正在加载视频...

视频加载失败

🎬open_world_firearms The M416 in its rawest form. Precision engineering meets fluid mechanics in this slow-motion cutaway. Observe the gas management through the custom suppressor baffles. Designed by Open world firearms. 3DDesign Engineering SlowMotion TacticalTech Weaponry

477,881 次观看 • 2 天前 •via X (Twitter)

0 条评论

暂无评论

原始帖子的评论将显示在这里

相关视频

Cooking meets cinematic AI. This stunning commercial was created with Seedance 2.0 in Lart AI Delivering realistic motion, rich food details, and premium visuals that look like a real production. Create yours here 👇 Prompt: THE FLAME CHEF - 15 second high-energy cinematic cooking film, 10 rapid scenes, fast rhythmic pacing, whip-pan and speed-ramp transitions between every scene, kinetic kitchen artistry from fresh ingredients to final plated dish. Shot on ARRI Alexa 35, 35mm lens, natural film grain, rich warm color grade with deep shadows and golden highlights, professional food cinematography, photorealistic, not CGI. Dark moody restaurant kitchen, dramatic overhead lighting, steam and warm glow. SCENE 1 (0-1.5s): Chef's hand places a cast iron pan onto a glowing gas burner with confident energy, blue flame rising around the edges, quick real time then micro slow motion on the flame glow, hard whip-pan into locked close-up. SCENE 2 (1.5-3s): Rapid skilled vegetable prep, knife rocking smoothly through fresh herbs and bell peppers in rhythmic motion, hyper-fast real time with hands in controlled motion, one pepper slice spinning in brief slow motion, top-down locked shot. SCENE 3 (3-4.5s): Butter cube tossed gracefully through the air landing in the warm pan, melting instantly into golden foam and swirl, slow motion flight with speed ramp to real time on the sizzle, side macro tracking the arc. SCENE 4 (4.5-6s): Chef flips the pan, vegetables rising upward in a golden arc, warm flame glow beneath, tiny seasoning embers drifting, speed ramp from real time flip into dramatic slow motion at the peak of the toss, low hero angle. SCENE 5 (6-7.5s): Extreme macro, garlic and chili meeting hot oil, lively golden bubbles, steam rising in a soft backlit plume, 120fps slow motion with every bubble crisp, probe lens push-in through the steam. SCENE 6 (7.5-9s): Chef seasoning from height with flowing hand movement, salt crystals raining down in slow motion through a shaft of overhead light catching like snow, slow motion rain against fast hand movement, side close-up with shallow focus on the crystals. SCENE 7 (9-10.5s): Sauce poured from a steel pan in a glossy ribbon coating the dish in one continuous silky wave, steam curling, silky hypnotic slow motion, orbiting macro around the pour. SCENE 8 (10.5-12s): Fresh herbs dropped from above, leaves tumbling in slow motion landing perfectly on the glistening dish, tiny sparkle of sauce, slow motion fall with real time landing, top-down locked shot. SCENE 9 (12-13.5s): Chef wipes the plate rim in one confident swift motion and spins the plate a quarter turn, steam rising through dramatic side light, fast confident real time, close-up tracking the hand with whip-pan on the spin. SCENE 10 (13.5-15s): Final hero shot, finished dish center frame under a single overhead spotlight, steam rising in elegant curls, background fading to darkness, chef's silhouette stepping back with satisfaction, calm slow motion after the energy, slow push-in settling to a loop-friendly hold. Movement: continuous kinetic energy throughout, hands moving with professional speed and precision, constant speed ramping between hyper-fast real time and crisp slow motion for rhythm, ingredients gracefully in flight, intensity building from scene 1 to 9 then sudden calm hero ending Camera: hard whip-pans between scenes, top-down locked shots, side macro tracking, low hero angle, probe lens push-in, orbiting pour shot, close-up hand tracking, slow push-in finale, all cuts punchy and landing on beat Effects: warm flame glow, backlit steam plumes, golden oil bubbles in extreme macro, salt crystals in overhead light shafts, glossy sauce reflections, shallow depth of field, natural film grain, dark moody kitchen atmosphere, no text no watermark.

Zar⭕on

31,229 次观看 • 7 天前

The fascinating concept of Non-Newtonian fluids, which transition from a liquid state to a solid-like state when pressure is applied, has a rich history that spans several centuries. The study and understanding of these peculiar fluids have evolved over time, leading to a wide range of practical applications and scientific insights. One of the earliest references to Non-Newtonian behavior in fluids dates back to the 17th century when Sir Isaac Newton formulated the basic principles of fluid mechanics. Newton's laws of fluid motion primarily applied to Newtonian fluids, which exhibit constant viscosity and flow behavior regardless of the applied force or pressure. However, it soon became apparent that not all fluids behaved in this predictable manner. In the mid-19th century, a scientist named Thomas Andrews made significant contributions to the understanding of Non-Newtonian fluids. Andrews conducted groundbreaking experiments with carbon dioxide, revealing that under high pressure, this gas could transform into a liquid. This observation marked one of the earliest instances of pressure-induced phase changes in fluids. The term "Non-Newtonian" itself was coined in the 20th century to describe fluids that did not adhere to Newton's classical laws of fluid dynamics. These fluids exhibited a variety of behaviors, but one of the most intriguing was their ability to solidify or increase in viscosity when subjected to stress or pressure. One of the most famous examples of such behavior is cornstarch mixed with water, which forms a substance known as "oobleck" that becomes more solid when pressure is applied. In the modern era, Non-Newtonian fluids have found applications in various fields, including food science, engineering, and material science. They are used in products like quicksand, body armor, and even in the development of impact-resistant materials. One of the key insights that emerged from the study of Non-Newtonian fluids is the importance of understanding the relationship between stress and strain, as well as the influence of time-dependent properties on their behavior. This knowledge has led to advancements in rheology, the study of flow and deformation in materials, and has practical implications in areas such as industrial processing, medicine, and the design of everyday products.

Historic Vids

2,632,483 次观看 • 2 年前

Fighter jet pilot demonstrates centripetal force, a concept that Isaac Newton discovered between 1676 and 1677. However, the concept of centripetal force was not actually discovered in a single event or by a single individual but rather evolved over time through the works of multiple scientists and thinkers. Here is a brief history of the development of our understanding of centripetal force: Ancient Greece: The ancient Greeks, particularly philosophers such as Aristotle and later Archimedes, made observations and formulated theories about the motion of objects. However, they did not have a clear understanding of centripetal force as a distinct concept. Islamic Scholars: During the Islamic Golden Age, scholars such as Ibn Sina (Avicenna) and Ibn Bajjah (Avempace) made significant contributions to the understanding of motion. They discussed the idea of impetus, a precursor to the concept of centripetal force. Johannes Kepler: In the 17th century, Johannes Kepler, a German astronomer and mathematician, formulated his laws of planetary motion. Kepler's laws described the motion of planets around the sun and the concept of elliptical orbits. Although Kepler did not explicitly mention centripetal force, his work laid the foundation for later developments. Isaac Newton: In the late 17th century, Sir Isaac Newton, an English physicist and mathematician, published his groundbreaking work, "Mathematical Principles of Natural Philosophy" (also known as the Principia). In this work, Newton presented his laws of motion and the universal law of gravitation. Newton's laws, particularly the second law of motion, provided a mathematical understanding of centripetal force. He demonstrated that an object moving in a curved path experiences an inward force acting towards the center of the curve, which is now known as centripetal force. Further Developments: Following Newton's work, subsequent scientists, such as Jean le Rond d'Alembert and Daniel Bernoulli, expanded on the understanding of centripetal force in the context of mechanics and fluid dynamics. It's important to note that the discovery and understanding of centripetal force were gradual processes that involved the contributions of numerous individuals over centuries. The concept became firmly established with the development of Newtonian physics and its laws of motion.

Historic Vids

11,803,499 次观看 • 3 年前