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Fun facts for sunday: Did You Know? A Happy Accident That Changed the World of Electronics! Back in 1947, three brilliant minds at Bell Labs—John Bardeen, Walter Brattain, and William Shockley, were experimenting with germanium crystals when they stumbled upon something incredible: the transistor! 💡 Why This Discovery Rocks: Mini Marvels: Before transistors, electronics relied on bulky vacuum tubes. Transistors shrunk devices down, making gadgets like smartphones and laptops possible. Foundation of the Digital Age: These tiny components are the building blocks of all modern electronics, from your favorite apps to powerful supercomputers. Nobel-Worthy Breakthrough: Their accidental discovery was so groundbreaking that it earned them the Nobel Prize in Physics in 1956. Imagine a world without transistors—no sleek tech, no instant communication, no digital innovation. This accidental discovery didn’t just earn a Nobel Prize; it sparked a technological revolution that shapes our everyday lives! Next time you swipe your phone or power up your laptop, give a nod to the transistor; a true game-changer in electronics history. #Innovation #Electronics #TechHistory #Transistor #NobelPrize #DigitalAge #TechFacts

Unlocking the secrets of semiconductors - the tiny tech that powers our world! 💻⚡ From smartphones to solar panels, these microscopic marvels make modern life possible. #semiconductor #semiconductorrevolution #technology #technical #engineering #science #evening #reels #techreels #sunday

Last week, I posted about studying commercial foil-based flex circuits, regarding high cycle motions. While this might seem like a distraction, I was taking a first step to tie several concepts together. As I've written over the past few months, I am interested in high motion areas and I am interested in biostability. Achieving full device biostability is dependent on use case. There are concerns regarding deployment of the device and, if it is a wearable, potential damage to the metal layers. If we deposit gold on copper, what happens if we damage the gold coating and expose the copper to human contact? How can we prevent that? We can prevent it with an all biocompatible metal stack. What if the metal is biocompatible but not biostable? We may not have a toxic interaction but we might have drifting electrical performance if the body interacts with our underlying traces. Sputtered gold on polyethelyne from a Stanford presentation:

The Novel Material Revolutionizing Energy Storage. Washington University in St. Louis scientists have developed a novel material that supercharges innovation in electrostatic energy storage. The material is built from artificial heterostructures made of freestanding 2D and 3D membranes that have an energy density up to 19 times higher than commercially available capacitors. Electrostatic capacitors play a crucial role in modern electronics. They enable ultrafast charging and discharging, providing energy storage and power for devices ranging from smartphones, laptops, and routers to medical… http://ow.ly/846R105r5pP

The Novel Material Revolutionizing Energy Storage. Washington University in St. Louis scientists have developed a novel material that supercharges innovation in electrostatic energy storage. The material is built from artificial heterostructures made of freestanding 2D and 3D membranes that have an energy density up to 19 times higher than commercially available capacitors. Electrostatic capacitors play a crucial role in modern electronics. They enable ultrafast charging and discharging, providing energy storage and power for devices ranging from smartphones, laptops, and routers to medical… http://ow.ly/846R105r5pP

🔥 2023 Hot Paper! 🔥 Soft conductive nanocomposites for recording biosignals on skin 👨🔬Corresponding authors: Prof. Dae-Hyeong Kim, and Dr. Mincheol Lee #nanomaterials #biointegratedelectronics This review focus on recent advances in soft conductive nanocomposites, mainly on their electrical and mechanical properties according to the types of nanofillers, and present their applications to wearable biosignal recording devices. 🔗 Read the full article: https://lnkd.in/gnU88BjG

Exciting developments in the tech world! 🚀 Motorola's latest announcement on the Android 15 update list shows a commitment to enhancing device longevity, a crucial concern for many users today. While Motorola is catching up with software updates, the tech industry is advancing with materials that could redefine durability and performance in electronics. 📱 In the realm of innovation, silicon carbide (SiC) is making waves, especially in miniaturized devices. SiC's exceptional mechanical and thermal properties are pushing the capabilities of MEMS and NEMS, found in our everyday electronics, to new heights. This evolution is crucial not just for consumer electronics, but also for applications in industry, medicine, agriculture, space, and defense. Dive deeper into the potential of SiC-based MEMS/NEMS with our featured ebook "SiC based Miniaturized Devices". It's a treasure trove of insights on novel designs, applications, and the future of SiC in tech. Whether you're in the tech industry, a developer, or simply a tech enthusiast, this is knowledge you won't want to miss. Unlock the full potential of next-gen devices → https://lnkd.in/dEXqz8_M #TechInnovation #SiCMEMS #MotorolaUpdate #SiliconCarbide #FutureTech #ReadMore Let's discuss below: How do you see SiC technology shaping the future of our devices?

Nanoscale transistors are revolutionizing electronics by enabling ultra-efficient, low-voltage operations potentially overcoming the limits of traditional silicon technology. Leveraging quantum mechanics, these advances could transform everything from smartphones to AI-driven systems. Could this be the future of sustainable computing? #Nanotechnology #QuantumInnovation #EnergyEfficiency #Electronics #FutureOfTech https://lnkd.in/d24v-7Mh

Lead Zirconium Titanate Sputtering target PZT (PbZr0.52Ti0.48O3) Sputtering Target PZT thin films are one of the most effective materials attractive for MEMs applications. Due to their outstanding piezoelectric response and high polarization, PZT thin films of ferroelectric materials have been extensively utilized for Micro-Electro-Mechanical Systems (MEMs), scanning mirrors, micro-pumps and valves, radio-frequency switches, hard disc drive read/write heads, portable and wearable electronics, intracochlear applications, and energy harvesters.#thinfilm #sputter #PZT #depositions

Tech history: November 17, 1947 — A revolutionary invention that would change the world forever was born. John Bardeen, Walter Brattain, and William Shockley successfully demonstrated the first working transistor at Bell Laboratories in Murray Hill, New Jersey. This groundbreaking device would go on to replace bulky and power-hungry vacuum tubes, paving the way for smaller, more efficient electronic devices. The impact of the transistor: 1. It miniaturized electronics, enabling the development of portable devices we now take for granted. 2. It dramatically reduced power consumption, making our gadgets more energy-efficient. 3. It became the fundamental building block of modern computing and telecommunications. The invention of Bardeen, Brattain, and Shockley was recognized with the 1956 Nobel Prize in Physics. But the story doesn't end there. The transistor's legacy extends far beyond its initial creation. William Shockley's decision to start Shockley Semiconductor Labs in Mountain View, California, set in motion a chain of events that would lead to the birth of Silicon Valley. Today, we use our smartphones, laptops, and countless other electronic devices, all thanks to these pioneers. Their work not only revolutionized technology but also shaped the very landscape of innovation we know today. #TechHistory #Innovation #Transistor #SiliconValley