Silicon Photonics: The Next Silicon Revolution?
Summary
TLDRSilicon Photonics is a revolutionary technology that merges silicon manufacturing with photonics for high-speed data transmission. It aims to replace copper wiring with optical fibers for faster, more efficient communication. Despite challenges like silicon's inability to emit light and the lack of a modulator, the industry has made strides with workarounds and innovations, finding its niche in data centers and LiDAR systems. However, it seeks a broader market to realize its full potential and avoid the pitfalls faced by MEMS technology.
Takeaways
- 🌌 Silicon Photonics is a futuristic technology that involves the manipulation of light using silicon-based components, similar to how MEMS applies CMOS processes to the mechanical world.
- 🚀 The term 'Photonics' refers to technologies that transmit and manipulate light, or photons, which is crucial for optical data transmission and has advantages over traditional electrical signals in terms of speed and heat generation.
- 🔌 The shift to using light for long-distance communications in the 1990s revolutionized the industry, allowing for higher data volume transmissions through optical fibers.
- 🌐 Silicon is a key material in the electronics industry due to its abundance, low cost, and scalability, which has led engineers to explore its application in photonics.
- 💡 The ideal silicon photonics system would consist of five components: a light source, pathways to manipulate light, modulators, photodetectors, and traditional CMOS electronics.
- 🚧 Silicon's inability to emit light due to its indirect bandgap presents a significant challenge for creating a pure silicon light source, leading to the development of workarounds like external lasers or hybrid integration.
- 🛠 Silicon modulators have seen steady progress, with Intel announcing a high-speed optical modulator in 2004 and a fully integrated CMOS silicon photonics transceiver in 2012.
- 💼 The data center industry, particularly hyperscalers like AWS, Google, and Microsoft, has become a significant market for silicon photonics due to the need for high-speed, efficient data transmission within their vast server networks.
- 🛰 The potential application of silicon photonics in LiDAR systems for autonomous vehicles offers the possibility of reducing costs and increasing resolution by integrating optical components onto a chip.
- 🏭 Silicon photonics products require a specialized fabrication process using silicon-on-insulator (SOI) wafers, with companies like GlobalFoundries and Intel leading in this space.
- 💡 The future of silicon photonics may lie in its ability to find a large and valuable commercial market, as it currently faces challenges in becoming mainstream due to competition with existing technologies and market size limitations.
Q & A
What is Silicon Photonics?
-Silicon Photonics is a technology that applies modern nanoscale CMOS processes to the optical realm, enabling the transmission and manipulation of light, or photons, for high-speed data communication.
Why did networking companies switch from copper wires to optical fibers for data transmission?
-Networking companies switched to optical fibers because light travels at the speed of light, allowing for super-high frequency transmissions and higher data volume. Optical fibers also avoid the slowdown and heat generation issues associated with electron movement in copper wires.
What are the benefits of using multiple light wavelengths in the same optical fiber?
-Using multiple light wavelengths allows for the transmission of multiple signals through the same fiber without interference, greatly increasing the capacity for data transmission.
Why is silicon an attractive material for photonics applications?
-Silicon is attractive due to its abundance, low cost, and the ability to scale manufacturing processes. It has been widely studied and used in the electronics industry, making it a candidate for integrating photonics with electronics.
What are the five components necessary for a monolithic silicon photonics chip?
-The five components are: 1) A light source, usually a laser; 2) Passive structures for manipulating light; 3) A modulator to convert digital electronic signals to optical signals; 4) A photodetector to convert optical signals back to electronic signals; and 5) Traditional CMOS electronics for support functions.
What are the two main issues with integrating a light source into silicon photonics?
-The two main issues are that silicon cannot emit light on its own due to its indirect bandgap, and it does not exhibit the Pockels effect, which is necessary for modulating light with electrical fields.
What is the significance of the development of silicon-based high-speed optical modulators?
-The development of high-speed optical modulators, such as the one announced by Intel in 2004, marked a significant breakthrough, enabling the conversion of continuous laser light into digital signals, which is essential for data communication.
How does silicon photonics benefit data centers?
-Silicon photonics can integrate transceiver functionality onto chips, replacing legacy components, which saves on cost, power, and labor, and addresses bandwidth bottlenecks in data centers.
What potential applications does silicon photonics have in the sensor and LiDAR markets?
-Silicon photonics can potentially reduce the cost and size of LiDAR systems by integrating multiple optical components onto a chip, which is crucial for high-resolution, compact, and affordable sensors used in applications like autonomous driving.
What challenges does the silicon photonics industry face in terms of market adoption and integration?
-The industry faces challenges such as finding large and valuable markets for its technology, as well as technical hurdles like the lack of a pure silicon-based laser and the difficulty of making photonics components smaller than the wavelength of light they use.
What is the current state of silicon photonics in terms of manufacturing and market presence?
-Silicon photonics products are being manufactured using silicon-on-insulator wafers and are finding their niche in data centers and potentially in LiDAR and sensor markets. Companies like Intel, Cisco, and MACOM are selling millions of units annually, but the industry is still seeking broader mainstream adoption.
Outlines
🌌 Introduction to Silicon Photonics
The first paragraph introduces the concept of Silicon Photonics, a technology that applies nanoscale CMOS processes to the optical realm. It explains the shift from using electrical signals through copper wires to transmitting data via light through optical fibers, which is faster and more efficient. The paragraph also discusses the challenges of integrating photonics with silicon, including the need for a light source and modulator, and the limitations of silicon's inability to emit light natively.
🔍 The Silicon Optics Dream and Its Challenges
This paragraph delves into the aspirations of creating a monolithic silicon chip for photonics, which would include a light source, pathways for light manipulation, modulators, photodetectors, and traditional CMOS electronics. It highlights two main issues: silicon's inability to emit light due to its indirect bandgap and the lack of the Pockels effect, which is necessary for modulating light with electric fields. The paragraph also touches on the history of silicon photonics development and the workarounds used to overcome these challenges, such as external lasers and hybrid integration.
🚀 Advancements in Silicon Modulators and Data Center Applications
The third paragraph discusses the progress made in silicon modulators, from the announcement of Intel's high-speed optical modulator in 2004 to the development of fully integrated CMOS silicon photonics transceivers. It explains how these advancements have allowed the silicon photonics industry to move out of the laboratory and into commercial applications, particularly in data centers. The paragraph also introduces the concept of hyperscalers and how silicon photonics can improve internal data transmission performance, leading to significant cost, power, and bandwidth savings.
🛰️ LiDAR, Sensors, and the Future of Silicon Photonics
The final paragraph explores the potential of silicon photonics in the sensor and LiDAR markets, highlighting its ability to reduce costs and increase resolution for autonomous driving applications. It also discusses the manufacturing process of silicon photonics, the role of different fabs in the industry, and the challenges faced in finding large-scale commercial markets for this technology. The paragraph concludes by comparing silicon photonics to the MEMS industry and pondering its potential to become the next silicon revolution.
Mindmap
Keywords
💡Silicon Photonics
💡Photonics
💡MEMS
💡Optical Fiber
💡Wavelength Division Multiplexing (WDM)
💡Silicon Optics Dream
💡Transceiver
💡Indirect Bandgap
💡Pockels Effect
💡Mach-Zehnder Interferometer (MZI)
💡Data Center
💡LiDAR
💡Silicon-on-Insulator (SOI)
💡Hyperscaler
Highlights
Silicon Photonics is an emerging technology that applies nanoscale CMOS processes to the optical realm.
Photonics technologies transmit and manipulate light, or photons, for optical data transmission.
Optical fiber communication is faster and more efficient than traditional copper wire due to the speed of light.
Wavelength division multiplexing allows multiple signals to be sent through the same fiber without interference.
Silicon is a widely studied and used element in electronics due to its abundance, low cost, and scalability.
Engineers aim to integrate CMOS manufacturing processes with photonics to create a monolithic silicon chip.
A complete photonics system requires five components: a light source, pathways, modulator, photodetector, and CMOS electronics.
Silicon's inability to emit light due to its indirect bandgap presents a significant challenge for silicon photonics.
Researchers have modified silicon to emit light, but commercial silicon-based lasers are not yet available.
Silicon's lack of the Pockels effect makes it difficult to create modulators for converting electrical signals to optical signals.
The development of silicon photonics began in the mid-1980s with the work of Richard Soref on adjusting silicon's refractive index.
Intel announced the first high-speed silicon-based optical modulator in 2004, using a Mach-Zehnder interferometer.
In 2012, Intel introduced a fully integrated CMOS silicon photonics transceiver with a ring modulator device.
Silicon photonics has found its first major commercial application in data centers, improving internal performance.
Hyperscalers like AWS, Google, and Microsoft are driving the demand for silicon photonics in data centers.
Silicon photonics has potential in the sensor and LiDAR markets, offering cost and size advantages.
Silicon photonics products use silicon-on-insulator wafers, requiring a specialized fabbing process.
GlobalFoundries and Intel are significant players in silicon photonics manufacturing, with TSMC focusing on integration schemes.
Silicon photonics faces challenges in finding a large and valuable commercial market to fulfill its potential.
The industry is exploring the use of silicon photonics in microprocessors to disrupt traditional semiconductors.
Silicon photonics is in search of a market that can capitalize on its futuristic technology and applications.
Transcripts
Silicon Photonics. What a cool-sounding word.
It sounds like something from the age of the Jetsons. But
behind that futuristic phrase is a simple need.
If MEMS is the result of applying modern nanoscale CMOS processes to the mechanical world,
then doing the same for the optical realm gives us Silicon photonics.
In this video, I want to talk about another magic silicon technology.
One that’s starting to make a splash in the contemporary technology world.
## Photonics
Let us break it down - starting with "Photonics".
Photonics. What does that mean? Lasers? Sharks with lasers?
Eyeglasses? Lithography machines? How does that jive with the silicon world?
In the context I am talking about here, photonics technologies transmit and manipulate light - in
the form of light particles or "photons". It is related to the world of optical data transmission.
Previously, networking companies communicated using electrical signals sent
through copper wire. The issue is that the electrons traveling through such
wires interact with other atoms, which slows them down and generates heat.
By the 1990s, networking companies found themselves struggling to deal with exploding
data traffic network demands. They revolutionized long distance communications by switching
to using light - sent via optical fiber - to efficiently transmit data across great distances.
Light moves through optical fiber at the speed of light. Nothing is faster than the speed of light.
This lets us transmit optical signals at super-high frequencies,
which means higher data volume transmissions. Later on, engineers took the concept yet
another step forward - sending multiple signals through the same fiber by using
different light wavelengths that won't interfere with each other.
Today, optical fiber technologies dominate the long-distance communications space. Over 2 billion
kilometers of optical fiber have been deployed, enough to wrap around the world over 50,000 times.
## The Silicon Optics Dream
Now, silicon. The nano-electronics industry has been using silicon for decades.
The element is the single most widely studied element in human history.
It is plentiful, low-cost and allows for massive scale.
People have been able to make silicon do amazing things - billions of transistors
on one wafer. Entire systems on chips that are faster, smaller, and cheaper than their priors.
And for that reason, engineers have wanted to
bring the titanic scale of modern CMOS manufacturing - with its EDAs,
PDKs, and all the other tools and processes used for it - over to the photonics world.
Furthermore, transistors on traditional chips right now are still communicating
using electrons through wires. What if you were to replace those wires and electrons
with optical fibers and light? More on that later.
## The Five Photonic Ingredients
Dreams of a monolithic silicon chip - meaning everything on it being made of
a single material system - transmitting and manipulating light date back to the 1970s.
Such a system would have five components:
One. A light source, usually a laser;
Two. Routes and pathways to manipulate light. Bend it, guide it, filter it, couple it,
split it, and combine it - kind of like optical fiber does but just within the integrated chip.
These are broadly referred to as passive structures,
but as with legos there are different shapes and structures with their own names;
Three and Four. Ways to convert digital electronic signals into digital optical
signals and vice versa. The former is called a modulator, three. The latter
is a photodetector, four, which makes sense if you think about it;
A component that can do both modulator and photodetector work
is called a transceiver. In data centers, a transceiver sits at each end of the optical
cable, converting light data to electrical data back and forth.
And finally, number five, we need traditional CMOS
electronics to accompany the various aforementioned photonics components.
These serve support functions like encoding and decoding certain data items.
Anyway. So there you have it, a complete photonics system
that researchers are trying to incorporate all onto a single monolithic chip. But there’s one
big issue. Actually, two. And they have to do with the light source and the modulator.
## The Two Issues
The first is that, on its own, silicon cannot emit light. Crystalline silicon has what is called
an indirect bandgap. This prevented it from being used for the first Light Emitting Diodes
or LEDs and also means that it cannot lase.
Without lasing, we cannot use silicon to make light. No pure silicon light source.
Researchers and engineers have to modify the silicon structure to force it to emit light. For
instance, they implanted boron into the silicon to finally create efficient, room-temperature
silicon-based LEDs. But commercial silicon-based lasers still aren't there yet.
Second, silicon's crystal structure means that it does not exhibit the Pockels effect.
The Pockels effect describes a phenomenon where you can use an electric field to
control how fast light goes through a certain object. In other words, its refractive index.
Lasers typically lase continuously. The modulator's purpose is to convert
its continuous lasing into a digital signal. The preferred way to do this
is with a material sitting in front of the light, changing its intensity by absorbing it.
If we cannot control light's progress through silicon using electrical fields
then we cannot convert digital electrical signals into digital light signals. No modulator.
These two big issues make it that much harder to produce a fully-integrated photonics device
out of pure silicon using the same methods we use to make an Apple A15,
Intel Core, or MEMS accelerometer part.
Early optics researchers instead focused on other
materials and made a great deal of progress with gallium arsenide and indium phosphide.
## Development
Silicon photonics as we know it today starts in the mid-1980s
with the work of Richard Soref. In 1987, he co-authored a paper discussing how
silicon can be manipulated into adjusting its refractive index.
From there, the industry was able to replicate one of the elementary
building blocks of a semiconductor electronic devices - called a P-N
junction - using a type of photonic passive structure called a waveguide.
This kickstarted the silicon photonics industry, which began work on building
out a photonics system with a practical light source and modulator.
The light source is where silicon faces its greatest challenge.
Scientists have tried a lot of things in order to make it lase.
A silicon-based laser is considered the "Holy Grail" of the silicon photonics space - the
final piece of the puzzle. But with that still far off, engineers settled on workarounds.
The most pragmatic workaround is to use an external laser positioned outside the chip itself.
This has the added benefit of keeping the chip from getting overheated.
Another is to bond a pre-made laser made from a different material like
Indium phosphide - something known as hybrid integration.
Today, most commercial silicon photonics providers do one of the two.
## The Modulator
Silicon modulators had been studied from the very beginning, with slow but steady breakthroughs
throughout the 1980s and 1990s. First in shrinking the device and then in speeding up its throughput.
In 2004, Intel announced the first silicon-based high-speed optical modulator, meaning to have a
bandwidth over 1 gigahertz. This attracted huge media attention and represents a big breakthrough.
That 2004 system used a Mach-Zehnder interferometer - shortened to MZI.
These modulators work by splitting light into two
wavelengths and then recombining them to replicate a 1 or 0 signal.
Then in 2012, Intel announced their first fully integrated CMOS silicon photonics transceiver
with four channels, each at 25 Gigabit per second. It was fabbed with a 90 nanometer process.
This used a different type of modulator - a ring
modulator device that offers size benefits over the MZI.
With these advancements, the silicon photonics industry managed to progress
out of the laboratory despite still lacking a pure silicon-based laser. The industry quickly
found its first big commercialization opportunity inside the data center.
## The Data Center
A "Hyperscaler" is a term that describes Alibaba, AWS,
Google and Microsoft - companies offering immense cloud computing scalability to their customers.
To do this, they are building out titanic data centers - spending
tens of billions a year in capital expenditure.
There is more data transmitting between a couple hundred servers within a single hyperscaler data
center than what goes between the east and west halves of the United States public internet.
Thus the hyperscalers are always looking for new ways to improve their internal performance.
If you might recall from earlier, transceivers are
products that convert between digital optical and digital electrical signals.
They are a separate item that is plugged into the switchgear at the top of each server rack.
Data flows through optical fiber into the servers through this equipment.
With silicon photonics you can now integrate transceiver functionality
right onto the chip - replacing the legacy component. Using them saves on cost,
power, and labor and cracks a bandwidth bottleneck.
Today, companies like Intel, Cisco, and MACOM are selling millions of units a year. And photonic
components will continue to take share from legacy optics and copper wire in this expanding space.
## LiDAR and Sensors
Silicon photonics's biggest market in the short term will likely be in the data center.
But there is some potential in the sensor and LIDAR markets.
LiDAR uses light to help acquire a 3-D picture of a particular environment.
As the name implies, it works similar to RADAR.
But since optical light waves are so much smaller than radio waves, you can get higher resolutions.
It is seen as an important part of the autonomous driving puzzle.
The problem is that LiDAR setups are rather expensive. Depending on what you are using,
a single system can cost up to $70,000. They are also quite bulky, which has its own issues.
A silicon photonics-based LiDAR system offers the possibility of integrating
many discrete optical components right onto the chip. This would drastically
bring down LiDAR costs in addition to shrinking it to a more manageable size.
There are a number of companies pursuing this space. Intel subsidiary Mobileye
recently presented a small LiDAR system on chip with integrated lasers.
This is a pretty crowded space, with notable other players including Pointcloud,
Aeva, Voyant Photonics, and Analog Photonics. LiDARs are so hot right now.
## Fabs
Silicon photonics products use silicon-on-insulator or SOI wafers.
These are wafers with special layers - usually silicon dioxide - in addition to the silicon.
The layers' contrasting refractive indices help confine light.
Because of this, silicon photonics require a slightly different fabbing process a couple
years behind the leading edge. This makes it a speciality node with special opportunities
for foundries not looking to compete for silly things like 3 nanometers.
GlobalFoundries in particular has done a lot in the space. They had acquired a great deal
of relevant IP from IBM when they acquired Big Blue's Microelectronics division back in 2014.
Dylan Patel of SemiAnalysis - which I recommend - seems to believe that they are the market leader.
It's great for them after they abandoned going for the leading edge a few years back.
Intel has been an R&D pioneer for silicon photonics for a very long time.
They are also setting up a foundry and I feel that they would be missing out
if they didn't offer some of that IP and capability to outsiders.
And finally, TSMC. They have not offered much in this space,
an absence that more than a few have noticed.
Recently, it seems like their corporate strategy has been building up integration schemes that
allow silicon photonics chiplets to work together seamlessly with traditional semiconductors.
I’ve been wondering about this for a while and here’s my thinking. The issue seems to
be one of volume. The single biggest market is transceivers. A market research publication
estimates about 50-75 million transceiver units sold annually over the next few years.
Assuming a 200 millimeter SOI wafer,
a 25 millimeter die, and 100% yield then that's about 40-60,000 wafers for an entire industry.
Less than a month's production for a typical mega-fab. Broken down to any one customer,
that's just a few days' run at a foundry. I guess for TSMC, the juice isn’t worth the squeeze.
## The Next Silicon Revolution?
It illustrates one of the challenges the industry now faces. Even if it takes
over the entirety of the transceiver and LiDAR markets, what other big markets are out there?
Investors and enterprises have poured hundreds of millions of dollars into silicon photonics
R&D over the years. And it's yielded some fruits but not enough to go mainstream.
Thus some startups have sought to achieve the dream of the 1970s. Replacing the copper
wiring on chips with optical fiber to create a silicon photonics microprocessor capable of
disrupting traditional semiconductors. But there are challenges here too.
Today's leading edge transistors now have feature sizes only a few nanometers large. But photonics
components cannot be made smaller than the wavelengths of the light they carry. This tops
out at about 1 micrometer. Electrons on the other hand, have wavelengths of just a few nanometers.
At the 7 nanometer node, 1 square micrometer of real estate can house over a hundred
transistors - a very high opportunity cost. It pushes the industry away from highly-integrated
silicon photonics monoliths and towards packaging solutions that pair photonics
and traditional chiplets together. Which might explain what TSMC is doing right now.
It's not a dealbreaker. Like I said,
there are a few startups out there working on it. But it is something to think about.
## Conclusion
I discussed in an earlier video the situation faced by the MEMS industry.
That industry sells millions of units each year for everyday items
like accelerometers and sensors. Units-wise, it’s a legitimate hit.
However, each MEMS die sells for cents - with the majority of value accruing to the packaging.
This has stifled innovation and made MEMS commercialization extremely difficult.
As a result, the technology has yet to really hit its financial potential
as the next silicon revolution.
Silicon photonics is a technology from the future, vying to change the way things are done. But it
also happens to be a technology in search of a commercial market big and valuable enough to
fulfill its potential. Without that, it risks suffering the same fate as its elder sibling.
関連動画をさらに表示
How Does LIGHT Carry Data? - Fiber Optics Explained
Why This New CD Could Change Storage
Come funziona il bluetooth?
Optical fiber cables, how do they work? | ICT #3
GET IN EARLY! I'm Investing In This HUGE AI Chip Breakthrough
Donald Cornwell plenary talk: NASA's Optical Communications Program: 2015 and Beyond
5.0 / 5 (0 votes)