Penn State Engineers Build First-Ever Computer Using Atomically Thin 2D Materials, No Silicon

In a groundbreaking advancement, researchers at Pennsylvania State University have created the world’s first computer constructed entirely from atomically thin two-dimensional (2D) materials—marking a significant step toward the future of ultra-slim, low-power electronics.

A Silicon-Free Innovation
The research team developed a complementary metal-oxide semiconductor (CMOS) computer without using traditional silicon. Instead, they employed two atomically thin materials: molybdenum disulfide for n-type transistors and tungsten diselenide for p-type transistors. These transistor types are vital for controlling electric current in CMOS logic circuits—the building blocks of nearly all modern digital devices.

Project leader Dr. Saptarshi Das, a professor of engineering, emphasized that while silicon-based technology struggles at nanoscale sizes, 2D materials retain superior electrical properties at atomic thickness. “Two-dimensional materials maintain their exceptional electronic properties at atomic thickness,” he noted, offering a new path for continued miniaturization in electronics.

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Precision Engineering at the Atomic Scale
Using metal-organic chemical vapor deposition (MOCVD), the team deposited ultra-thin layers of these materials with atomic-level precision. They fabricated over 1,000 transistors of each type and carefully tuned their threshold voltages—successfully assembling a functional CMOS logic circuit from the 2D components.

A Modest Yet Historic Prototype
Though the prototype computer operates at a modest speed of up to 25 kilohertz—much slower than commercial silicon chips—it represents a powerful proof of concept. “Our 2D CMOS computer operates at low voltages with minimal power consumption,” said lead author and PhD candidate Subir Ghosh.

This single-instruction-set computer is not designed to replace today’s processors but serves as a foundational achievement. It could pave the way for a new generation of flexible, lighter, and energy-efficient electronic devices in the years to come.