Disruptive Coffee Technologies

04/08/2025

I got a PR from Ikawa on their "new" 2x version of their roasters. It is 50g max like the Aria 3 and has a light in the roast camber like the Aria 3 but is SLOW and of course can not do preround coffee.
I asked ChatGPT4 about their claim to being "smoke free" and it was not surprised that it is limited to lighter (less smoke) roasts and does not remove any "It won’t filter out aromas or volatile organic compounds (VOCs)". On to the Aria 3 news In doing the temp calibration a few things have been found out about the "3". The induction heating is FAST, and even though using 1/4 the energy of conventional roasters. How fast? From ambit to 500f(260 c) for a empty roast chamber time is 60 seconds. On cooling side from 500f (260C) is 30 seconds. This means that with whole bean you will set up the profile using the CVS to match the profiles used in other drum machines as a start, I think that we are a lot faster but it's a starting point. On roasting powder this will mean that everything will happen much faster. In theory for agtron 22 roast 1 min with a cool down of 40 sec at a rpm of 100 with other lighter roasts being even less time.

04/03/2025

The Aria 3 is Finally Here – Shipping April 7th!
The Aria 3 test demo roaster, patent pending, represents the pinnacle of our expertise in induction heating, thin-shell roast chamber design, water cooling, adjustable RPM control, and low-airflow roasting—creating a completely smokeless process without the need for filters or afterburners. After extensive development, the Aria 3 is complete and ready to ship on Monday, April 7th!

Designed for unmatched flexibility, it accommodates everything from 16 mm AA whole beans to 0.5 mm pre-ground green coffee, making it a powerful tool for roasters, researchers, and innovators.

Precision, Speed, and Efficiency
Digital induction heating for rapid, even heat distribution in the thin-shell steel roast chamber.

1-second command intervals for heater time, duration, target temperature, and water cooling.

Ultra-fast IR temperature sensing for real-time accuracy.

Flexible step timing, ranging from 3 to 1000 seconds per test.

Adjustable roast chamber RPM, controlled via an external k**b so the RPM can be adjusted on the fly, with an independent PWM power supply for precise tuning.

The Aria 3 uses 1/4 the energy of conventional roasters and achieves roasts in 1/4 the time, drastically reducing both energy costs and roasting duration.

Intuitive and Easy to Use
With five profile selections accessible via a responsive touchscreen, the Aria 3 allows precise control over every stage of the roasting process. Its settings are stored in an easy-to-edit CSV file, conveniently housed on a thumb drive for seamless modification on a laptop, desktop, or phone.

Compact Yet Powerful
Powered by a Raspberry Pi Zero running custom 3.5 software, the Aria 3 operates on 120V or 220V while consuming only 360 watts—making it an energy-efficient yet high-performance roasting solution.

A Game-Changer in Coffee Roasting
The Aria 3 isn’t just another roaster—it’s a revolution in precision and versatility. Whether you're working with whole beans or pre-ground green coffee, this compact powerhouse is designed to push the boundaries of coffee roasting innovation. With its unique smokeless operation, which requires no filters or afterburners, it’s a cost-effective, cleaner, and more efficient solution for modern roasting.

Now Shipping to Key Testers!
The Aria 3 is now on its way to select testers, gathering insights from roasters, coffee scientists, and R&D teams. Stay tuned for real-world feedback and the next steps in shaping the future of coffee roasting.

02/24/2025

The future of coffee IS in particles.

What is a coffee particle?

Traditionally a coffee particle refers to a small piece or granule of coffee grounds that results from grinding after the roasting of coffee beans. As we will see when you particularize has a huge impact on energy consumption and time. These particles play a critical role in the process of brewing coffee, as their size and consistency significantly affect the extraction process and the resulting flavor of the coffee.
Key Characteristics of Coffee Particles:
1. Particle Size:
◦ The size of the coffee particles depends on the grind setting used during grinding.
◦ Common sizes include:
▪ Coarse: Suitable for French press or cold brew.
▪ Medium: Ideal for drip coffee makers or pour-over brewing.
▪ Fine: Used for espresso machines.
▪ Extra-fine: Used for Turkish coffee.
2. Surface Area:
◦ Smaller particles have a larger surface area relative to their volume, which allows for quicker extraction of coffee solubles during brewing.
3. Uniformity:
◦ Consistent particle size leads to even extraction, preventing over-extraction (bitterness) or under-extraction (sourness).
4. Composition:
◦ Coffee particles contain soluble compounds (caffeine, acids, sugars, etc.) and insoluble materials (fiber, oils, etc.).
◦ The soluble compounds dissolve in water during brewing, creating the coffee's flavor and aroma.
Understanding and controlling coffee particle size and distribution are essential for brewing the perfect cup of coffee, as it directly influences the taste and quality of the beverage.
There are huge differentials in particle sizes.
The standard value is PSD. Is Particle Size Distribution. This term is used to describe the range of sizes of coffee particles after grinding.

Why is the future in particles?
Imagine coffee that is inexpensive, available year around and from a wide range of “origins”. Cellular coffee, also known as lab-grown or cell-cultured coffee, offers several advantages over traditional coffee farming. These benefits span environmental, economic, and social domains:
1. Environmental Sustainability
• Reduced Deforestation: Traditional coffee farming often involves clearing forests, especially in biodiversity-rich areas. Cellular coffee production eliminates this need.
• Lower Water Use: Cultivating coffee beans is water-intensive, while cellular methods require significantly less water.
• Decreased Carbon Emissions: Cellular coffee production can have a smaller carbon footprint than conventional farming, which involves fertilizers, transportation, and processing.
• Biodiversity Preservation: By reducing the need for land use, cellular coffee helps protect ecosystems and wildlife habitats.
2. Consistent Quality
• Flavor and Profile Control: The production process allows precise control over flavor profiles, ensuring a consistent product every time.
• Resilience to Climate Change: Cellular coffee is unaffected by changing weather patterns, pests, and diseases that can compromise traditional crops.

3. Economic Stability
• Steady Supply: Cellular coffee is not subject to the seasonal and geographic constraints of traditional coffee farming, leading to a reliable year-round supply.
• Reduced Price Volatility: The stable production process can help mitigate the price fluctuations caused by crop failures and market changes.
4. Ethical and Social Benefits
• Alleviation of Labor Exploitation: Traditional coffee farming can involve exploitative labor practices. Cellular coffee production reduces reliance on low-paid agricultural labor.
• Enhanced Food Security: By using fewer resources, cellular coffee can free up land and resources for other essential food production.
5. Innovation and Customization
• Tailored Products: Producers can create customized blends with specific taste profiles, caffeine levels, and other attributes.
• Functional Additions: Cellular technology allows for the inclusion of additional nutrients or properties, potentially creating "healthier" coffee options.
6. Reduced Impact of Global Supply Chain Disruptions
• Cellular coffee can be produced locally in controlled environments, reducing dependency on long-distance supply chains and minimizing transportation emissions. By addressing the challenges of traditional coffee farming, cellular coffee presents a promising, sustainable alternative for meeting global coffee demand while preserving the planet.
What is cellular coffee?
Cellular coffee, also known as cell-cultured or lab-grown coffee, is an emerging field aiming to produce coffee sustainably without traditional farming. Several companies are pioneering this innovative approach:
• Pluri: Utilizing cell-based technology, Pluri produces coffee in laboratories, eliminating the environmental impacts associated with conventional coffee farming. Their process mimics natural conditions to ensure consistent quality and high yields with minimal resources.
• Stem: A Paris-based startup, Stem develops cell-cultured coffee targeting the specialty Arabica market. Their method involves cultivating coffee cells to replicate the flavor and aroma of traditional coffee, offering a sustainable alternative to conventional production.
• VTT Technical Research Center of Finland: VTT has successfully produced coffee cells in bioreactors through cellular agriculture. Their innovation aims to make coffee production more sustainable, addressing challenges like deforestation and water usage associated with traditional farming.
• Atomo Coffee: A Seattle-based startup, Atomo creates "bean-less coffee" by using up-cycled plant materials to mimic the taste and mouthfeel of coffee. Their process seeks to reduce the environmental footprint of coffee production.
• California Cultured: This company employs plant cell culture technology to produce coffee and cocoa with characteristics identical to traditional products, aiming to offer sustainable alternatives to conventional agriculture.
• Compound Foods: Part of Cult Food Science's portfolio, Compound Foods focuses on developing cell-based coffee, contributing to the growing field of sustainable coffee alternatives.
These companies are at the forefront of developing sustainable coffee solutions through cellular agriculture, aiming to meet increasing global demand while mitigating environmental impacts.
When to grind and why?
Lets ask a simple question why grind coffee?
Coffee is ground to increase the surface area of the coffee beans, allowing for optimal extraction of flavor, aroma, and other compounds during brewing. Here's a breakdown of why this process is essential:
1. Increased Surface Area. Grinding coffee beans exposes more of their interior surface to water, facilitating the release of soluble compounds. This ensures the water can extract the maximum amount of flavor and aroma during brewing.
2. Efficient Extraction. When hot water interacts with ground coffee, it dissolves a variety of compounds, including oils, acids, and caffeine. Grinding ensures these compounds are extracted efficiently in the limited brewing time.
3. Control Over Flavor. The grind size directly impacts the flavor of the coffee:
◦ Fine Grind: Ideal for espresso, where water passes through quickly under high pressure, requiring more exposed surface for proper extraction.
◦ Coarse Grind: Suitable for methods like French press, where the coffee steeps for a longer period, preventing over-extraction.
◦ Medium Grind: Works well for drip coffee makers and pour-over systems.
4. Versatility in Brewing Methods
• Different brewing methods require different grind sizes to match the time and pressure involved in extraction. Grinding allows you to tailor the coffee to your preferred brewing style.
5. Release of Aromatic Compounds
• Grinding breaks the beans into smaller particles, allowing aromatic compounds to be released and enhancing the coffee's sensory appeal. These aromas are fleeting, which is why freshly ground coffee is often preferred.
Grinding is a key step in turning coffee beans into the beverage we enjoy, as it unlocks their full potential for flavor and aroma.
Why do we grind coffee only after roasting?
The common reaction is you get a look like “whats wrong with you are you stupid?” and “We just do” and “To get maximum freshness”. So I asked a AI, it reads EVERYTHING (ChatGPT4) why. Its answer was predictable, but still surprising. It said that coffee un-roasted (green) is moist and rubbery, making them difficult to grind. They would clog grinders and result in uneven particles.
It did not say “its the way it’s been done for centuries” and it also did not say that all the equipment has been designed and built that way and why change it if not “broke”. Both of theses statements are true, and show how fundamental idea is, you just “do”.
Are there any problems grinding green un-roasted coffee?
The AI states that green un-roasted coffee is “difficult to grind” and “rubbery”. There are also the ones that the AI did not mention such as “its always been done that way” to “Whats wrong with you are you stupid?” I know from direct real world experience that the statements are BS.
The technical aspects of grinding green un-roasted coffee.
I want you to think of all the other seeds that are ground finely, rice, wheat, barley, flax, and many more. So the equipment to grind stuff is not only common but it’s cheap. Grinding other seeds “raw” has been done for centuries, so lets start with the basics. So the grinding part is a solved problem, so lets go even further in the dumb question mode.
Why do we even roast coffee?
According to the AI and all the other experts It is a transformation process. The process of roasting develops the flavor, aroma, and color of coffee beans.
This is why we roast coffee.
1. Flavor development: Raw (green) coffee beans are dense, acidic, and lack the complex flavors we associate with coffee. Green un-roasted raw coffee is high in anti oxidants and roasting destroys anti oxidants. The darker you roast the lower the levels of anti oxidants. Roasting triggers chemical reactions, such as the Maillard reaction and caramelization, which produce the rich, nuanced flavors of brewed coffee
2. Aroma enhancement: Roasting releases hundreds of aromatic compounds, giving coffee its enticing smell. The volatile compounds developed during roasting contribute to the signature scent of freshly brewed coffee.
3. Texture and grindability: Roasting reduces the moisture content ofgreen beans, making them less dense and more brittle. This makes them easier to grind for brewing
4. Color and appearance: Roasting changes the beans' color from green to shades of brown, which visually indicates the roast level (light, medium, or dark). The color also hints at the intensity of flavor.
5. Preservation and use: Green coffee beans can be stored for longer periods but lack the flavors consumers want. Roasted beans are ready to brew and have a shorter shelf life, ideal for immediate consumption.
We know you can grind green un-roasted coffee, but can you roast it? We know that you can roast green coffee, that is done all the time. All coffee roasters have experience in dealing with roasting coffee that is of different sizes. The normal range for peaberries is from between 4.75 mm and 6.75 mm in diameter. Maragogipe (elephant or super size) are huge and come in at Length: up to 15 mm, Width: up to 10 mm and are up to 5mm thick.
You can see that even among Arabica coffees the size rand is HUGE. Some other coffee’s grow where one seed such as is larger than the other such as Liberica. It is not uncommon and is grown in the Philippines (Barako), Malaysia, and parts of Africa. Most roasters hate coffee liberica as with the asymmetrical size of the green coffee it makes it impossible for the roaster to set up their roasting machine to provide an even roast, some will be over roasted some others under roasted and all in the same batch.

Why would you roast green ground coffee?
1. Energy efficient.
It requires less than ¼ the energy to bring the coffee up to the same agtron number
2. Time efficient.
It requires less than ¼ the time to bring the coffee up to the same agtron number.
3. Lower maintenance.
Requires no after burner of other smoke abatement systems
4. No consumer grinding.
No need for the noise of grinding. No need for the time it takes to grind coffee for use.
5. No smoke or odor during roasting.
This is the only other system that is inherently smoke and odor free.
6. Long shelf life.
As long as any other un-roasted coffee. This is of some controversy as to time with the norm being 2 years for aged Sumatran or as Café de L’Ambre of Tokyo have demonstrated that green coffee can be kept for decades.

Experts say that roasted coffee must degas. Do roasted coffee particles degas faster?
Roasting and all degassing is based on a simple equation of surface area versus volume roasted whole bean comes in at 300 and 600 square mm. Particularized is 0.785 square mm or 550 times LESS. This means of course that any degassing will take place 550 times faster. Roasting also will take less time and energy. There was no noticeable difference in acidity between ground and brewed whole bean and particularized.
Is this process controllable?
The simple answer is yes. This aspect is vital as we all know that as the
flavor changes dependent on the roast degree and the levels of anti
oxidants change with them from agtron 20 up to full green. The difference
is in the time and energy it takes.
It is all very simple when you think about it.
Think about the difference between a peaberry size coffee bean (3mm
diameter) and a huge AA coffee bean (8mm diameter). If you roast them
not only will the curve need to be different but so will the over all time. It's
a simple, surface area to volume. In the peaberry to AA example you have
14.13 mm v 268. for the AA a HUGE difference. This difference is why not
only will the partials roast faster they will degas faster. IA added advantage
is it appears that praticalizing (grinding the green un-roasted coffee) also
allows for it to have much lower % water thus making roasting faster and
preventing mold from forming.

What are the down sides to roasting particularized coffee?
The biggie is your current roaster will NOT work.
Why?
Your existing coffee roaster was not designed and built to deal with
particles that are 0.1mm to 0.5mm in diameter.

The ARIA system was designed from to roast particles no matter the size.
To roast successfully our new system had to be designed and built
a roasting system that is CLOSED. It is closed because no air flow is
wanted inside the roasting chamber. The reason for no airflow is the
particles are tiny, and light. They are the size of an espresso ground
roasted coffee and less. This also means that all smoke or odor is
contained within the roasting chamber. Imagine putting
table salt granules inside your existing roaster, it would be blown around
uncontrollably.
The ARIA roaster drum is smooth, solid and very thin.
The ARIA drum is made of very thin metal it is 0.25 mm in thickness. It is
metal so it reacts to the induction heating coil. The ARIA drum is sealed on
both ends preventing air movement or escape of any smoke or odor. The
inside of the roasting drum is smooth and can be coated with carbon but
has removable metal fins to provide agitation and to help move heat from
the skin of the roast chamber to the particles.
Many existing drum type coffee roasters have a screen drum they are
screen as they use airflow to (and in some cases recirculated air) to roast
coffee. The screen size is generally just less than 3 mm (about the size of
a peaberry) this is far larger than the 0.3 mm of the coffee partials. The
screen is also used to move chaff into a collection area.
The ARIA roaster uses induction heating not an open gas flame.
Most coffee roasters use a gas flame to heat the roast chamber there are a
very few that use electricity but even then they use nichrome wire this is
also known as resistance heating. Gas heating is generally unregulated
and run at one intensity, depending on a fast or slow profile. This means
that time is the variable the response time. Energy Input is measured in
minuets not 10ths of seconds. This is due to the design of the roaster system.
Induction heating is responsive
The induction system used in the ARIA his highly responsive and is
controlled down to the milliwatt level. The induction system is also binary
meaning it can be turned on and off rapidly, allowing for precise control of
the temperature. The ARIA roast profiles now use a maximum of 100 steps
with a temperature target for each of the 100 steps. The maximum number
of steps is infinite as is the temperature targets.
The ARIA system uses infrared sensing of the roast chamber skin
Infrared temperature sensing, is non contact and is very responsive. As
ARIA uses induction heating of a thin metal roast chamber and very small
particles a responsive non contact temperature sensing system was vital.
This very fast system with a response time of 10–30 milliseconds that is
even faster than the induction heating system, one that is very responsive.
Other existing coffee roasters use k type thermocouple that measure air
temperature. This system works well but slowly reading a temperature
change 500 to 5000 milliseconds. Given the “bean” will 2.5mm size and
larger it works well if slowly.
The ARIA system uses water of the roast chamber.
Given the thin roast chamber only 0.25 mm thick it moves heat to and from the roast chamber efficiently. ARIA is a closed system this is vital.
This means that the water (chilled down to 33F or ambient) will cool the
roasted particles rapidly. This is due in part of their small thermal mass but
also that the system is efficient. As a safety system until the IR sensor
reads that the roast chamber is below 120 F (48C) the system will not
signal “done”. Conventional roasting machines use ambient air cooling.
This can be quite effective if the ambient air temperature is low below 33 F
but can be very inefficient if the ambient air is hot and humid.
Summation.
We see a huge decrease in the energy needed to “roast” coffee. This is not
small number. Every kilo or lb of coffee used every year requires the use of
3581 Btu's of natural gas. Worldwide, approximately 40 trillion Btu’s are
used annually for just coffee roasting. We can lower that to 10 trillion Btu’s
annually or less. On average, afterburners our process does not need
consume about 25-50% of the energy required for the roasting process. So
when we roll in the afterburner value world wide coffee roasting is 50 trillion
Btu’s. This ad's up, currently we use $240 million to roast coffee. Using our
process we could lowering it to $ 40 million a saving of over $200,000,000.
The generation of CO2 gas from the combustion of fossil fuels is a huge
global problem. The roasting of coffee annually adds 8.8 billion pounds of
of CO₂ annually, but using our process we can lower that to 2.2 billion
pounds, still a lot, but a lot less. This does not include the reduction in cost
of using particles in the drying and shipping of coffee world wide. This too
adds up as transporting is ground green is 10-15% more efficient than
green whole bean. Particles are much faster to dry to a 10% water level
than whole bean and can take 1/5th the time.

In conclusion
Deciding on when to grind coffee matters a LOT. Grinding “green” is not
only requires less energy it is also faster, cheaper, easier to handle, and
provides a longer shelf life than conventional methods. It makes roasting of
coffee, fast, easy, smoke and odor free and something that every home,
cafe or office can and should do and opens up these markets.

02/01/2025

well worth the read. Elaine Jutamulia ’24 took a sip of coffee with a few drops of anise extract. It was her second try.
“What do you think?” asked Omar Orozco, standing at a lab table in MIT’s Breakerspace, surrounded by filters, brewing pots, and other coffee paraphernalia.
“I think when I first tried it, it was still pretty bitter,” Jutamulia said thoughtfully. “But I think now that it’s steeped for a little bit — it took out some of the bitterness.”
Jutamulia and current MIT senior Orozco were part of class 3.000 (Coffee Matters: Using the Breakerspace to Make the Perfect Cup), a new MIT course that debuted in spring 2024. The class combines lectures on chemistry and the science of coffee with hands-on experimentation and group projects. Their project explored how additives such as anise, salt, and chili oil influence coffee extraction — the process of dissolving flavor compounds from ground coffee into water — to improve taste and correct common brewing errors.
Alongside tasting, they used an infrared spectrometer to identify the chemical compounds in their coffee samples that contribute to flavor. Does anise make bitter coffee smoother? Could chili oil balance the taste?
“Generally speaking, if we could make a recommendation, that’s what we’re trying to find,” Orozco said.
A three-unit “discovery class” designed to help first-year students explore majors, 3.000 was widely popular, enrolling more than 50 students. Its success was driven by the beverage at its core and the class’s hands-on approach, which pushes students to ask and answer questions they might not have otherwise.
For aeronautics and astronautics majors Gabi McDonald and McKenzie Dinesen, coffee was the draw, but the class encouraged them to experiment and think in new ways. “It’s easy to drop people like us in, who love coffee, and, ‘Oh my gosh, there’s this class where we can go make coffee half the time and try all different kinds of things?’” McDonald says.
Percolating knowledge
The class pairs weekly lectures on topics such as coffee chemistry, the anatomy and composition of a coffee bean, the effects of roasting, and the brewing process with tasting sessions — students sample coffee brewed from different beans, roasts, and grinds. In the MIT Breakerspace, a new space on campus conceived and managed by the Department of Materials Science and Engineering (DMSE), students use equipment such as a digital optical microscope to examine ground coffee particles and a scanning electron microscope, which shoots beams of electrons at samples to reveal cross-sections of beans in stunning detail.
Once students learn to operate instruments for guided tasks, they form groups and design their own projects.
“The driver for those projects is some question they have about coffee raised by one of the lectures or the tasting sessions, or just something they’ve always wanted to know,” says DMSE Professor Jeffrey Grossman, who designed and teaches the class. “Then they’ll use one or more of these pieces of equipment to shed some light on it.”
Grossman traces the origins of the class to his initial vision for the Breakerspace, a laboratory for materials analysis and lounge for MIT undergraduates. Opened in November 2023, the space gives students hands-on experience with materials science and engineering, an interdisciplinary field combining chemistry, physics, and engineering to probe the composition and structure of materials.
“The world is made of stuff, and these are the tools to understand that stuff and bring it to life,” says Grossman. So he envisioned a class that would give students an “exploratory, inspiring nudge.”
“Then the question wasn’t the pedagogy, it was, ‘What’s the hook?’ In materials science, there are a lot of directions you could go, but if you have one that inspires people because they know it and maybe like it already, then that’s exciting.”
Cup of ambition
That hook, of course, was coffee, the second-most-consumed beverage after water. It captured students’ imagination and motivated them to push boundaries.
Orozco brought a fair amount of coffee knowledge to the class. In 2023, he taught in Mexico through the MISTI Global Teaching Labs program, where he toured several coffee farms and acquired a deeper knowledge of the beverage. He learned, for example, that black coffee, contrary to general American opinion, isn’t naturally bitter; bitterness arises from certain compounds that develop during the roasting process.
“If you properly brew it with the right beans, it actually tastes good,” says Orozco, a humanities and engineering major. A year later, in 3.000, he expanded his understanding of making a good brew, particularly through the group project with Jutamulia and other students to fix bad coffee.
The group prepared a control sample of “perfectly brewed” coffee — based on taste, coffee-to-water ratio, and other standards covered in class — alongside coffee that was under-extracted and over-extracted. Under-extracted coffee, made with water that isn’t hot enough or brewed for too short a time, tastes sharp or sour. Over-extracted coffee, brewed with too much coffee or for too long, tastes bitter.
Those coffee samples got additives and were analyzed using Fourier Transform Infrared (FTIR) spectroscopy, measuring how coffee absorbed infrared light to identify flavor-related compounds. Jutamulia examined FTIR readings taken from a sample with lime juice to see how the citric acid influenced its chemical profile.
“Can we find any correlation between what we saw and the existing known measurements of citric acid?” asks Jutamulia, who studied computation and cognition at MIT, graduating last May.
Another group dove into coffee storage, questioning why conventional wisdom advises against freezing.
“We just wondered why that’s the case,” says electrical engineering and computer science major Noah Wiley, a coffee enthusiast with his own espresso machine.
The team compared methods like freezing brewed coffee, frozen coffee grounds, and whole beans ground after freezing, evaluating their impact on flavor and chemical composition.
“Then we’re going to see which ones taste good,” says Wiley. The team used a class coffee review sheet to record attributes like acidity, bitterness, sweetness, and overall flavor, pairing the results with FTIR analysis to determine how storage affected taste.
Wiley acknowledged that “good” is subjective. “Sometimes there’s a group consensus. I think people like fuller coffee, not watery,” he says.
Other student projects compared caffeine levels in different coffee types, analyzed the effect of microwaving coffee on its chemical composition and flavor, and investigated the differences between authentic and counterfeit coffee beans.
“We gave the students some papers to look at in case they were interested,” says Justin Lavallee, Breakerspace manager and co-teacher of the class. “But mostly we told them to focus on something they wanted to learn more about.”
Drip, drip, drip
Beyond answering specific questions about coffee, both students and teachers gained deeper insights into the beverage.
“Coffee is a complicated material. There are thousands of molecules in the beans, which change as you roast and extract them,” says Grossman. “The number of ways you can engineer this collection of molecules — it’s profound, ranging from where and how the coffee’s grown to how the cherries are then treated to get the beans to how the beans are roasted and ground to the brewing method you use.”
Dinesen learned firsthand, discovering, for example, that darker roasts have less caffeine than lighter roasts, puncturing a common misconception. “You can vary coffee so much — just with the roast of the bean, the size of the ground,” she says. “It’s so easily manipulatable, if that's a word.”
In addition to learning about the science and chemistry behind coffee, Dinesen and McDonald gained new brewing techniques, like using a pour-over cone. The pair even incorporated coffee making and testing into their study routine, brewing coffee while tackling problem sets for another class.
“I would put my pour-over cone in my backpack with a Ziploc bag full of grounds, and we would go to the Student Center and pull out the cone, a filter, and the coffee grounds,” McDonald says. “And then we would make pour-overs while doing a P-set. We tested different amounts of water, too. It was fun.”
Tony Chen, a materials science and engineering major, reflected on the 3.000’s title — “Using the Breakerspace to Make the Perfect Cup” — and whether making a perfect cup is possible. “I don’t think there’s one perfect cup because each person has their own preferences. I don't think I’ve gotten to mine yet,” he says.
Enthusiasm for coffee’s complexity and the discovery process was exactly what Grossman hoped to inspire in his students. “The best part for me was also just seeing them developing their own sense of curiosity,” he says.
He recalled a moment early in the class when students, after being given a demo of the optical microscope, saw the surface texture of a magnified coffee bean, the mottled shades of color, and the honeycomb-like pattern of tiny irregular cells.
“They’re like, ‘Wait a second. What if we add hot water to the grounds while it’s under the microscope? Would we see the extraction?’ So, they got hot water and some ground coffee beans, and lo and behold, it looked different. They could see the extraction right there,” Grossman says. “It’s like they have an idea that’s inspired by the learning, and they go and try it. I saw that happen many, many times throughout the semester.”

A new MIT coffee class combines coffee science, brewing techniques, and hands-on experiments to explore coffee and its chemical composition, empowering students to exercise their curiosity through group projects.