As AI workloads grow and data centers of all types adapt to support high-density computing, preparing liquid-ready ...

Global computing power is growing aggressively and pushing high-density chip power consumption. As this power density increases, traditional air cooling is reaching its physical limits, and ...

Efficient liquid cooling supported by reliable instrumentation is essential for data centers to handle increased capacity demands in the age of artificial intelligence (AI) and other heavy compute ...

High-density computing workloads like AI training and inference run too hot for traditional air cooling. Companies are increasingly adopting liquid cooling technologies, even in traditional air-cooled ...

In the data center sector, single-phase liquid cooling remains the most widely deployed method for removing heat from chips.

As rack densities surge and grid headroom tightens, liquid cooling is becoming the backbone of AI data centers. Here we ...

Air cooling limits Air cooling starts to reach its limits once you get over 20 kilowatts per rack. Typical air-cooling systems top out at 15 to 20 kilowatts, and row-based cooling with containment ...

Data centers stand at the forefront of innovation as the beating heart of the digital age. Mountains of data are processed, stored, and disseminated to power everything from AI-driven applications to ...

Federal agencies need to ensure their data centers can withstand the effects of climate change, from record-breaking temperatures to unexpected outages and changing weather patterns across the globe.

The rise of AI applications has spurred demand for AI servers. However, the increasing computational power has also led to a growth in cooling requirements, presenting a challenge for all industry ...