#F Orbital Complex Shape

Shapes of Orbital Orbitals are regions around the nucleus where there’s a high probability of finding an electron. The shape depends on the subshell — s, p, d, or f. s-orbital: Spherical. Only 1 per energy level. Example: 1s, 2s, 3s. Gets larger with higher energy levels but stays a sphere. Can hold 2 electrons. p-orbital: Dumbbell-shaped. 3 per energy level starting from n=2. They lie along the x, y, and z axes: pₓ, pᵧ, p𝓏. Each can hold 2 electrons, so 6 total for p-subshell. d-orbital: 4 are cloverleaf-shaped, 1 looks like a dumbbell with a donut around the middle. 5 per energy level starting from n=3. Holds 10 electrons total. f-orbital: Complex shapes with multiple lobes. 7 per energy level starting from n=4. Holds 14 electrons total. Key point: Orbitals don’t show a fixed path. They show electron density. The boundary surface encloses ∼90% probability of finding the electron there. #AtomicOrbitals #ElectronCloud #Chemistry #ScienceReels

Cicada-AWACS releases flares I've designed this aircraft of my drone army and today I tried making flare system with blender simulation nodes! #future #scifi #aviationdaily #aviation4u #instaaviation #airplane #fighterjet #jet #plane #engineering #technology #airforce #creativeart #rendering #3dartist #blender3d #digitalartwork #render #instarender #3dmodel #digitaldesign #conceptdesign #3danimation

These are 4 exoplanetary-systems in motion 😱 created using a technique called motion interpolation to reconstruct the orbit of the exoplanets from real images •HR 8799 - there are 4 exoplanets seen orbiting the star and the timelapse is made from 10 images taken over 12 years •51 Eri b - timelapse shows one exoplanet orbiting its star over the course of 4 years •Beta Pic b - timelapse shows one exoplanet orbiting its star over the course of 17 years •Fomalhaut b - timelapse shows the exoplanet orbiting its star over the course of 7 years  Credit: Jason Wang &  Malachi Noel (Northwestern)/Gemini Planet Imager Exoplanet Survey, William Thompson (UVic)/Christian Marois (NRC Herzberg)/Quinn Konopacky (UCSD),   (Northwestern), Paul Kalas (UC Berkeley) #planetary #system #alien #alienplanet #cosmos #universe #solarsystem #exoplanet #deepspace #constellations

🧪 KIT MODELOS ATÓMICOS – MATERIAL DIDÁCTICO 3D Este kit incluye 4 modelos atómicos diseñados para comprender la evolución de las teorías sobre la estructura del átomo 👩‍🏫👨‍🏫 🔹 Modelo de Dalton Esfera maciza de aprox. 6 cm de diámetro (similar a una pelota de tenis), con base y nombre del modelo. 📘 Teoría: Dalton propuso que la materia está formada por átomos indivisibles, macizos e indestructibles, y que los átomos de un mismo elemento son iguales entre sí. 🔹 Modelo de Thomson Modelo de aprox. 6 cm de diámetro, con base. 📘 Teoría: Thomson planteó que el átomo es una esfera con carga positiva en la que se encuentran incrustados los electrones, conocido como el “budín de pasas”. 🔹 Modelo de Rutherford Altura aproximada 15 a 17 cm. Contiene un núcleo representado por una esfera de un solo color y tres orbitales. 📘 Teoría: Rutherford demostró que el átomo posee un núcleo pequeño, denso y con carga positiva, donde se concentra casi toda la masa, y que los electrones giran alrededor. 🔹 Modelo de Bohr (Litio) Altura aproximada 14 cm, con dos orbitales. En el centro se representan protones y neutrones, y en los orbitales los electrones. 📘 Teoría: Bohr propuso que los electrones se mueven en órbitas definidas con niveles de energía específicos. 📍 Somos Biomec Impresión 📦 Estamos en Bahía Blanca 🚚 Realizamos envíos a todo el país ✨ Ideal para nivel secundario, terciario y formación docente 💬 Consultanos por más info o pedidos personalizados #modelosatomicos #materialdidactico #educacion #quimica

How orbital look like

Learn Structure of Atom in 30 seconds ⏱️ Save this for revision 📌 Science made EASY 💙 #teachersofinstagram #engageandinspire #scienceteacher #StructureOfAtom #ScienceNotes LearnScience PKsLearningStudio ChemistryBasics StudentLife TeacherContent StudyReels EasyLearning ScienceMadeSimple

Atomic models explain how scientists understand the structure of the atom. Over time, these models improved as new experiments were performed. Here’s a clear, step-by-step overview: 1. Dalton’s Atomic Model (1803) Scientist: John Dalton Main Ideas: Atom is a solid, indivisible sphere All atoms of an element are identical Atoms combine in fixed ratios Limitation: Could not explain subatomic particles (electron, proton, neutron) 2. Thomson’s Atomic Model (1897) Scientist: J. J. Thomson Main Ideas: Atom is a positively charged sphere Electrons are embedded like raisins in pudding Limitation: Failed to explain atomic nucleus 3. Rutherford’s Atomic Model (1911) Scientist: Ernest Rutherford Main Ideas: Atom has a small dense nucleus Electrons revolve around nucleus Most of the atom is empty space Experiment: Gold Foil Experiment Limitation: Could not explain why electrons don’t fall into nucleus 4. Bohr’s Atomic Model (1913) Scientist: Niels Bohr Main Ideas: Electrons move in fixed orbits (energy levels) Energy is quantized Electrons jump between levels by absorbing/emitting energy Limitation: Works well only for hydrogen atom 5. Quantum Mechanical Model (Modern Model) Scientists: Erwin Schrödinger, Werner Heisenberg Main Ideas: Electrons exist in probability clouds (orbitals) Exact position cannot be known (uncertainty principle) Uses mathematics and wave functions Best Model: Explains all atoms, bonding, and spectra #FScPhysics #physicsnotes #physicsvibespk #atomicmodel #modernphysics

Orbital Living Structure #orbitalhabitat #megastructure #spaceengineering

After spending almost my whole summer dealing with extensive math and experimentation, orbital mechanics will now be possible on SURFACE WORLDS, along with the Aresonius Update, and fulfilling one of the bucketlist updates! Now this is what I call ‘easier said than done!’, new and revolutionary updates are yet to come to Space Sailors, this is just the beginning! Just a sidenote: the ‘orbital mechanics’ on the In-Space SEV is horribly made and scientifically inaccurate. The new and accurate one will be applied to that as well! Below is a 4-hour timelapse, sped up 1000x from takeoff to apoareion, to deorbiting and landing dangerously at night! #roblox #space #robloxdev #mars #ksp #spaceflight

Complex calculations underpin all progress in the aerospace sector. Every equation and each algorithm are like scientific compasses, guiding our missions into the unknown. 🚀 Do you know an emblematic aerospace formula? If so, share it with the group in a comment! 👇 #Ariane6 #ArianeGroup #SpaceExploration #RocketScience #AlgebraInAction #ScienceFiction #QuoteOfTheDay

Orbital Megastructure by @architectcha with AI assistants Imagine a future where many of humanity lives aboard a megastructure in orbit around Earth. This futurist speculation situates our descendants in orbit due to climate change effects or devastating wars. #SciFi #DigitalArt #madewithAI #Futurism #Future #FuturisticDesign #Megastructure #SpeculativeDesign #DigitalArchitecture #VisionaryArchitecture ⚫

⚛️✨ Journey of Atomic Models – How Scientists Imagined the Atom! ✨⚛️ The concept of the atom has evolved over time. Let’s look at the major atomic models that shaped our understanding of matter: 1️⃣ Dalton’s Atomic Model (1803) – Atom as an indivisible solid sphere. 2️⃣ Thomson’s Model (1897) – The “Plum Pudding Model” 🍮, with electrons embedded in a positive sphere. 3️⃣ Rutherford’s Model (1911) – Discovered the nucleus; atoms are mostly empty space with electrons revolving around a dense center. 4️⃣ Bohr’s Model (1913) – Electrons move in fixed orbits (energy levels) around the nucleus. 5️⃣ Quantum Mechanical Model (1926, Schrödinger & Heisenberg) – The most accepted model today; electrons exist in regions called orbitals, not fixed paths. 💡 Each model brought us closer to the truth — showing how science keeps improving with new discoveries! 👉 Which atomic model do you find most interesting? #chemistry #trendingreels #chemistrymemes #reels #amazing