A district court judge said in March that hot conditions for inmates are “plainly unconstitutional.”

Baltimore, Annapolis and Anne Arundel County argue that lower courts mischaracterized the cases by echoing industry assertions.

Assemblymember Lisa Calderon is facing a Friday deadline to get her bill through the Assembly.

Activists left it at the Paris headquarters of energy giant EDF to protest France’s imports of Russian energy.

It would be an unwelcome development for a government focused heavily on food security and could force a rethink on imports.

Energize Capital is seeking to back new energy companies, as well as startups that will make manufacturing more efficient and build out U.S. infrastructure.

Nature Climate Change, Published online: 05 June 2025; doi:10.1038/s41558-025-02342-w

Current European Union policies are insufficient to achieve residential heating decarbonization targets. Substantial subsidies for heat pumps and carefully targeted incentives for home renovation are critical to efficiently and affordably meet climate goals. We emphasize the importance of adapting strategies to national contexts.

Nature Climate Change, Published online: 05 June 2025; doi:10.1038/s41558-025-02351-9

Mitigation actions can have large-scale health co-benefits, which, however, are not effectively incorporated into policy design and implementation. This Perspective overviews the health co-benefits and cost-effectiveness of climate policies and discusses ways to improve their policy relevance.

Nature Climate Change, Published online: 05 June 2025; doi:10.1038/s41558-025-02348-4

Decarbonizing the residential sector is essential for net-zero targets, and the EU has established ambitious policy packages with various instruments. This research shows that beyond carbon trading programmes, massive heat-pump subsidies and targeted energy renovation incentives are needed.

Ready for that long-awaited summer vacation? First, you’ll need to pack all items required for your trip into a suitcase, making sure everything fits securely without crushing anything fragile.

Because humans possess strong visual and geometric reasoning skills, this is usually a straightforward problem, even if it may take a bit of finagling to squeeze everything in.

To a robot, though, it is an extremely complex planning challenge that requires thinking simultaneously about many actions, constraints, and mechanical capabilities. Finding an effective solution could take the robot a very long time — if it can even come up with one.

Researchers from MIT and NVIDIA Research have developed a novel algorithm that dramatically speeds up the robot’s planning process. Their approach enables a robot to “think ahead” by evaluating thousands of possible solutions in parallel and then refining the best ones to meet the constraints of the robot and its environment.

Instead of testing each potential action one at a time, like many existing approaches, this new method considers thousands of actions simultaneously, solving multistep manipulation problems in a matter of seconds.

The researchers harness the massive computational power of specialized processors called graphics processing units (GPUs) to enable this speedup.

In a factory or warehouse, their technique could enable robots to rapidly determine how to manipulate and tightly pack items that have different shapes and sizes without damaging them, knocking anything over, or colliding with obstacles, even in a narrow space.

“This would be very helpful in industrial settings where time really does matter and you need to find an effective solution as fast as possible. If your algorithm takes minutes to find a plan, as opposed to seconds, that costs the business money,” says MIT graduate student William Shen SM ’23, lead author of the paper on this technique.

He is joined on the paper by Caelan Garrett ’15, MEng ’15, PhD ’21, a senior research scientist at NVIDIA Research; Nishanth Kumar, an MIT graduate student; Ankit Goyal, a NVIDIA research scientist; Tucker Hermans, a NVIDIA research scientist and associate professor at the University of Utah; Leslie Pack Kaelbling, the Panasonic Professor of Computer Science and Engineering at MIT and a member of the Computer Science and Artificial Intelligence Laboratory (CSAIL); Tomás Lozano-Pérez, an MIT professor of computer science and engineering and a member of CSAIL; and Fabio Ramos, principal research scientist at NVIDIA and a professor at the University of Sydney. The research will be presented at the Robotics: Science and Systems Conference.

Planning in parallel

The researchers’ algorithm is designed for what is called task and motion planning (TAMP). The goal of a TAMP algorithm is to come up with a task plan for a robot, which is a high-level sequence of actions, along with a motion plan, which includes low-level action parameters, like joint positions and gripper orientation, that complete that high-level plan.

To create a plan for packing items in a box, a robot needs to reason about many variables, such as the final orientation of packed objects so they fit together, as well as how it is going to pick them up and manipulate them using its arm and gripper.

It must do this while determining how to avoid collisions and achieve any user-specified constraints, such as a certain order in which to pack items.

With so many potential sequences of actions, sampling possible solutions at random and trying one at a time could take an extremely long time.

“It is a very large search space, and a lot of actions the robot does in that space don’t actually achieve anything productive,” Garrett adds.

Instead, the researchers’ algorithm, called cuTAMP, which is accelerated using a parallel computing platform called CUDA, simulates and refines thousands of solutions in parallel. It does this by combining two techniques, sampling and optimization.

Sampling involves choosing a solution to try. But rather than sampling solutions randomly, cuTAMP limits the range of potential solutions to those most likely to satisfy the problem’s constraints. This modified sampling procedure allows cuTAMP to broadly explore potential solutions while narrowing down the sampling space.

“Once we combine the outputs of these samples, we get a much better starting point than if we sampled randomly. This ensures we can find solutions more quickly during optimization,” Shen says.

Once cuTAMP has generated that set of samples, it performs a parallelized optimization procedure that computes a cost, which corresponds to how well each sample avoids collisions and satisfies the motion constraints of the robot, as well as any user-defined objectives.

It updates the samples in parallel, chooses the best candidates, and repeats the process until it narrows them down to a successful solution.

Harnessing accelerated computing

The researchers leverage GPUs, specialized processors that are far more powerful for parallel computation and workloads than general-purpose CPUs, to scale up the number of solutions they can sample and optimize simultaneously. This maximized the performance of their algorithm.

“Using GPUs, the computational cost of optimizing one solution is the same as optimizing hundreds or thousands of solutions,” Shen explains.

When they tested their approach on Tetris-like packing challenges in simulation, cuTAMP took only a few seconds to find successful, collision-free plans that might take sequential planning approaches much longer to solve.

And when deployed on a real robotic arm, the algorithm always found a solution in under 30 seconds.

The system works across robots and has been tested on a robotic arm at MIT and a humanoid robot at NVIDIA. Since cuTAMP is not a machine-learning algorithm, it requires no training data, which could enable it to be readily deployed in many situations.

“You can give it a brand-new problem and it will provably solve it,” Garrett says.

The algorithm is generalizable to situations beyond packing, like a robot using tools. A user could incorporate different skill types into the system to expand a robot’s capabilities automatically.

In the future, the researchers want to leverage large language models and vision language models within cuTAMP, enabling a robot to formulate and execute a plan that achieves specific objectives based on voice commands from a user.

This work is supported, in part, by the National Science Foundation (NSF), Air Force Office for Scientific Research, Office of Naval Research, MIT Quest for Intelligence, NVIDIA, and the Robotics and Artificial Intelligence Institute.

Every year during the growing season, thousands of pilots across the country climb into small planes loaded with hundreds of pounds of pesticides and fly extremely close to the ground at upward of 140 miles an hour, unloading their cargo onto rows of corn, cotton, and soybeans.

The world of agricultural aviation is as dangerous as it is vital to America’s farms. Unfortunately, fatal crashes are common. Now Guardian Ag, founded by former MIT Electronics Research Society (MITERS) makers Adam Bercu and Charles Guan ’11, is offering an alternative in the form of a large, purpose-built drone that can autonomously deliver 200-pound payloads across farms. The company’s drones feature an 18-foot spray radius, 80-inch rotors, a custom battery pack, and aerospace-grade materials designed to make crop spraying more safe, efficient, and inexpensive for farmers.

“We’re trying to bring technology to American farms that are hundreds or thousands of acres, where you’re not replacing a human with a hand pump — you’re replacing a John Deere tractor or a helicopter or an airplane,” Bercu says.

“With Guardian, the operator shows up about 30 minutes before they want to spray, they mix the product, path plan the field in our app, and it gives an estimate for how long the job will take,” he says. “With our fast charging, you recharge the aircraft while you fill the tank, and those two operations take about the same amount of time.”

From Battlebots to farmlands

At a young age, Bercu became obsessed with building robots. Growing up in south Florida, he’d attend robotic competitions, build prototypes, and even dumpster dive for particularly hard-to-find components. At one competition, Bercu met Charles Guan, who would go on to major in mechanical engineering at MIT, and the two robot enthusiasts became lifelong friends.

“When Charles came to MIT, he basically convinced me to move to Cambridge,” Bercu says. “He said, ‘You need to come up here. I found more people like us. Hackers!’”

Bercu visited Cambridge, Massachusetts, and indeed fell in love with the region’s makerspaces and hacker culture. He moved soon after, and he and Guan began spending free time at spaces including the Artisans Asylum makerspace in Somerville, Massachusetts; MIT’s International Design Center; and the MIT Electronics Research Society (MITERS) makerspace. Guan held several leadership positions at MITERS, including facilities manager, treasurer, and president.

“MIT offered enormous latitude to its students to be independent and creative, which was reflected in the degree of autonomy they permit student-run organizations like MITERS to have compared to other top-tier schools,” Guan says. “It was a key selling point to me when I was touring mechanical engineering labs as a junior in high school. I was well-known in the department circle for being at MITERS all the time, possibly even more than I spent on classes.”

After Guan graduated, he and Bercu started a hardware consulting business and competed in the robot combat show Battlebots. Guan also began working as a design instructor in MIT’s Department of Mechanical Engineering, where he taught a section of Course 2.007 that tasked students with building go-karts.

Eventually, Guan and Bercu decided to use their experience to start a drone company.

“Over the course of Battlebots and building go-karts, we knew electric batteries were getting really cheap and electric vehicle supply chains were established,” Bercu explains. “People were raising money to build eVTOL [electric vertical take-off and landing] vehicles to transport people, but we knew diesel fuel still outperformed batteries over long distances. Where electric systems did outperform combustion engines was in areas where you needed peak power for short periods of time. Basically, batteries are awesome when you have a short mission.”

That idea made the founders think crop spraying could be a good early application. Bercu’s family runs an aviation business, and he knew pilots who would spray crops as their second jobs.

“It’s one of those high-paying but very dangerous jobs,” Bercu says. “Even in the U.S., we lose between 1 and 2 percent of all agriculture pilots each year to fatal accidents. These people are rolling the dice every time they do this: You’re flying 6 feet off the ground at 140 miles an hour with 800 gallons of pesticide in your tank.”

After cobbling together spare parts from Battlebots and their consulting business, the founders built a 600-pound drone. When they finally got it to fly, they decided the time was right to launch their company, receiving crucial early guidance and their first funding from the MIT-affiliated investment firm the E14 Fund.

The founders spent the next year interviewing crop dusters and farmers. They also started engaging with the Federal Aviation Administration.

“There was no category for anything like this,” Bercu explains. “With the FAA, we not only got through the approval process, we helped them build the process as we went through it, because we wanted to establish some common-sense standards.”

Guardian custom-built its batteries to optimize throughput and utilization rate of its drones. Depending on the farm, Bercu says his machines can unload about 1.5 to 2 tons of payload per hour.

Guardian’s drones can also spray more precisely than planes, reducing the environmental impact of pesticides, which often pollute the landscapes and waterways surrounding farms.

“This thing has the precision to spray the ‘Mona Lisa’ on 20 acres, but we’re not leveraging that functionality today,” Bercu says. “For the operator we want to make it very easy. The goal is to take someone who sprays with a tractor and teach them to spray with a drone in less than a week.”

Scaling for farmers

To date, Guardian Ag has built eight of its aircraft, which are actively delivering payloads over California farms in trials with paying customers. The company is currently ramping up manufacturing in its 60,000-square-foot facility in Massachusetts, and Bercu says Guardian has a backlog of hundreds of millions of dollars-worth of drones.

“Grower demand has been exceptional,” Bercu says. “We don’t need to educate them on the need for this. They see the big drone with the big tank and they’re in.”

Bercu envisions Guardian’s drones helping with a number of other tasks like ship-to-ship logistics, delivering supplies to offshore oil rigs, mining, and other areas where helicopters and small aircraft are currently flown through difficult terrain. But for now, the company is focused on starting with agriculture.

“Agriculture is such an important and foundational aspect of our country,” says Guardian Ag chief operating officer Ashley Ferguson MBA ’19. “We work with multigenerational farming families, and when we talk to them, it’s clear aerial spray has taken hold in the industry. But there’s a large shortage of pilots, especially for agriculture applications. So, it’s clear there’s a big opportunity.”

Seven years since founding Guardian, Bercu remains grateful that MIT’s community opened its doors for him when he moved to Cambridge.

“Without the MIT community, this company wouldn’t be possible,” Bercu says. “I was never able to go to college, but I’d love to one day apply to MIT and do my engineering undergrad or go to the Sloan School of Management. I’ll never forget MIT’s openness to me. It’s a place I hold near and dear to my heart.”

MIT physicists have demonstrated a new form of magnetism that could one day be harnessed to build faster, denser, and less power-hungry “spintronic” memory chips.

The new magnetic state is a mash-up of two main forms of magnetism: the ferromagnetism of everyday fridge magnets and compass needles, and antiferromagnetism, in which materials have magnetic properties at the microscale yet are not macroscopically magnetized.

Now, the MIT team has demonstrated a new form of magnetism, termed “p-wave magnetism.”

Physicists have long observed that electrons of atoms in regular ferromagnets share the same orientation of “spin,” like so many tiny compasses pointing in the same direction. This spin alignment generates a magnetic field, which gives a ferromagnet its inherent magnetism. Electrons belonging to magnetic atoms in an antiferromagnet also have spin, although these spins alternate, with electrons orbiting neighboring atoms aligning their spins antiparallel to each other. Taken together, the equal and opposite spins cancel out, and the antiferromagnet does not exhibit macroscopic magnetization.

The team discovered the new p-wave magnetism in nickel iodide (NiI2), a two-dimensional crystalline material that they synthesized in the lab. Like a ferromagnet, the electrons exhibit a preferred spin orientation, and, like an antiferromagnet, equal populations of opposite spins result in a net cancellation. However, the spins on the nickel atoms exhibit a unique pattern, forming spiral-like configurations within the material that are mirror-images of each other, much like the left hand is the right hand’s mirror image.

What’s more, the researchers found this spiral spin configuration enabled them to carry out “spin switching”: Depending on the direction of spiraling spins in the material, they could apply a small electric field in a related direction to easily flip a left-handed spiral of spins into a right-handed spiral of spins, and vice-versa.

The ability to switch electron spins is at the heart of “spintronics,” which is a proposed alternative to conventional electronics. With this approach, data can be written in the form of an electron’s spin, rather than its electronic charge, potentially allowing orders of magnitude more data to be packed onto a device while using far less power to write and read that data.   

“We showed that this new form of magnetism can be manipulated electrically,” says Qian Song, a research scientist in MIT’s Materials Research Laboratory. “This breakthrough paves the way for a new class of ultrafast, compact, energy-efficient, and nonvolatile magnetic memory devices.”

Song and his colleagues published their results May 28 in the journal Nature. MIT co-authors include Connor Occhialini, Batyr Ilyas, Emre Ergeçen, Nuh Gedik, and Riccardo Comin, along with Rafael Fernandes at the University of Illinois Urbana-Champaign, and collaborators from multiple other institutions.

Connecting the dots

The discovery expands on work by Comin’s group in 2022. At that time, the team probed the magnetic properties of the same material, nickel iodide. At the microscopic level, nickel iodide resembles a triangular lattice of nickel and iodine atoms. Nickel is the material’s main magnetic ingredient, as the electrons on the nickel atoms exhibit spin, while those on iodine atoms do not.

In those experiments, the team observed that the spins of those nickel atoms were arranged in a spiral pattern throughout the material’s lattice, and that this pattern could spiral in two different orientations.

At the time, Comin had no idea that this unique pattern of atomic spins could enable precise switching of spins in surrounding electrons. This possibility was later raised by collaborator Rafael Fernandes, who along with other theorists was intrigued by a recently proposed idea for a new, unconventional, “p-wave” magnet, in which electrons moving along opposite directions in the material would have their spins aligned in opposite directions.

Fernandes and his colleagues recognized that if the spins of atoms in a material form the geometric spiral arrangement that Comin observed in nickel iodide, that would be a realization of a “p-wave” magnet. Then, when an electric field is applied to switch the “handedness” of the spiral, it should also switch the spin alignment of the electrons traveling along the same direction.

In other words, such a p-wave magnet could enable simple and controllable switching of electron spins, in a way that could be harnessed for spintronic applications.

“It was a completely new idea at the time, and we decided to test it experimentally because we realized nickel iodide was a good candidate to show this kind of p-wave magnet effect,” Comin says.

Spin current

For their new study, the team synthesized single-crystal flakes of nickel iodide by first depositing powders of the respective elements on a crystalline substrate, which they placed in a high-temperature furnace. The process causes the elements to settle into layers, each arranged microscopically in a triangular lattice of nickel and iodine atoms.

“What comes out of the oven are samples that are several millimeters wide and thin, like cracker bread,” Comin says. “We then exfoliate the material, peeling off even smaller flakes, each several microns wide, and a few tens of nanometers thin.”

The researchers wanted to know if, indeed, the spiral geometry of the nickel atoms’s spins would force electrons traveling in opposite directions to have opposite spins, like what Fernandes expected a p-wave magnet should exhibit. To observe this, the group applied to each flake a beam of circularly polarized light — light that produces an electric field that rotates in a particular direction, for instance, either clockwise or counterclockwise.

They reasoned that if travelling electrons interacting with the spin spirals have a spin that is aligned in the same direction, then incoming light, polarized in that same direction, should resonate and produce a characteristic signal. Such a signal would confirm that the traveling electrons’ spins align because of the spiral configuration, and furthermore, that the material does in fact exhibit p-wave magnetism.

And indeed, that’s what the group found. In experiments with multiple nickel iodide flakes, the researchers directly observed that the direction of the electron’s spin was correlated to the handedness of the light used to excite those electrons. Such is a telltale signature of p-wave magnetism, here observed for the first time.

Going a step further, they looked to see whether they could switch the spins of the electrons by applying an electric field, or a small amount of voltage, along different directions through the material. They found that when the direction of the electric field was in line with the direction of the spin spiral, the effect switched electrons along the route to spin in the same direction, producing a current of like-spinning electrons.

“With such a current of spin, you can do interesting things at the device level, for instance, you could flip magnetic domains that can be used for control of a magnetic bit,” Comin explains. “These spintronic effects are more efficient than conventional electronics because you’re just moving spins around, rather than moving charges. That means you’re not subject to any dissipation effects that generate heat, which is essentially the reason computers heat up.”

“We just need a small electric field to control this magnetic switching,” Song adds. “P-wave magnets could save five orders of magnitude of energy. Which is huge.”

“We are excited to see these cutting-edge experiments confirm our prediction of p-wave spin polarized states,” says Libor Šmejkal, head of the Max Planck Research Group in Dresden, Germany, who is one of the authors of the theoretical work that proposed the concept of p-wave magnetism but was not involved in the new paper. “The demonstration of electrically switchable p-wave spin polarization also highlights the promising applications of unconventional magnetic states.”

The team observed p-wave magnetism in nickel iodide flakes, only at ultracold temperatures of about 60 kelvins.

“That’s below liquid nitrogen, which is not necessarily practical for applications,” Comin says. “But now that we’ve realized this new state of magnetism, the next frontier is finding a material with these properties, at room temperature. Then we can apply this to a spintronic device.”

This research was supported, in part, by the National Science Foundation, the Department of Energy, and the Air Force Office of Scientific Research.

In the wake of the California State Senate’s passage of S.B. 690, the Electronic Frontier Foundation (EFF), TechEquity, Consumer Federation of California, Tech Oversight California, and ACLU California Action issued a joint statement warning that the bill would put the safety and privacy of millions of Californians at serious risk:

“SB 690 gives the green-light to dystopian big tech surveillance practices which will endanger the privacy and safety of all Californians. SB 690 would allow companies to spy on us to get our sensitive personal information, such as our immigration status or what healthcare we’ve received. And once they have our sensitive personal information, SB 690 places no limits on how that business can use or share that information, allowing them to share it with data brokers, immigration officials, or law enforcement officials in states that restrict reproductive or gender-affirming care.

“At a time where agencies of the federal government are actively targeting individuals based on information collected from businesses about their political beliefs, religious affiliations, or health decisions, we cannot risk sharing even more sensitive information with them. The legislature should be doing all it can to protect Californians, not make it easier for the federal government to secretly obtain our sensitive information.”

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Coalition Floor Alert Opposing SB 690

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“Close your eyes and imagine we are on the same team. Same arena. Same jersey. And the game is on the line,” Jaylen Brown, the 2024 NBA Finals MVP for the Boston Celtics, said to a packed room of about 200 people at the recent Day of Climate event at the MIT Museum.

“Now think about this: We aren’t playing for ourselves; we are playing for the next generation,” Brown added, encouraging attendees to take climate action. 

The inaugural Day of Climate event brought together local learners, educators, community leaders, and the MIT community. Featuring project showcases, panels, and a speaker series, the event sparked hands-on learning and inspired climate action across all ages.

The event marked the celebration of the first year of a larger initiative by the same name. Led by the pK-12 team at MIT Open Learning, Day of Climate has brought together learners and educators by offering free, hands-on curriculum lessons and activities designed to introduce learners to climate change, teach how it shapes their lives, and consider its effects on humanity. 

Cynthia Breazeal, dean of digital learning at MIT Open Learning, notes the breadth of engagement across MIT that made the event, and the larger initiative, possible with contributions from more than 10 different MIT departments, labs, centers, and initiatives. 

“MIT is passionate about K-12 education,” she says. “It was truly inspiring to witness how our entire community came together to demonstrate the power of collaboration and advocacy in driving meaningful change.”

From education to action 

The event kicked off with a showcase, where the Day of Climate grantees and learners invited attendees to learn about their projects and meaningfully engage with lessons and activities. Aranya Karighattam, a local high school senior, adapted the curriculum Urban Heat Islands — developed by Lelia Hampton, a PhD student in electrical engineering and computer science at MIT, and Chris Rabe, program director at the MIT Environmental Solution Initiative — sharing how this phenomenon affects the Boston metropolitan area. 

Karighattam discussed what could be done to shield local communities from urban heat islands. They suggested doubling the tree cover in areas with the lowest quartile tree coverage as one mitigating strategy, but noted that even small steps, like building a garden and raising awareness for this issue, can help.

Day of Climate echoed a consistent call to action, urging attendees to meaningfully engage in both education and action. Brown, who is an MIT Media Lab Director’s Fellow, spoke about how education and collective action will pave the way to tackle big societal challenges. “We need to invest in sustainability communities,” he said. “We need to invest in clean technology, and we need to invest in education that fosters environmental stewardship.”

Part of MIT’s broader sustainability efforts, including The Climate Project, the event reflected a commitment to building a resilient and sustainable future for all. Influenced by the Climate Action Through Education (CATE), Day of Climate panelist Sophie Shen shared how climate education inspired her civic life. “Learning about climate change has inspired me to take action on a wider systemic level,” she said.

Shen, a senior at Arlington High School and local elected official, emphasized how engagement and action looks different for everyone. “There are so many ways to get involved,” she said. “That could be starting a community garden — those can be great community hubs and learning spaces — or it could include advocating to your local or state governments.”

Becoming a catalyst for change 

The larger Day of Climate initiative encourages young people to understand the interdisciplinary nature of climate change and consider how the changing climate impacts many aspects of life. With curriculum available for learners from ages 4 to 18, these free activities range from Climate Change Charades — where learners act out words like “deforestation” and “recycling” — to Climate Change Happens Below Water, where learners use sensors to analyze water quality data like pH and solubility.

Many of the speakers at the event shared personal anecdotes from their childhood about how climate education, both in and out of the classroom, has changed the trajectory of their lives. Addaline Jorroff, deputy climate chief and director of mitigation and community resilience in the Office of Climate Resilience and Innovation for the Commonwealth of Massachusetts, explained how resources from MIT were instrumental in her education as a middle and high schooler, while Jaylen Brown told how his grandmother helped him see the importance of taking care of the planet, through recycling and picking up trash together, when he was young.

Claudia Urrea, director of the pK-12 team at Open Learning and director of Day of Climate, emphasizes how providing opportunities at schools — through new curriculum, classroom resources and mentorship — are crucial, but providing other educational opportunities also matter: in particular, opportunities that support learners in becoming strong leaders.

“I strongly believe that this event not only inspired young learners to take meaningful action, both large and small, towards a better future, but also motivated all the stakeholders to continue to create opportunities for these young learners to emerge as future leaders,” Urrea says.

The team plans to hold the Day of Climate event annually, bringing together young people, educators, and the MIT community. Urrea hopes the event will act as a catalyst for change — for everyone.

“We hope Day of Climate serves as the opportunity for everyone to recognize the interconnectedness of our actions,” Urrea says. “Understanding this larger system is crucial for addressing current and future challenges, ultimately making the world a better place for all.”

The Day of Climate event was hosted by the Day of Climate team in collaboration with MIT Climate Action Through Education (CATE) and Earth Day Boston.

When people think of MIT, they may first think of code, circuits, and cutting-edge science. But the school has a rich history of interweaving art, science, and technology in unexpected and innovative ways — and that’s never been more clear than with the Institute’s latest festival, Artfinity: A Celebration of Creativity and Community at MIT.

After an open-call invitation to the MIT community in early 2024, the inaugural Artfinity delivered an extended multi-week exploration of art and ideas, with more than 80 free performing and visual arts events between Feb. 15 and May 2, including a two-day film festival, interactive augmented reality art installations, an evening at the MIT Museum, a simulated lunar landing, and concerts by both student groups and internationally renowned musicians. 

“Artfinity was a fantastic celebration of MIT’s creative excellence, offering so many different ways to explore our thriving arts culture,” says MIT president Sally Kornbluth. “It was wonderful to see people from our community getting together with family, friends, and neighbors from Cambridge and Boston to experience the joy of music and the arts.”

Among the highlights were a talk by Tony-winning scenic designer Es Devlin, a concert by Grammy-winning rapper and visiting scholar Lupe Fiasco, and a series of events commemorating the opening of the Edward and Joyce Linde Music Building.

Devlin shared art tied to her recent spring residency at MIT as the latest honoree of the Eugene McDermott Award in the Arts. Working with MIT faculty, students, and staff, she inspired a site-specific installation called “Face to Face,” in which more than 100 community members were paired with strangers to draw each other. In recent years, Devlin has focused her work on fostering interpersonal connection, as in her London multimedia exhibition “Congregation,” in which she drew 50 people displaced from their homelands and documented their stories on video.

Fiasco’s May 2 performance centered around a new project inspired by MIT’s public art collection, developed this year in collaboration with students and faculty as part of his work as a visiting scholar and teaching the class “Rap Theory and Practice.” With the backing of MIT’s Festival Jazz Ensemble, Fiasco presented original compositions based on famed campus sculptures such as Alexander Calder’s La Grande Voile [The Big Sail] and Jaume Plensa’s Alchemist, with members of the MIT Rap Ensemble also jumping on board for many of the pieces. Several students in the ensemble also spearheaded complex multi-instrument arrangements of some of Fiasco’s most popular songs, including “The Show Goes On” and “Kick, Push.” 

Artfinity’s programming also encompassed an eclectic mix of concerts commemorating the new Linde Music Building, which features the 390-seat Tull Hall, rehearsal rooms, a recording studio, and a research lab to help support a new music technology graduate program launching this fall. Events included performances of multiple student ensembles, the Boston Symphony Chamber Players, the Boston Chamber Music Society, Sanford Biggers’ group Moonmedicin, and Grammy-winning jazz saxophonist Miguel Zenón, an assistant professor of music at MIT.

“Across campus, from our new concert hall to the Great Dome, in gallery spaces and in classrooms, our community was inspired by the visual and performing arts of the Artfinity festival,” says MIT provost Cynthia Barnhart. “Artfinity has been an incredible celebration and display of the collective creativity and innovative spirit of our community of students, faculty, and staff.” 

A handful of other Artfinity pieces also made use of MIT’s iconic architecture, including Creative Lumens and Media Lab professor Behnaz Farahi’s “Gaze to the Stars.” Taking place March 12–14 and coinciding with the total lunar eclipse, the large-scale video projections illuminated a wide range of campus buildings, transforming the exteriors of the new Linde Music Building, the MIT Chapel, the Stratton Student Center, the Zesiger Sports & Fitness Center, and even the Great Dome, which Farahi’s team affixed with images of eyes from the MIT community.

Other popular events included the MIT Museum’s After Dark series and its Argus Installation, which examined the interplay of light and hand-blown glass. A two-day Bartos Theatre film festival featured works by students, staff, and faculty, ranging from shorts to 30-minute productions, and spanning the genres of fiction, nonfiction, animation, and experimental pieces. The Welcome Center also hosted “All Our Relations,” a multimedia celebration of MIT's Indigenous community through song, dance, and story.

An Institute event, Artfinity was organized by the Office of the Arts, and led by professor of art, culture, and technology Azra Akšamija and Institute Professor of Music Marcus A. Thompson. Both professors spoke about the importance of spotlighting the arts and demonstrating a diverse breadth and depth of programming for future iterations of the event.

“People think of MIT as a place you go to only for technology. But, in reality,  MIT has always attracted students with broad interests and required them to explore balance in their programs with substantive world-class offerings in the humanities, social sciences, and visual and performing arts,” says Thompson. “We are hoping this festival, Artfinity, will showcase the infinite variety and quality we have been offering and actually doing in the arts for quite some time.”

Professor of music and theater art Jay Scheib sees the mix of art and technology as a way for students to explore other ways for them to approach different research challenges. “In the arts, we tend to look at problems in a different way … framed by ideas of aesthetics, civic discourse, and experience,” says Scheib. “This approach can help students in physics, aerospace design, or artificial intelligence to ask different, yet equally useful, questions.”

An Institute-sponsored campus-wide event organized by the Office of the Arts, Artfinity represents MIT’s largest arts festival since its 150th anniversary in 2011. Akšamija, who is director of MIT’s Art, Culture, and Technology (ACT) program, says that the festival serves as both a student spotlight and an opportunity to interact with, and meaningfully give back to, MIT’s surrounding community in Cambridge and greater Boston.

“What became evident during the planning of this festival was the quantity and quality of art here at MIT, and how much of that work is cutting-edge,” says Akšamija. “We wanted to celebrate the creativity and joyfulness of the brilliant minds on campus [and] to bring joy and beauty to MIT and the surrounding community.”

With a dramatic victory in the 4x400m relay, the MIT women's track and field team clinched the 2025 NCAA Division III Outdoor Track and Field National Championship May 24 at the SPIRE Institute's Outdoor Track and Field facility. The title was MIT's first NCAA women's outdoor track and field national championship. The team scored first of 79 with 56 points; runners-up included Washington University with 47 points and the University of Winsconsin at La Crosse with 38 points.

With the victory, MIT completed a sweep of the 2024-25 NCAA Division III women's cross country, indoor track and field, and outdoor track and field titles — becoming the first women's program to sweep all three in the same year.

MIT earned 20 All-America honors across three days, including the program's first relay national championship in the 4x400m on Saturday and Alexis Boykin's eighth career national title with an NCAA record-breaking performance in the shot put on Friday.

On Thursday, Boykin opened the championships with a third-place performance in the discus as MIT quickly moved to the top of the team leaderboard on the first day of competition. Boykin and classmate Emily Ball each earned a spot on the podium. Boykin was third with a throw of 45.12m (148' 0") on her second attempt and Ball was seventh with a mark of 41.90m (137' 5") on her final throw of prelims.

In the pole vault, junior Katelyn Howard tied for fifth, clearing 3.85m (12' 7.5") to pick up three points for MIT. Howard passed on the first height and cleared at both 3.75m and 3.85m, but did not pass the fourth progression. Classmate Hailey Surace was 14th, clearing 3.75m (12' 3.5").

Junior Elaine Wang picked up a big point with an eighth-place finish for MIT in the javelin. Wang's second attempt traveled 40.44m (132' 8"), moving her into sixth place. She would eventually finish in eighth on the strength of her second attempt.  

The opening day concluded with junior Kate Sanderson finishing fourth with a personal best of 34:48.601 in the 10,000m to earn a spot on the podium, as MIT continued to lead the team standings. 

On Friday, Boykin returned on day two and set the NCAA Division III women's shot put all-time record, winning her eighth career national championship with a throw of 16.80m (55’ 1/2”). Boykin won the event by over 2 meters, breaking Robyn Jarocki's NCAA Division III record on her final preliminary attempt with a throw of 16.80m.

MIT wrapped action with the 3,000m Steeplechase final, where sophomore Liv Girand finished in 10th place in 10:58.71 to earn the first All-America honor of her career. MIT continued to lead the team standings at the end of the second day of competition.

On Saturday, Boykin earned her third All-America honor in three events at the championships with a third-place finish in the hammer with a throw of 58.79m (192' 10”), while junior Nony Otu Ugwu took 10th with a jump of 11.91m (39' 1") on her final attempt of prelims. Otu Ugwu did not advance to the final.

MIT shined on the track to secure the title, as grad student Gillian Roeder and senior Christina Crow picked up seven big points in the 1,500m final. Roeder was fifth in 4:27.76 and Crow was one spot back, finishing sixth in 4:28.81.

Senior Marina Miller followed and picked up six more points while earning the first of two All-America honors on the day with a third-place finish and a personal record of 54.32 in the 400m.

Junior Rujuta Sane, Roeder, and junior Kate Sanderson finished 13th, 14th, and 16th, respectively, in the 5,000m. Sane had a time of 16:51.45, with Roeder finishing in 16:54.07 and Sanderson clocking in at 17:00.55.

With MIT leading second-place Washington University by seven points heading into the final event, MIT's 4x4 relay team of senior Olivia Dias, junior Shreya Kalyan, junior Krystal Montgomery, and Miller left no doubt, securing the team championship with a national title of their own, as Miller moved from third to first over the final 50m to win an electric final race.

You can read the details of Operation Spiderweb elsewhere. What interests me are the implications for future warfare:

If the Ukrainians could sneak drones so close to major air bases in a police state such as Russia, what is to prevent the Chinese from doing the same with U.S. air bases? Or the Pakistanis with Indian air bases? Or the North Koreans with South Korean air bases? Militaries that thought they had secured their air bases with electrified fences and guard posts will now have to reckon with the threat from the skies posed by cheap, ubiquitous drones that cFan be easily modified for military use. This will necessitate a massive investment in counter-drone systems. Money spent on conventional manned weapons systems increasingly looks to be as wasted as spending on the cavalry in the 1930s...

The White House proposal would slash funding for the science division from $7.3 billion to $3.9 billion.

Marcia McNutt offered a grim assessment without mentioning the president’s assault on science.

The West Virginia governor said he will urge President Trump to get “the science right.”