The phrase “More Than Moore” has gained significant traction in the semiconductor and electronics industry. Unlike the traditional “Moore’s Law” which primarily focuses on scaling transistor sizes to improve computing performance, “More Than Moore” emphasizes integrating diverse functionalities beyond just transistor miniaturization.
Power electronics—responsible for the efficient conversion and control of electrical energy—has become the cornerstone of modern technological advancement. From electric vehicles to renewable energy systems and data centers, power electronics lies at the heart of energy-efficient solutions.
As the semiconductor industry continues to push the boundaries of performance and efficiency, traditional silicon (Si) materials have increasingly revealed their limitations. The ever-growing demand for devices capable of operating at higher voltages, frequencies, and temperatures has driven the exploration and adoption of compound semiconductors, which offer superior physical and electrical properties .
The global electric vehicle (EV) industry is undergoing an unprecedented transformation. With the push for decarbonization, stricter emissions standards, and rapid advancements in battery technology, EV adoption is accelerating across the globe.
The phrase “More Than Moore” has gained significant traction in the semiconductor and electronics industry. Unlike the traditional “Moore’s Law” which primarily focuses on scaling transistor sizes to improve computing performance, “More Than Moore” emphasizes integrating diverse functionalities beyond just transistor miniaturization.
Power electronics—responsible for the efficient conversion and control of electrical energy—has become the cornerstone of modern technological advancement. From electric vehicles to renewable energy systems and data centers, power electronics lies at the heart of energy-efficient solutions.
As the semiconductor industry continues to push the boundaries of performance and efficiency, traditional silicon (Si) materials have increasingly revealed their limitations. The ever-growing demand for devices capable of operating at higher voltages, frequencies, and temperatures has driven the exploration and adoption of compound semiconductors, which offer superior physical and electrical properties .
The global electric vehicle (EV) industry is undergoing an unprecedented transformation. With the push for decarbonization, stricter emissions standards, and rapid advancements in battery technology, EV adoption is accelerating across the globe.
