Monday, May 1st 2023

MIT Researchers Grow Transistors on Top of Silicon Wafers

MIT researchers have developed a groundbreaking technology that allows for the growth of 2D transition metal dichalcogenide (TMD) materials directly on fully fabricated silicon chips, enabling denser integrations. Conventional methods require temperatures of about 600°C, which can damage silicon transistors and circuits as they break down above 400°C. The MIT team overcame this challenge by creating a low-temperature growth process that preserves the chip's integrity, allowing 2D semiconductor transistors to be directly integrated on top of standard silicon circuits. The new approach grows a smooth, highly uniform layer across an entire 8-inch wafer, unlike previous methods that involved growing 2D materials elsewhere before transferring them to a chip or wafer. This process often led to imperfections that negatively impacted device and chip performance.

Additionally, the novel technology can grow a uniform layer of TMD material in less than an hour over 8-inch wafers, a significant improvement from previous methods that required over a day for a single layer. The enhanced speed and uniformity of this technology make it suitable for commercial applications, where 8-inch or larger wafers are essential. The researchers focused on molybdenum disulfide, a flexible, transparent 2D material with powerful electronic and photonic properties ideal for semiconductor transistors. They designed a new furnace for the metal-organic chemical vapor deposition process, which has separate low and high-temperature regions. The silicon wafer is placed in the low-temperature region while vaporized molybdenum and sulfur precursors flow into the furnace. Molybdenum remains in the low-temperature region, while the sulfur precursor decomposes in the high-temperature region before flowing back into the low-temperature region to grow molybdenum disulfide on the wafer surface.
Emerging applications such as AI, automotive, and HPC require computing to be very dense, and stacking the transistors can be challenging. This new method has significant implications for the industry, enabling rapid, efficient integration of 2D materials into industrial fabrications. Future developments include fine-tuning the technique to grow multiple layers of 2D transistors and exploring low-temperature growth processes for flexible surfaces, such as polymers, textiles, or even paper.
Source: MIT
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8 Comments on MIT Researchers Grow Transistors on Top of Silicon Wafers

#1
Bomby569
so cheaper chips? (for those not requiring high end)
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#2
Lei
Bomby569so cheaper chips? (for those not requiring high end)
I'm guessing 500w cpus with coolers size of the Washington monument

Posted on Reply
#3
FeelinFroggy
Bomby569so cheaper chips? (for those not requiring high end)
Not cheaper chips. Pricing wont change only performance.
Posted on Reply
#4
LabRat 891
Neat.
Lemme know when we've commercialized full-die angstrom-scale additive manufacturing.
(+points if they call it a "replicator")
Posted on Reply
#5
Bomby569
FeelinFroggyNot cheaper chips. Pricing wont change only performance.
if pricing doesn't change, what's the point? just go for a smaller node and you'd even get better thermals
Posted on Reply
#6
Wirko
LabRat 891Neat.
Lemme know when we've commercialized full-die angstrom-scale additive manufacturing.
(+points if they call it a "replicator")
There are machines (a variant of scanning electron microscopes) that move individual atoms across a surface and build structures with them.
The trouble is, they move individual atoms.
Posted on Reply
#7
A Computer Guy
LeiI'm guessing 500w cpus with coolers size of the Washington monument

Perhaps with nanometer waterpipes running through the CPU die to help keep it cool.
Posted on Reply
#8
Minus Infinity
Bomby569if pricing doesn't change, what's the point? just go for a smaller node and you'd even get better thermals
The price for the manufacturer will most likely be cheaper, but they will not pass this on to consumers, they just may not raise prices as much.
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Dec 17th, 2024 20:46 EST change timezone

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