Application areas
SisuSemi offers an innovative solution to eliminate these impurities, ensuring superior performance and reliability for semiconductor chips in key application areas such as mobile and wearable devices, IoT, and data centres.
Mobile and Wearable Chips: Enabling Longer Battery Life
Mobile and wearable devices rely on compact, energy-efficient chips to meet consumer demands for longer battery life and reliable performance. However, atomic-level impurities introduce leakage currents that drain power and limit device lifespan, especially as these chips shrink in size and increase in complexity. Also, there are thermal management issues: Impurities cause inefficiencies, generating excess heat in compact devices.
IoT Chips: Power Efficiency and Reliability at Scale
IoT devices are designed to operate in low-power environments, often for extended periods without maintenance. Atomic-level impurities pose a challenge in achieving the power efficiency and reliability needed for these devices to function seamlessly across smart homes, industrial applications, and beyond. This calls for that IoT devices must perform reliably in diverse and often harsh conditions.
Data Center Chips: Performance and Efficiency for High-Computing Demand
Data centers require semiconductor chips that can handle massive workloads with high efficiency and reliability. Atomic-level impurities in processor and memory chips lead to increased power consumption and reduced processing speeds, creating bottlenecks in high-performance computing systems. Variations in chip performance can lead to system failures and downtime, and thus reducing reliability. High power consumption cost money in electricity bill and cause cooling need that is waisted energy. Reduced life span of component through diffusion
The Rise of Advanced Applications: AI, Quantum Computing, and Beyond
The future of technology lies in advanced applications such as artificial intelligence, quantum computing, and biotechnology, all of which require semiconductors with unprecedented levels of performance. For example, AI chips used in data centers and autonomous vehicles must process massive amounts of data at lightning speeds, requiring semiconductors with high transistor density and minimal defects. Atom-level cleaning ensures that these chips meet the exacting standards necessary for such applications.
Quantum computing, another frontier technology, relies on quantum bits that are extremely sensitive to environmental factors, including atomic-level impurities. Leakage currents cause component heating, which is a problem in low temperature environment of quantum computing. Companies that provide atom-level cleaning solutions are therefore positioned at the cutting edge of this emerging field.
