In 2026, MIT granted tenure to 10 faculty members across the School of Engineering. This year’s tenured engineers hold appointments in the departments of Aeronautics and Astronautics, Civil and Environmental Engineering, Electrical Engineering and Computer Science (EECS) — which reports jointly to the School of Engineering and MIT Schwarzman College of Computing — and Mechanical Engineering, as well as within the Institute for Medical Engineering and Sciences (IMES).

“I’m delighted to congratulate the 10 newest tenured faculty members in the School of Engineering. This major career milestone reflects not only their impact and excellence in research, but their deep commitment to education and mentoring the next generation of engineers. I am so excited to see what new developments, innovations, and technologies will come next from this incredibly accomplished group,” says Paula T. Hammond ’84, PhD ’93, dean of engineering, Institute Professor, and professor of chemical engineering.

This year’s newly tenured engineering faculty include the following:

Jacob Andreas is an associate professor in EECS and is affiliated with the Computer Science and Artificial Intelligence Laboratory (CSAIL). His work is in natural language processing, and more broadly in AI. He aims to understand the computational foundations of language learning, and to build intelligent systems that can learn from human guidance.

Zachary Cordero is the Esther and Harold E. Edgerton Associate Professor in the Department of Aeronautics and Astronautics and the associate director of the MIT Gas Turbine Laboratory. His research seeks to enable frontier aviation and space platforms through advanced materials, manufacturing, and structures, with a particular focus on high-temperature systems.

Christina Delimitrou is the KDD Career Development Professor in Communications and Technology and an associate professor in EECS. She is also affiliated with CSAIL. Her research sits at the intersection of computer architecture and computer systems; specifically, she is one of the first systems researchers to apply machine learning techniques to design and management problems in the cloud.

Sili Deng is the Doherty Career Development Professor in Ocean Utilization and an associate professor in the Department of Mechanical Engineering. Her group develops scientific machine learning and experimental approaches to understand, predict, and engineer chemically reacting systems for sustainable energy, advanced materials manufacturing, and climate-resilient technologies.

David Des Marais is the Amgen Career Development Professor in the Department of Civil and Environmental Engineering. He leads the Des Marais Lab, whose primary focus of research is to understand the mechanisms of plant-environment interaction, using tools from molecular, quantitative, and population genetics to identify the physiological basis of plant response to environmental cues.

Carmen Guerra-Garcia is the Esther and Harold E. Edgerton Associate Professor in the Department of Aeronautics and Astronautics and the director of the Aerospace Plasma Group. Her work lies at the intersection of aerospace engineering, low-temperature plasma technologies, and gas discharge physics. It addresses two aviation challenges — reducing emissions, and ensuring safety of next-generation aircraft — through three interconnected thrusts: advancing the fundamental science of electrical discharges in flowing gases and nonuniform media, applying that science to plasma-assisted combustion and chemical conversion, and developing physics-based approaches to lightning protection.

Laura Lewis is the Athinoula A. Martinos Associate Professor in EECS and IMES. Her research aims to develop methods to analyze and interpret multi-modal neuroimaging data in order to enable measurement of previously undetectable aspects of brain function. She has a particular interest in fast fMRI, EEG, and PET, and is applying those methods to study sleep.

Tami Lieberman is the Hermann L. F. von Helmholtz Career Development Professor in the Department of Civil and Environmental Engineering and IMES. She leads the Lieberman Lab, which seeks to understand how ecology and evolution shape the personalized communities of the human microbiome, and the role of this personalization on human health.

Kevin O’Brien is an associate professor in EECS and a member of the Research Laboratory of Electronics.  He leads the Quantum Coherent Electronics Group. His research efforts focus on developing tools, techniques, and devices to enhance the measurement of quantum systems, most notably superconducting quantum computers.

Wim van Rees is an associate professor in the Department of Mechanical Engineering and the Leonardo Career Development Professor in Engineering. His research advances high-order, high-fidelity numerical methods for efficiently simulating interactions between fluid flows and moving or deforming bodies, with methodologies spanning applications from wake vortex dynamics to bio-inspired propulsion and morphing structures. 

Researchers around the world are racing to develop new quantum-based systems for sensing, communication, computing, and control that have the promise of outperforming traditional systems. Creating stable, measurable, distinguishable quantum states, which would be the heart of any such system, is a daunting task.

Quantum states possess unique properties that can be exploited for developing novel information processing systems. Two key properties, stability and distinguishability, are hard to achieve, however. Extracting information from a quantum system depends on the distinguishability of quantum states, an intrinsic property associated with a property known as orthogonality. Nevertheless, no two Gaussian states (a widely studied class of quantum states) are orthogonal, and this yields an unavoidable error when attempting to distinguish them. 

In addition, present quantum devices tend to remain stable only for a fraction of a second, and require complex protocols to distinguish states. Now, researchers at MIT and the University of Ferrara have found a new approach for creating easily distinguishable states that could help to enable the development of these new quantum-based devices.

The new approach is described in a paper published today in the journal Physical Review A, by Moe Z. Win and Peter L. Falb at MIT with Andrea Giani and Andrea Conti at the University of Ferrara. The team found a way of translating between quantum states of light and algebraic varieties (a mathematical structure from abstract algebra), making the analysis more manageable by reducing it to solvable mathematical equations.

“Quantum systems can provide performance that is significantly better than classical counterparts,” Win says, “but this doesn’t come for free.” To develop practical devices for producing and detecting different states, “one needs to carefully engineer the quantum states in which they encode information.” 

Traditional computers typically use different voltages in a solid-state device to encode ones and zeros, while optical systems may use the presence or absence of a pulse of light. In quantum devices, the states might have to do with the spin state of a single atom, or the excitation level of a group of electrons.

Win adds that “we have been studying how to design distinguishable quantum states, which translates directly into improved performance for sensing and communication.” In the jargon of the field, they are improving the orthogonality — that is, the distinguishability — of different states.

The particular kinds of states studied in this theoretical analysis had to do with energy levels of photons, or particles of light. Giani explains that they used an operation called photon variation. This can take two forms: photon addition, in which photons are excited to a higher energy state, or photon subtraction, in which photons are annihilated (i.e., removed from the system). These operations change the quantum state from Gaussian to non-Gaussian states; it’s the non-Gaussian states that seem most useful, the team concluded. 

“The domain of non-Gaussian states is quite big,” Giani says, “but among them, we are looking into non-Gaussian states that are easier to implement with current technologies, because if we want to make the transition to the quantum world, we need to take into account realistic experimental challenges.”

Unlike some kinds of cutting-edge technologies being studied for possible quantum applications, Giani explains, “these kinds of photon-varied states have already been produced in the laboratory, and there is much interest in this kind of operation.”

These types of states are relatively new, Conti says, and so “there was a need for a theoretical characterization for these states,” The theoretical characterization this team derived, based on underlying mathematical properties, makes it possible to design states with higher levels of distinguishability. 

With this work, Win says, “we have a theory that gives us a blueprint to go design these non-Gaussian states, rather than just, ‘try this and that, and let’s hope they’re somewhat distinguishable.’ Our theory tells us exactly how to go about designing orthogonal non-Gaussian states.”

The findings result from the connection between the algebraic equations and the underlying physics, Win says, “That was the important connection between different disciplines — bringing algebraic geometry to the table.” 

“The equations to be solved for determining the orthogonality” of the quantum states “happened to be polynomial equations,” Falb says. “It just happened that there was the appropriate mathematics to solve them.”

Now that the principles have been established through this work, implementation should be relatively straightforward, the researchers say. There already are some optical setups that can be used to implement these kinds of states. 

“In principle,” Giani notes, “you can just put the parameters that you find by solving these equations directly into your physical apparatuses and produce these kinds of states. I don’t think this requires some more-advanced technology.” 

Conti adds that “as soon as this paper is published, we hope that experimentalists can try these methods.”

But that’s just the beginning, Win emphasizes. “We are getting momentum, and it’s very exciting,” he says. “The approach that we are taking here is to ask more general questions than just, ‘here’s a particular setup, how do you tune it to get a performance gain?’ Rather, we’re looking at a class of signal design problems, and then finding keys that really unlock these, so that hopefully the answer will not just be applied to only one particular setup, but something significantly broader.”

An international team of researchers has developed a novel fluorescent nanosensor powered by carbon nanotubes that is capable of rapidly detecting an emerging biomarker linked to gut health and disease. 

This important development could eventually lead to faster and more accessible gut-health testing. 

Indole-3-propionic acid (IPA) is a metabolite produced by gut bacteria during the breakdown of dietary tryptophan, an amino acid essential for protein synthesis. It plays an important role in regulating inflammation and oxidative stress, and has been associated with conditions such as inflammatory bowel disease (IBD), Type 2 diabetes, and liver disease. However, current detection methods rely on traditional mass spectrometry-based analytical techniques, which are costly and time-consuming, making it impractical for routine screening or point-of-care use.

The new platform addresses a longstanding gap in gut metabolite sensing. Using a fluorescence-based approach, the sensor produces a rapid optical readout within minutes, offering a significantly faster and more accessible alternative to conventional analytical techniques. It demonstrates high selectivity, distinguishing IPA from closely related metabolites commonly found in the gut, which enables accurate detection even in complex biological environments such as blood serum.

“This is the first time we are able to directly and rapidly measure IPA levels in biological samples using an optical nanosensor,” says co-first author Mervin Ang, assistant professor at the National Institute of Education (NIE) within Nanyang Technological University in Singapore, who was also associate scientific director at the Disruptive and Sustainable Technologies for Agricultural Precision (DiSTAP) interdisciplinary research group within the Singapore-MIT Alliance for Research and Technology (SMART) when the research was initiated. “This novel approach, which moves away from traditional mass spectrometry, can pave the way towards faster and more accessible ways of monitoring gut health in real-world settings.”

This latest breakthrough is described in the research team’s open-access paper, “Fluorescent Nanosensor for Indole-3-Propionic Acid Detection in Gut Health Monitoring,” in the journal Advanced Healthcare Materials. The work was led by researchers at NIE, MIT, and SMART, in collaboration with clinicians from the National University Hospital (NUH) and Yong Loo Lin School of Medicine within the National University of Singapore (NUS Medicine). 

From monitoring plants to sensing human health

The new nanosensor builds on SMART DiSTAP’s research into nano and optical sensor technologies. Originally developed to monitor plant health — including plant growth signals and stress responses —  the technology has now been adapted for human health applications by redesigning the nano- and optical-sensing platform to detect IPA.

“This work builds on technology at SMART DiSTAP on molecular recognition. We have used techniques like this to measure hormones and metabolites in living plants for agriculture, and have now applied it to the human gastrointestinal system. We were able to apply it to this long-standing challenge in gut health,” says Michael Strano, SMART DiSTAP lead principal investigator, the Carbon P. Dubbs Professor of Chemical Engineering at MIT, and corresponding author. 

“By focusing our molecular recognition on this important gut health biomarker, we’ve demonstrated a powerful new tool that could one day enable proactive, personalized health care. The tool promises near-instant insights into gut wellness, or the status of chronic diseases like IBD.”

A dual-mode platform for rapid testing and future monitoring

A key innovation of the technology is its dual-mode sensing capability. 

The nanosensor operates in both a visible fluorescence mode, enabling rapid, low-cost, high-throughput screening of biological samples; and a near-infrared mode, with wavelengths that can penetrate deeper into tissues. The near-infrared capability, enabled by carbon nanotubes, allows the technology to be adapted for in vivo applications and integration into wearable devices that could be used for home-based testing or continuous monitoring. This could, for example, help patients with chronic conditions like IBD detect flare-ups earlier and manage their health with greater autonomy. 

This flexibility allows the platform to be utilized in various environments, from laboratory tests to hospital bedside use, and wearable devices for real-time health monitoring. 

Validated in patient samples

To evaluate its clinical relevance, the research team collaborated with NUH clinicians to test the nanosensor on 125 human plasma samples across multiple patient groups, including healthy individuals and those with gastrointestinal diseases.

The study revealed significant differences in IPA levels between healthy individuals and patients with inflammatory bowel diseases, including Crohn’s disease and ulcerative colitis. Patients with active gut inflammation showed lower IPA levels — consistent with established clinical findings.

“From a clinical perspective, having a rapid and minimally complex way to assess metabolite levels like IPA could be very valuable,” says Jonathan Lee, senior consultant in the Division of Gastroenterology and Hepatology within the Department of Medicine at NUH; adjunct associate professor at NUS Medicine; and co-first author of the work. “It has the potential to complement existing diagnostic tools and provide additional insights into patients with inflammatory bowel diseases.”

Faster, more accessible gut health testing

Beyond the laboratory, this research could pave the way for faster and more accessible gut health testing. Instead of relying on complex and time-intensive laboratory methods, the new nanosensor could enable rapid screening in clinics, or even portable or home-based testing, helping to detect gut diseases earlier and monitor treatment progress more easily.

Unlike conventional microbiome tests that focus on identifying which bacteria are present, this nanosensor measures what those microbes are actively producing, offering a more direct and functional snapshot of gut health. Directly measuring metabolite output, rather than bacterial composition alone, could provide more meaningful insights into overall health and support more personalized approaches to health care. 

Beyond clinical diagnostics, the technology can be used to track the immediate efficacy of dietary interventions. Users can see rapidly if specific foods or probiotics are successfully fueling their gut bacteria to produce anti-inflammatory molecules like IPA. The sensor also demonstrated reliable performance in complex biological fluids such as serum and plasma, an important step toward real-world clinical deployment and further translational applications. 

For pharmaceutical and therapeutic research, the nanosensor could be used to conduct rapid functional tests to determine the efficacy of new therapeutics or probiotics. By providing an instant readout of IPA levels, the platform could enable them to demonstrate in real time that their therapeutics are biologically active and effective, significantly accelerating drug screening and dosage optimization processes.

Toward point-of-care diagnostics, and beyond

“The transition from laboratory discovery to a point-of-care clinical tool is already underway,” says Ang. “With further development, the platform has the potential to be translated into clinical applications, and in the long term, adapted into portable platforms for routine health monitoring.”

Looking ahead, the research team has been awarded an Innovation to Startup Innovation Grant to incubate a Singapore proto-startup to advance validation and development. The focus would be to translate the sensor into a point-of-care clinical diagnostic tool, and aim to expand the platform to detect multiple gut metabolites simultaneously and AI-driven signal deconvolution, enabling more accurate, comprehensive and personalized gut health monitoring. 

Future developments may also explore integration into wearable devices, microneedle systems, or microfluidic platforms for continuous, real-time sensing.

The research was supported by the Intra-CREATE Seed Collaboration Grant, and research conducted at SMART was supported by the National Research Foundation Singapore under its Campus for Research Excellence and Technological Enterprise (CREATE) program.

A proposed FCC rule would kill burner phones: phones whose accounts are not attached to a particular person.

The FCC plans to do this by legally forcing the country’s telecoms to store a wealth of personal information about essentially all phone customers, including a government issued identification number and their physical address, alarming privacy advocates and civil rights activists who compare the measures to those from authoritarian countries where it can be difficult to buy a mobile phone plan without giving up your identity.

The proposed change would drastically shake up how people obtain phone plans in the U.S., and have all sorts of privacy and cybersecurity knock-on effects. The FCC is proposing the data collection partly as a way to combat scammers, with telecoms being required to collect other information on business and foreign customers like the intended use case of their bulk phone plan purchase and their IP address. But the changes would mean telecoms collect data on all new and renewing customers, and the FCC provides a long list of other things that the collected data could help authorities with...

Some allies of the president say the administration is sending mixed signals on EPA’s bid to dismantle greenhouse gas regulation.

Regulators questioned Xcel's push for new gas infrastructure while also paying for electrification.

Cyprus tabled amendments to the Carbon Border Adjustment Mechanism at a meeting of EU finance ministers at the European Council.

The U.K. government promised a “revolution” to clean the skies of harmful emissions. Now some of Labour’s own members of Parliament are fed up with the costs and delays.

"Indirect greenhouse gases," together with heat-absorbing black carbon, are responsible for about 15 percent of global warming to date, according to an analysis.

The process could kick off as soon as the end of this year, with a sale likely to take place in 2027, officials said.

In a hospital or at home, temperatures are usually taken using an oral or forehead thermometer, but these do not always accurately reflect the core body temperature. Measuring core temperature from within the body could make it easier to determine whether someone is sick, and whether they’re at risk of spiking a dangerous fever.

To make it more feasible to obtain core body temperature measurements, MIT engineers have developed an ingestible sensor that can send continuous temperature updates from the GI tract. 

The sensor is shaped like a tiny blueberry, 6 millimeters in diameter and 4 millimeters in height. That makes it much smaller than existing ingestible temperature sensors, which are more difficult to swallow and pose a potential risk of obstructing the GI tract.

“A sensor like this gives us the ability to monitor infections and identify them early,” says Giovanni Traverso, an associate professor of mechanical engineering at MIT, a gastroenterologist at Brigham and Women’s Hospital, and an associate member of the Broad Institute of MIT and Harvard. “That’s very relevant, particularly for at-risk populations like people who are immunosuppressed from chemotherapy treatments or immunosuppressive drugs.”

Ingestible sensors could also enable more accurate temperature measurements for fertility tracking, and for monitoring people during anesthesia.

Traverso and Anantha Chandrakasan, MIT’s provost and the Vannevar Bush Professor of Electrical Engineering and Computer Science, are the senior authors of the new study. MIT postdoc Saransh Sharma is the lead author of the paper, which appears today in Nature Electronics.

Ingestible electronics

A handful of ingestible temperature sensors have become commercially available in recent years, but most are the size of a multivitamin or slightly larger, making them more challenging to swallow. Their size can also increase the risk of obstructing the GI tract.

Those capsules tend to be large due to the complex circuits they include, which require a great deal of power. That power is provided by relatively large, on-board batteries that make up much of the bulk of the capsule.

The MIT team wanted to design sensors that could measure temperature accurately, but at a much smaller size.

“The reason for them to be small is safety,” Traverso says. “We want something that is so small that the risk of any blockage or obstruction is highly mitigated, and also so that it can be easily ingested.”

To create a smaller device, the researchers set out to reduce the size of all of the main components — the temperature-sensing circuit, the antenna that relays temperature data, and the battery.

For the circuit, they created their own customized circuit that can fit onto a 1-square-millimeter silicon chip. To reduce the chip’s power consumption, the researchers designed an oscillator based on leakage current — the small current that flows through a circuit when it’s off. The frequency of this current varies depending on the temperature of the chip’s surroundings.

This circuit, which can detect temperature with an accuracy of 0.01 degrees Celsius, requires very little power — about 10 nanowatts. This means that it can be powered with a 1.55-volt coin cell battery, which is 4.8 millimeters in diameter and about 1.6 millimeter thick.

The new design further cuts energy consumption by using a communication strategy known as backscattering. This approach allows most of the power requirements to be outsourced to an external antenna that is located outside the body, within a foot or two of the sensor. The external antenna emits an ultra-high-frequency radio wave, which is then modulated by a tiny antenna within the sensor and sent back to the external antenna. By interpreting the changes in the radio wave, the external antenna can calculate the temperature value.

“We combined all of these different pieces together — the silicon chip, the battery, and the antenna — and we made it into an ingestible capsule, which is the smallest ingestible capsule that we have seen for temperature-sensing paradigms,” Sharma says. 

The internal antenna sends out a temperature reading once every second, allowing for continuous monitoring of temperature.

Tiny thermometers

The researchers envision that this kind of sensor could be useful in several scenarios, including monitoring infection and observing patients during and after anesthesia. Anesthesia often disrupts the body’s normal temperature regulation mechanisms, which can put patients at risk of hypothermia.

This type of device could also be used at home, for monitoring fevers in children, or measuring core body temperature as a marker of ovulation, for fertility purposes. It could also be useful for monitoring athletes, soldiers, or anyone else who might be exposed to extreme temperatures. 

To explore these possible uses, the researchers tested the sensors in animals while they were under anesthesia, and found that they could accurately detect and transmit temperature information. They also obtained accurate readings from animals that were awake and actively moving.

The researchers are now working on combining the temperature sensor with other sensors that could measure vital signs such as heart rate. They hope to begin testing these types of sensors in clinical trials within the next few years. 

If proven effective for people in high-risk situations, Traverso believes such sensors could become widely used by anyone who needs to monitor their temperature. 

“I think this could replace all thermometers, because it’s the most accurate way of taking temperature,” he says. “If we have miniature systems that can be easily swallowed and give very accurate data that’s superior to the current data, I think it can be helpful in so many ways.”

Other authors of the paper include Yubin Cai, Injoo Moon, Zhenming Yang, Peter Chai, Niora Fabian, Kailyn Schmidt, Alison Hayward, Andrew Pettinari, Maria Platero, Benedict Laidlaw, and Ashley Guevara.

The research was funded by the 711th Human Performance Wing, the Defense Advanced Research Projects Agency (DARPA), and the Advanced Research Projects Agency for Health (ARPA-H), which notes that the views and conclusions contained in this article are those of the authors and should not be interpreted as representing the official policies, either expressed or implied, of the United States government.

This is a current list of where and when I am scheduled to speak:

• I’m giving a keynote at Cybernation 2026 in Berlin, Germany, on June 24, 2026.
• I’m speaking at the Potsdam Conference on National Cybersecurity at the Hasso Plattner Institut in Potsdam, Germany. The event runs June 24–25, 2026, and my talk will be the evening of June 24.
• I’m participating in a panel discussion at the Austrian Institute for International Affairs in Vienna on Thursday, June 25, 2026.
• I’m speaking at the Digital Humanism Conference in Vienna, Austria, on Friday, June 26, 2026...

Section 702 of the Foreign Intelligence Surveillance Act lets US intelligence agencies collect communications from foreigners abroad without a warrant, and routinely sweeps in Americans’ emails, messages, and calls in the process.

The authority for this program is set to expire Friday, June 12th, 2026, at midnight. As we wrote earlier this week, Congress has been kicking the ball down the road for months now—temporarily postponing the expiration of the mass surveillance authority Section 702 of FISA in hopes that some consensus on a longer reauthorization could be reached. 

EFF has said for decades, every time this program is up for renewal: Section 702 should require a warrant before the Federal Bureau of Investigation can look at digital communications collected from Americans. If not, we should let the whole thing expire. And this time, it has, at least for a little while. 

Ironically, we have Bill Pulte to thank for this (probably temporary) reprieve. Earlier this month, Trump on Tuesday named Pulte – currently director of the Federal Housing Finance Agency (FHFA) and chairman of Fannie Mae and Freddie Mac – to replace current DNI Tulsi Gabbard, who announced her resignation last month. As has been widely reported, Pulte lacks any intelligence, military, or congressional experience. Senate Democrats responded by refusing to move forward with their version of a bill to reauthorize Section 702. Similarly, the House refused to approve even a short-term renewal of the program. 

However, the potential for abuse of this program is not limited to one individual or one administration. And if Congress is this concerned about one particular individual having access to Americans’ most sensitive information, the responsible thing to do is to put more transparency, accountability, and oversight into the structure of this program. 

Members on both sides of the aisle understand this. As we have seen several times this year already, the appetite for reform is stronger than ever. We hope to continue to see strong bipartisan opposition in Congress to renewing Section 702 without a warrant requirement for backdoor searches. Until then, the authority for this program should remain expired. 

This fluid pump was inspired by the way squids propel themselves through the water.

As usual, you can also use this squid post to talk about the security stories in the news that I haven’t covered.

Blog moderation policy.

MIT leadership has in the strongest terms rejected antisemitism and taken thoughtful and steadfast action to prevent it, to promote student-wellbeing, to respond to complaints raised by community members, and to address policy violations. 

Examples of actions MIT has taken since 2023 to address concerns of antisemitism

• MIT President Sally Kornbluth and other senior leaders have sent multiple campus-wide letters and video messages condemning reports of antisemitism on campus. 
• Prior to October 7, MIT joined the Hillel Campus Climate Initiative, which helps universities build awareness of and take action against antisemitism. Learnings from that engagement continue to guide MIT’s campus response. 
• MIT increased security around campus, including at the Office of Religious, Spiritual, and Ethical Life building, which houses MIT Hillel.
• MIT participated in the Brandeis Leadership Symposium on Antisemitism in Higher Education.
• MIT created multiple opportunities for training, education, and dialogue, e.g.: 
  • American Jewish Committee training on antisemitism for Academic Council, which comprises the Institute’s senior leadership 
  • ADL training on antisemitism for MIT’s Bias Response Team 
  • Institute-level educational programming, including an event featuring Professor Pamela Nadell—director of the Jewish Studies Program at American University and a scholar of antisemitism in America
• The Institute updated, publicized, and enforced its policies on protests and demonstrations and posters/displays.
• MIT helped create and provided financial support for two years of weekly lunches focused on supporting MIT’s Jewish community.
• MIT provided support for the faculty-created MIT-Kalaniyot program, which brings Israel-based faculty and postdocs to MIT with the intent of building and strengthening ties between Israeli researchers and the MIT community.
• The Institute established a cross-functional team with representatives from the Institute Discrimination and Harassment Response Office (IDHR), Office of Student Conduct and Community Standards (OSCCS), Division of Student Life, Human Resources, and the Office of General Counsel to promptly and fairly triage reports of antisemitism and other forms of bias relating to the conflict in the Middle East. 
• Instituted disciplinary proceedings for policy violations stemming from campus protests and related activities, which resulted in significant sanctions for a number of students, including suspensions, expulsions, and numerous individual bans from being on campus, as well as permanent derecognition of a student organization. 
• And MIT established a Title VI coordinator.

Student discipline process improvements

Apart from individual student discipline cases as described above, MIT conducted a holistic review of its student discipline process, which resulted in a number of policy and procedure changes, including: 

• The senior administration has a more direct role in reviewing significant student discipline cases, with the Vice Chancellor for Student Life regularly conferring with the Chair of the Committee on Discipline (COD) and participating in hearing panels in serious cases. 
• The role of the Senior Associate Dean of Student Conduct and Community Standards has been enhanced and elevated, reporting directly to the Vice Chancellor for Student Life. 
• A more streamlined process allows the Chair of the COD to take action in response to noncompliance with previous COD sanctions.
• Additional sanctions were added to the COD Rules, giving the COD a broader range of tools to address student misconduct.
• Enhanced training on discriminatory harassment were made available to COD members. 

Over the last couple years, MIT has experienced a significant decline in the number of reports of student misconduct arising out of allegations of antisemitism or other forms of bias based on religion or ethnic/national origin. 

Courts have dismissed lawsuits claiming antisemitism at MIT

As a result of MIT’s actions, including specifically some of those described above, federal courts have dismissed claims of antisemitic harassment and discrimination asserted against MIT under Title VI. In doing so, the courts have acknowledged the escalating steps MIT has taken to promote a safe, inclusive community for its Jewish community members. For example, in a unanimous decision by the First Circuit Court of Appeals holding that MIT satisfied its Title VI obligations, the Court noted:   

• “As the protest gatherings occurred over the course of seven months, culminating in the Kresge Lawn encampment, MIT took an escalating series of actions aimed at calming the turmoil without violence… Even if we accept plaintiffs' position that some conduct of some protestors was antisemitic, that would not provide a Title VI pretext for requiring MIT to eliminate the protests entirely. In that respect, by managing the situation so as to avoid escalation and violence, MIT was much more effective than plaintiffs claim.” 
• “[A]ny reasonable school administrator in MIT's position could have reasonably surmised that its progressively evolving responses prevented the on-campus conflict from exploding into real violence between October 2023 and May 2024.”

Importantly, MIT took these steps to protect the MIT community even while the Court concluded that much of the campus protest activity at MIT amounted to legally protected expression and not a violation of Title VI: 

• “This absence of consensus reflects ongoing debate as to the relationship between anti-Zionism and antisemitism – debate that our constitutional scheme resolves through discourse, not judicial fiat. Indeed, the debate on occasion has been formal and high profile…We decline to interpret Title VI as arming either side of that debate with the powers of a censor.”

2026 Quality of Life survey results

Jewish student sentiment has significantly improved and is now higher than the general MIT student population. 

Below are data from the spring 2026 Quality of Life survey, a community-wide survey administered every two years to better understand the lives of faculty, staff, postdoctoral scholars, and students. The data reflect responses from those who selected “Judaism” as their religion, alone or in part (respondents were able to select more than one religion).

Overall, how satisfied are you being a student at MIT? 
(Percentages are a sum of respondents who selected “very satisfied” + “somewhat satisfied”)

Jewish Undergraduates:
2024: 87%
2026: 97% (compared to 86% for all undergraduate students) 

Jewish Graduate Students:
2024: 78%
2026: 94% (compared to 88% for all graduate students)

I feel that I belong at MIT. 
(Percentages are a sum of respondents who selected “strongly agree” or “somewhat agree”)

Jewish Undergraduates
2024: 83%
2026: 92% (compared to 80% for all undergraduate students)

Jewish Graduate Students 
2024: 70%
2026: 79% (compared to 79% for all graduate students)

Notably, not a single Jewish undergraduate respondent in 2026 disagreed with the statement “I feel that I belong at MIT.”

In winter 1997, at age 60, when many researchers might be looking forward to retirement, Harriet Latham Robinson SM ’61, PhD ’65 was pursuing a faculty position as the chief of microbiology and immunology at the Yerkes National Primate Research Center at Emory University in Atlanta, Georgia. 

She got the job. 

There, she would also co-found GeoVax, a biotechnology company, based on her preclinical research, including work on developing an HIV-1 vaccine. 

Often, as the only woman in a room throughout much of her career, and in the still-developing and male-dominated field of molecular biology, her colleagues were referred to as “doctor” or “professor” at scientific symposia and committee meetings. 

“In contrast,” she recalls, “I was Harriet.”

Becoming a scientist

Robinson was born in 1938, the second of four children, to a mother, Ruth, and a father, Allen, from Ohio and Connecticut, respectively. After finishing grammar school, she attended the Girls’ Latin School, a public magnet school for college-bound young women. Although the school offered only two classes in science — one semester of chemistry and a health class — Robinson credits her time there for inspiring a lifelong love of learning, especially history and languages. 

“At our 50th and 60th high school reunions, I was struck by what my Girls’ Latin school classmates had done with their lives,” she says. “We had become not only wives, mothers, teachers, and nurses we were supposed to become, but also physicians, lawyers, professors, politicians, and businesswomen.” 

Robinson pursued her undergraduate studies at Swarthmore College, where she intended to study political science. After an introductory biology course, however, she switched her major. Despite the shift, a love of languages persisted: Robinson took Russian and, the summer after her senior year of college, served as a Russian-English speaking guide at the 1959 American National Exhibition in Moscow. Despite mounting tensions between the United States and the Soviet Union, she served again in a similar role from September 1961 to January 1962 for a traveling transportation exhibition in Russia and Ukraine, where she was stationed by a Ford Thunderbird, wearing a TWA stewardess uniform.

“We were true entertainment, as well as education, and I worked to do my best to answer questions about America,” she says. “I was most surprised by the pride the Russian people took in the post-World War II accomplishments of their country.” 

Robinson might not have had a career in science at all had it not been for a dean at Radcliffe College who recognized Robinson’s interest in science. Robinson had thought it appropriate, as a young lady, to pursue marriage and to only further her education to become a teacher or nurse. Seeking permission to take chemistry instead of education courses to fulfill requirements for getting a teaching degree, she was referred to a dean who considered it perfectly appropriate for a young woman to pursue another career. Robinson recalls that the dean declared, “My dear, you want to be a scientist.” 

The foundation for a career

Robinson was soon accepted at MIT and was offered a fellowship to teach in an introductory biology lab to help pay her way. She returned from Moscow just five days before the start of a master’s program in biochemistry. In the Department of Biology at MIT, there were only a handful of women, no female faculty, and few ladies’ rooms in 1959. 

It was there that she met Walter “Wally” J.K. Tannenberg, a onetime partner but lifelong friend and companion, an MD taking courses at MIT. He wasn’t “at all taken aback by my becoming an educated woman,” Robinson says. He taught her to ski, and they sailed his lightening, the Ondine, in circles around Robinson’s parents’ comparatively slow motor sailor, the Palometa. 

Their breakup just before the winter holidays in 1963 precipitated her reentry to graduate school, to pursue her thesis work in the lab of Jim Darnell; she threw herself into studies to sit a qualifying exam less than a month after reentry. 

“A Bell Labs physicist who had just joined the Darnell Lab opined that any concept in biology could be mastered in two weeks,” Robinson says. “Much to everyone’s amazement, I not only passed my qualifying exam, but did much better than expected.”

It was at the University of California at Berkeley during her postdoctoral work that she met her husband. Although the marriage would not last the test of time, Robinson and her husband were blessed with three boys, each 13 months apart.

Robinson knew that she wanted to take time away from her career to stay home with her children before they entered primary school. As a graduate student at MIT, to prepare for both having a career and pursuing motherhood, Robinson hired a housekeeper and committed to being in the lab for only a typical 9 a.m. to 5 p.m. workday. If she were to compete with her male counterparts and be with her children, she needed to be able to get things done while working short hours. 

Robinson successfully completed her thesis work in just over two years.

“The difference between bearing children and rising up professional ladders is that you can start up the professional ladder after you are 40,” she advises. “Such is more problematic for having children.”

Robinson’s thesis work at MIT concerned how DNA, which is identical in all cells of an organism, produces different cell types from the same genetic blueprint. She explored this question through the lens of messenger RNA, a gene product that determines which DNA sequences are expressed in a cell. Later, her work on cancer-causing viruses in chickens would help lay the groundwork for gaining insight into genes that can cause tumors to form. 

“In contrast to becoming a wife, becoming a PhD from MIT did not falter, but rather provided me with the foundations for a career I loved in which I used molecular biology and chickens to study the genetic basis of cancer and pioneered the use of DNA as a new method of vaccination,” Robinson says.

Cancer-causing viruses

Robinson, supported by an National Science Foundation fellowship, pursued postdoc training at the University of California at Berkeley, in the lab of Harry Rubin. The Rubin Lab specialized in work on a virus known to cause cancer: the Rous sarcoma virus, which causes rapid tumor onset when introduced into chickens. RNA, it had recently been discovered, was the underlying genetic cause of tumors developing in chickens exposed to the Rous sarcoma virus. It cannot, however, do this deadly work without co-infection with something called a helper virus — in this case, avian leukosis virus. 

Both Rous sarcoma virus and its helper viruses were retroviruses, which can make DNA copies from RNA sequences, a departure from the previously accepted dogma that DNA is only transcribed into RNA, and not the other way around.

Robinson joined the Worcester Foundation for Biomedical Research in 1977, where she continued research on Rous helper viruses and had the opportunity to run her own lab for the first time. In 1998, she was recruited to be a professor of pathology at the University of Massachusetts Medical Center. While there, she conducted pioneering studies on the use of DNA for vaccination and worked on developing an AIDS vaccine. 

In 1999, she moved again, this time to step into the role of chief of microbiology and immunology at the Yerkes National Primate Research Center at Emory University, where she began testing her candidate HIV vaccines in primates. While at the University of Massachusetts and Emory, Robinson and her lab used DNA vaccines, both with and without a poxvirus booster vaccine provided by Bernie Moss at the National Institutes of Health, to immunize animals against influenza, HIV, measles, and Ebola.

“From the early days of DNA vaccines, I had wanted to start a company to help move DNA vaccines from bench to bedside,” she says. 

Thus, GeoVax, short for “Georgia Vaccines,” was born. Robinson co-founded it with Don Hildebrand in 2001 after her move to Yerkes; Robinson would serve as chief scientific officer and a member of the board of directors during her tenure at the company. 

GeoVax successfully moved Robinson’s candidate AIDS vaccine into human clinical trials. These trials were stopped due to the generally poor performance of HIV vaccines in clinical trials, compared to the outstanding therapeutic potential of more recently developed anti-HIV drugs. GeoVax, however, continues to work on vaccines for Mpox, Covid-19, and Ebola, and has expanded its scope to include a cancer treatment.  

A well-deserved retirement 

After rounds of good-natured roasting from colleagues at Emory University and GeoVax, Robinson retired and has been enjoying returning to Palo Alto, California, where her oldest son, Bill, and his wife now live. 

Ultimately, Robinson hopes that her story can encourage everyone, especially young women, not to let pursuing a challenging and enriching career prevent them from realizing the dream of having a family.

“I have had a wonderful life, far exceeding what I ever could have anticipated,” Robinson says. “I have had international adventure, the romance of a man who truly loved me, the joy of motherhood, and the warmth, wonder, and adventure of family and friends, and last, but not least, the exhilaration of a career in molecular biology.”

Let no one accuse Bernie Sanders of ducking the big questions. Writing in the New York Times last week, the senator asked: “Will the future of humanity be determined by a handful of billionaires who have promoted and developed AI, with virtually no democratic input, who stand to become even richer and more powerful than they are today?”

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