Our new dean, @nanonoodle, welcomes you to the start of the new academic year! In this video, he talks about his vision to prepare the next generation of engineers to create knowledge, invent technologies, drive economic growth, & change the world for the better. Thx @AimyWissa

Government investment in curiosity-driven academic research is the bedrock of technological transformation, argues @margmartonosi & her collaborators in this new opinion piece in @CACMmag. Read the piece here:

Some supercool demonstrations from the next generation of leaders in technology and innovation.

ODBI's Tina Kim has been named one of @_TheTransmitter's 2025 Rising Stars of Neuroscience, recognizing her early career contributions and dedication to mentoring and community building. Read: https://t.co/u18ZM8F7Oz

New work in @Nature from @benjraphael, in collab with Josh Rabinowitz's lab. Raphael's lab developed an algorithm that maps cell tissue in 3D by tracking gene expression. The team @princetonchem used this to capture an organ's spatial metabolic organization. Learn more 👇

Nan Yao's work has advanced a broad set of topics, including the visualization of electron orbital signatures within individual atoms, early advances in transmission electron microscopy and helium-ion microscopy. @PrincetonMSE ⬇️

Princeton researchers have developed a diamond-based quantum sensor that reveals rich new information about magnetic phenomena at a super-small scale. The senior author on the study was Nathalie de Leon of Princeton ECE. ⬇️ https://t.co/9LyM7NNvZ6

Welcome @vdean314, a teaching faculty member in @PrincetonCS, bringing expertise in machine learning and robotics. This semester, Dean is co-teaching "Introduction to Machine Learning" with Adji Bousso Dieng and @ruthcfong. Read more: https://t.co/tfPfxt0WSI

Happy Thanksgiving from your friends at Princeton Engineering! If you're looking for something to listen to in the car today, check out one of our podcasts, including "Composers & Computers" about @eprinceton's pioneering role in digital music:

On this #ThanksgivingDay, we are thankful for the bounty of good things in our lives made possible by the longstanding collaboration between the federal government and American universities. @eprinceton & federal agencies have enjoyed a robust partnership: https://t.co/feeGxglT2i

The deadline to apply to the Princeton Bioengineering doctoral program for fall 2026 is Dec. 1. See link below.

In addressing families of @eprinceton students on Friday, Nov. 7, Dean @nanonoodle spoke of #QuantumScience, the mysterious reality that underlies the physical world. He talked about its promise as well as the challenge of turning it into technology. 👇 https://t.co/0NTWvAY2de

Apply to become a @PrincetonGrad student at @omenndarlingbio! Follow this link:

A Princeton and @UChicago study finds that rainfall causes more than 8% of deaths in Mumbai during the monsoon season - a figure ten times higher than listed in official statistics: https://t.co/hx85WayfI5

Robert Prud'homme was honored with the John Scott Award for leading the development of a technique that allows pharmaceutical makers to encapsulate a drug particle in tiny sphere of fat and other materials. Read more👇

Since then, tens of thousands of patents have been filed worldwide related to nanoimprint. Cheers to 30 years of nanoimprint!🥳 (8/8)

Several companies have developed nanoimprint tools for making semiconductor circuits and AI chips, where nanoscale alignment is especially demanding. In 2003, @techreview named nanoimprint one of “10 Emerging Technologies That Will Change the World." (7/8)

It is used to manufacture new products including AR/VR goggles, smart glasses, smartphone components, gene-sequencing chips, flexible electronics, biosensors and more (6/8)

Meanwhile, several companies have developed nanoimprint tools for making semiconductor circuits and AI chips, where nanoscale alignment is especially demanding. Today, NIL has grown into a multi-billion-dollar global industry (5/8)

Chou invented a radically new approach: w/o using lasers or high-energy beams, the method mechanically imprints nanoscale patterns directly into a material. The technique is low-cost, energyefficient & scalable, & can produce smaller, denser, & more complex 3D structures (4/8)

Smaller dimensions also push devices into new regimes where conventional theories no longer apply, giving rise to new properties and capabilities. Traditional means of manufacturing these nanostructures rely on lasers or high-energy beams, which are costly & power-intensive (3/8)