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Our research impacts society
Needles are often used in surgery, because they cause the patient
minimum pain and tissue damage. By developing smart, fl exible and
controllable needles, we’re taking this minimally invasive surgery to the next level, for reasons like the fact that these needles can access parts
of the body that are diffi cult to reach. In the coming years, we hope to
continue developing these needles and to tailor them to a number of select, high-impact medical applications. I DR SARTHAK MSRA NICAL ENGINEERING F BIOMECHAOFESSOR IN THE DEPARTMENT OPR OBOTICS LABORATORYF TH RGICAL RAND DIRECTOR O E SU
LEARN FROM LEADING SCIENTISTS
OUR RESEARCH IMPACTS SOCIETY
Studying at UT means studying at a young and entrepreneurial research university, where scientists, lecturers and students engage in tackling the global societal challenges of today and tomorrow. We’re involved in giving direction to the digitalisation of society, in making technology in the healthcare sector better and more personal, in developing and using smart materials and smart industries, and in making our rapidly changing world more resilient.
For a long time, technology has mainly focused on the basic form of speech recognition: on whát a person says. However, I feel automatic speech recognition is ready for the next level. For me, the interesting part is the layer beyond words, the emotions or mental
state of a speaker. Are both speakers on the same page? What is the meaning of a certain
laugh? That’s important information because in communication it’s all about nuance.
About silences, a sigh, or a laugh of a person. My ultimate goal is to have a normal conversation with a machine. As if talking to a human being.
N DR KHIET TRUO G
IA INTERACTIONDOR HUMAN MEASSISTANT PROFESS
Material science plays a central role in the search for better storage solutions. In the NanoLab at the MESA+ Institute for Nanotechnology, my fellow scientists and I, along with students, explore technological breakthroughs by studying and designing new materials at nanoscale. One such breakthrough is the solid-state battery. In conventional batteries, two poles – the anode and the cathode – are joined by a liquid, the electrolyte.
Replacing the liquid with a solid yields higher energy density and more power. This is partly caused by the fact that you do not need cooling or protective equipment in a solid-state battery, as the solid cannot leak, it is harmless and insensitive to overheating. That leaves more room for energy storage.
