The ever-increasing rate of data and communications, accentuated by the rapid growth of applications such as 5G, VR, or AI, coupled with advanced manufacturing and packaging technologies in micro and nanoelectronic systems resulted in a continuous increase of the power density of integrated circuits (ICs). However, the inability to follow Dennard's scaling law has incurred an exponential increase in heat dissipation, establishing thermal management as a major concern for the information and communication technologies (ICT) community. In addition, the growing demand for data processing and storage is not free of environmental impact: data centers account today for around 1% of global electricity demand, and up to 40% of this consumption is associated with cooling systems. To meet the increasing power density of microprocessors and reduce cooling power requirements, data centers are increasingly moving from air to liquid cooling alternatives due to their higher heat capacity, compactness, and higher cooling performance.
Today, liquid-cooled devices for advanced microelectronics are mainly based on microchannels cold plate, fixed to the backside of microprocessors and, although this technology offers low thermal resistances, also presents large pressure drops (that turns into high hydraulic pumping powers) and poor temperature uniformities (which implies electronic reliability and lifetime issues). Moreover, in real operating conditions of advanced multicore processors or 3D-IC, the heat flux distribution changes spatially and over time and current cooling systems cannot provide high-performance levels, leading to temperature non-uniformities and overcooled systems. Within the existing cooling solutions to improve the performance of liquid cooling systems, none focuses on developing a system capable of adapting to changing conditions in time and space, so heat transfer is improved even when not needed and additional pressure drops are induced in the fluid channel, causing oversized pump powers for changing conditions.
A promising approach for more efficient thermal management, proposed by several studies, is to directly embed liquid cooling inside the chip, which eliminates the thermal resistance between the semiconductor die and the packaging and dimensions of the IC and cooling power can be significantly reduced.
UniSCool aims to enter a new leading thermal management paradigm by developing an in-chip smart liquid cooling system, embedded at the chip stack, with a new patented and highly innovative liquid cooling system, based on an adaptive heat sink that includes a series of thermally activated fins capable of efficiently adapting the local heat extraction to variable heat fluxes. This solution can boost the heat extraction capacity of the system up to more than 1kW/cm2 with significantly reduced flow rate and pumping power consumption (x0.5) high performance, and significantly reduced space (x10) in a sustainable and environmentally friendly way.