A research team from DGIST used intense light on the surface of a copper wire to synthesize #graphene. This method increased the production rate, lowered the cost of the high-quality transparent-flexible electrode materials, and enabled mass production. bit.ly/3L61ky4

A research team from University of Michigan developed a ferroelectric semiconductor platform for AI and IoT computing systems. They used ferroelectric semiconductor materials over conventional silicon-based architectures to sustain electrical polarization. bit.ly/3Lb129b

Check out this inspiring Q&A with Ukarian materials architect Andriy Zakutayev. Like Intermolecular, Zakutayev is focused on using materials to help develop power-efficient devices. bit.ly/3qrCyBx #MaterialScience #Memory #Engineering

Researchers from UK universities recently exposed high-quality graphene to magnetic fields at room temperature and measured its response. This revealed that graphene can record levels of magnetoresistance without a need to push the temp down towards zero. bit.ly/41VmVzV

Meet Navnidhi Upadhyay, Senior Device Engineer here at Intermolecular. He works at the intersection of electrical engineering, material science and computer science to innovate and engineer next-gen memory devices and materials. bit.ly/464Vvuk #MaterialScience

Researchers from the Tokyo Tech recently proposed a unique technique for creating superior Cs3Cu2I5 thin films. Read more here: bit.ly/45ACAr4 #ThinFilms #Materials

Quantum computers are promising but are also prone to error. However, researchers from The University of Chicago recently developed a new method to monitor the noise around a quantum system and adjust the qubits, to minimize error. bit.ly/3oI9llC #QuantumComputing

Researchers recently looked into the sensing characteristics of drop-cast thin films of various materials with different compositions to determine the most sensitive thin film for NO2 detection. bit.ly/43CjcrE #ThinFilms #Materials

Researchers University of Bath recently discovered that modified graphene could transform the production of hydrogen peroxide for industrial use. bit.ly/3oIfNck #Graphene #Materials

Researchers predict that supercomputers will be able to outperform standard computers within the next 2 years. bit.ly/44cQQ7S #Supercomputers #QuantumComputing

A team from University of Washington recently detected atomic ‘breathing’ for quantum computing breakthrough. bit.ly/43VYrrI #QuantumComputing #Atomic

Researchers from Arizona State University recently developed graphene-based ultrashort laser pulse technology. This new technology has potential applications across communication, biomedical sensing, and other industries. bit.ly/44bbi94 #Graphene

Researchers from various universities recently discovered that water can interact directly with the carbon’s electrons: a quantum phenomenon that is very unusual in fluid dynamics. bit.ly/3NuuWq0 #Electrons #Quantum

Quantum computing is a cutting-edge technology that has the potential to revolutionize many industries, such as sustainable energy. Here at Intermolecular, we have in-house capabilities to achieve materials and device sustainability goals. bit.ly/3qYjXxg #Sustainability

Researchers from Shimane University recently developed an innovative polarization-angle-resolved Raman microscope. This new device helps analyze the molecular structure of materials. bit.ly/44kWbtH #Materials #Ferroelectric

Researchers recently decided to use topology and a new kind of “quasiparticle” to come up with an error-correction technique for quantum computers. bit.ly/3NuhT7Y #Topology #Qubit

A new study reveals that scientists have successfully split phonons paving the path for a new type of quantum computer called linear mechanical quantum computers. bit.ly/442Cg2W #QuantumComputers #Phonons

Nanowire thin films are composed of thin layers of nanostructured objects. They have received significant attention for several advanced applications due to their physical and chemical properties. bit.ly/43CjcrE #ThinFilms

The human brain is known as one of the most complicated objects. However, scientists at Los Alamos National Laboratory have made a new interface-type memristive device, which can be used to build artificial synapses for next-gen neuromorphic computing. bit.ly/46lneXT #Neuromorphic