complex-valued function related to the likelihood of finding a particle in a certain state) evolves over time. ### **Key Concepts:** 1. **Wavefunction (ψ):**      - In quantum mechanics, particles don’t have definite positions or paths. Instead, their state is described by a *wavefunction*, which contains all the probabilistic information about the system.    - The wavefunction doesn’t tell us where a particle *is* but rather where it *might be* and with what probability. 2. **Time Evolution:**      - The Schrödinger equation explains how the wavefunction changes with time. It doesn’t determine a single outcome but describes a smooth, deterministic evolution of probabilities.    - If you know the wavefunction at one moment, the equation tells you how it will look in the next instant. 3. **Energy and Hamiltonian:**      - The equation depends on the *Hamiltonian*, which represents the total energy of the system (kinetic + potential energy).    - Different potentials (e.g., an electron in an atom vs. a free particle) lead to different wavefunction behaviors. 4. **Superposition & Quantization:**      - The equation naturally leads to *superposition*—where a quantum system can exist in multiple states at once until measured.    - For bound systems (like electrons in atoms), it predicts *quantized* energy levels, explaining why electrons occupy discrete orbitals. 5. **Uncertainty & Probabilities:**      - The wavefunction’s square magnitude gives the probability density of finding a particle in a certain state.    - Unlike classical physics, quantum mechanics is inherently probabilistic, and the Schrödinger equation encodes this randomness. ### **Analogy (Rough but Helpful):** Imagine a ripple spreading on a pond. The shape and motion of the ripple depend on the water’s properties (like depth and obstacles). Similarly, the Schrödinger equation describes how the
I updated my Schrödinger Equation visuals. This time, I included the unbounded inner product Gaussian in the first 2 animations, and used the more familar localized inner product on the last. To review: The Schrödinger equation is one of the cornerstones of quantum mechanics, describing how the quantum state of a physical system changes over time. Here's a detailed explanation without using any equations: ### **Core Idea:** The Schrödinger equation governs the behavior of quantum systems, much like Newton's laws govern classical mechanics. Instead of predicting exact positions and velocities of particles, it tells us how the *probability amplitude* (a complex-valued function related to the likelihood of finding a particle in a certain state) evolves over time. ### **Key Concepts:** 1. **Wavefunction (ψ):** - In quantum mechanics, particles don’t have definite positions or paths. Instead, their state is described by a *wavefunction*, which contains all the probabilistic information about the system. - The wavefunction doesn’t tell us where a particle *is* but rather where it *might be* and with what probability. 2. **Time Evolution:** - The Schrödinger equation explains how the wavefunction changes with time. It doesn’t determine a single outcome but describes a smooth, deterministic evolution of probabilities. - If you know the wavefunction at one moment, the equation tells you how it will look in the next instant. 3. **Energy and Hamiltonian:** - The equation depends on the *Hamiltonian*, which represents the total energy of the system (kinetic + potential energy). - Different potentials (e.g., an electron in an atom vs. a free particle) lead to different wavefunction behaviors. 4. **Superposition & Quantization:** - The equation naturally leads to *superposition*—where a quantum system can exist in multiple states at once until measured. - For bound systems (like electrons in atoms), it predicts *quantized* energy levels, explaining why electrons occupy discrete orbitals. 5. **Uncertainty & Probabilities:** - The wavefunction’s square magnitude gives the probability density of finding a particle in a certain state. - Unlike classical physics, quantum mechanics is inherently probabilistic, and the Schrödinger equation encodes this randomness. ### **Analogy (Rough but Helpful):** Imagine a ripple spreading on a pond. The shape and motion of the ripple depend on the water’s properties (like depth and obstacles). Similarly, the Schrödinger equation describes how the "quantum ripple" (the wavefunction) evolves based on the system’s energy landscape. ### **Interpretations:** - The equation itself doesn’t explain *why* the wavefunction behaves this way or what it "really" is—that’s the realm of quantum interpretations (e.g., Copenhagen, Many-Worlds). - It’s purely a mathematical tool that works astonishingly well to predict quantum phenomena, from chemical bonds to superconductivity. ### **Why It’s Profound:** - It replaces the deterministic trajectories of classical physics with a probabilistic framework. - It introduces wave-particle duality fundamentally: Particles are neither waves nor particles but entities described by wave-like equations that collapse to particle-like observations. #quantum #quantumphysics #quantummechanics #physics #wave #maths #mathematics #mathematician #interesting #engineering #programming #quantumcomputing #superposition #entanglement #educate #education

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