{"682216":{"#nid":"682216","#data":{"type":"news","title":"Unique Molecule May Lead to Smaller, More Efficient Computers","body":[{"value":"\u003Cp\u003E\u003Ca href=\u0022https:\/\/chemistry.gatech.edu\/people\/jason-azoulay\u0022\u003E\u003Cem\u003E\u003Cstrong\u003EJason Azoulay\u003C\/strong\u003E\u003C\/em\u003E\u003C\/a\u003E\u003Cem\u003E is an associate professor of \u003C\/em\u003E\u003Ca href=\u0022https:\/\/chemistry.gatech.edu\u0022\u003E\u003Cem\u003EChemistry and Biochemistry\u003C\/em\u003E\u003C\/a\u003E\u003Cem\u003E and \u003C\/em\u003E\u003Ca href=\u0022https:\/\/www.mse.gatech.edu\u0022\u003E\u003Cem\u003EMaterials Science and Engineering\u003C\/em\u003E\u003C\/a\u003E\u003Cem\u003E at Georgia Tech. He is the \u003C\/em\u003E\u003Ca href=\u0022https:\/\/gra.org\/\u0022\u003E\u003Cem\u003EGeorgia Research Alliance\u003C\/em\u003E\u003C\/a\u003E\u003Cem\u003E Vasser-Woolley Distinguished Investigator in Optoelectronics and serves as co-director of the \u003C\/em\u003E\u003Ca href=\u0022https:\/\/cope.gatech.edu\/\u0022\u003E\u003Cem\u003ECenter for Organic Photonics and Electronics\u003C\/em\u003E\u003C\/a\u003E\u003Cem\u003E.\u003C\/em\u003E\u003C\/p\u003E\u003Cp\u003E\u003Cem\u003EThis story by Janette Neuwahl Tannen is \u003C\/em\u003E\u003Ca href=\u0022https:\/\/news.miami.edu\/stories\/2025\/05\/unique-molecule-may-lead-to-smaller-more-efficient-computers.html\u0022\u003E\u003Cem\u003Eshared jointly with the University of Miami\u003C\/em\u003E\u003C\/a\u003E\u003Cem\u003E newsroom.\u0026nbsp;\u003C\/em\u003E\u003C\/p\u003E\u003Cp\u003EToday, most of us carry a fairly powerful computer in our hand \u2014 a smartphone.\u003C\/p\u003E\u003Cp\u003EBut computers weren\u2019t always so portable. Since the 1980s, they have become smaller, lighter, and better equipped to store and process vast troves of data.\u003C\/p\u003E\u003Cp\u003EYet the silicon chips that power computers can only get so small.\u003C\/p\u003E\u003Cp\u003E\u201cOver the past 50 years, the number of transistors we can put on a chip has doubled every two years,\u201d says \u003Ca href=\u0022https:\/\/people.miami.edu\/profile\/f7bad2a8f419d8386bde26d3bb75406d\u0022\u003EKun Wang\u003C\/a\u003E, assistant professor of physics at the University of Miami \u003Ca href=\u0022https:\/\/www.as.miami.edu\/\u0022\u003ECollege of Arts and Sciences\u003C\/a\u003E. \u201cBut we are rapidly reaching the physical limits for silicon-based electronics, and it\u2019s more challenging to miniaturize electronic components using the technologies we have been using for half a century.\u201d\u003C\/p\u003E\u003Cp\u003EIt\u2019s a problem that Wang and many in his field of molecular electronics are hoping to solve. Specifically, they are looking for a way to conduct electricity without using silicon or metal, which are used to create computer chips today. Using tiny molecular materials for functional components, like transistors, sensors, and interconnects in electronic chips offers several advantages, especially as traditional silicon-based technologies approach their physical and performance limits.\u003C\/p\u003E\u003Cp\u003EBut finding the ideal chemical makeup for this molecule has stumped scientists. Recently, Wang, along with his graduate students, \u003Cstrong\u003EMehrdad Shiri\u003C\/strong\u003E and \u003Cstrong\u003EShaocheng Shen\u003C\/strong\u003E, and collaborators \u003Cstrong\u003EJason Azoulay\u003C\/strong\u003E, associate professor at Georgia Institute of Technology and Georgia Research Alliance Vasser-Woolley Distinguished Investigator;\u0026nbsp;and \u003Cstrong\u003EIgnacio Franco\u003C\/strong\u003E, professor at the University of Rochester, uncovered a promising solution.\u003C\/p\u003E\u003Cp\u003EThis week, the team shared what they believe is the world\u2019s most electrically conductive organic molecule. Their discovery, published in the \u003Ca href=\u0022https:\/\/urldefense.com\/v3\/__http:\/www.pubs.acs.org\/doi\/10.1021\/jacs.4c18150__;!!KVu0SnhVq1hAFvslES2Y!LLGIGEsofweH_wfibO4xZ3nKxcvpUgjmdtiRpstWtkFFtN9MzYlEwOkWLnAMmkrSFJJ23Gt1-txxR2ds$\u0022\u003EJournal of the American Chemical Society\u003C\/a\u003E, opens up new possibilities for constructing smaller, more powerful computing devices at the molecular scale. Even better, the molecule is composed of chemical elements found in nature \u2014 mostly carbon, sulfur, and nitrogen.\u003C\/p\u003E\u003Cp\u003E\u201cSo far, there is no molecular material that allows electrons to go across it without significant loss of conductivity,\u201d Wang says. \u201cThis work is the first demonstration that organic molecules can allow electrons to migrate across it without any energy loss over several tens of nanometers.\u201d\u003C\/p\u003E\u003Cp\u003EThe testing and validation of their unique new molecule took more than two years.\u003C\/p\u003E\u003Cp\u003EHowever, the work of this team reveals that their molecules are stable under everyday ambient conditions and offer the highest possible electrical conductance at unparalleled lengths. Therefore, it could pave the way for classical computing devices to become smaller, more energy-efficient, as well as cost-efficient, Wang adds.\u003C\/p\u003E\u003Cp\u003ECurrently, the ability of a molecule to conduct electrons decreases exponentially as the molecular size increases. These newly developed molecular \u201cwires\u201d are needed highways for information to be transferred, processed, and stored in future computing, Wang says.\u003C\/p\u003E\u003Cp\u003E\u201cWhat\u2019s unique in our molecular system is that electrons travel across the molecule like a bullet without energy loss, so it is theoretically the most efficient way of electron transport in any material system,\u201d Wang notes. \u201cNot only can it downsize future electronic devices, but its structure could also enable functions that were not even possible with silicon-based materials.\u201d\u003C\/p\u003E\u003Cp\u003EWang means that the molecule\u2019s abilities might create new opportunities to revolutionize molecule-based quantum information science.\u003C\/p\u003E\u003Cp\u003E\u201cThe ultra-high electrical conductance observed in our molecules is a result of an intriguing interaction of electron spins at the two ends of the molecule,\u201d he adds. \u201cIn the future, one could use this molecular system as a qubit, which is a fundamental unit for quantum computing.\u201d\u003C\/p\u003E\u003Cp\u003EThe team was able to notice these abilities by studying their new molecule under a scanning tunneling microscope (STM). Using a technique called STM break-junction, the team was able to capture a single molecule and measure its conductance.\u003C\/p\u003E\u003Cp\u003EShiri, the graduate student, adds: \u201cIn terms of application, this molecule is a big leap toward real-world applications. Since it is chemically robust and air-stable, it could even be integrated with existing nanoelectronic components in a chip and work as an electronic wire or interconnects between chips.\u201d\u003C\/p\u003E\u003Cp\u003EBeyond that, the materials needed to compose the molecule are inexpensive, and it can be created in a lab.\u003C\/p\u003E\u003Cp\u003E\u201cThis molecular system functions in a way that is not possible with current, conventional materials,\u201d Wang says. \u201cThese are new properties that would not add to the cost but could make (computing devices) more powerful and energy efficient.\u201d\u0026nbsp;\u003C\/p\u003E\u003Cp\u003E\u0026nbsp;\u003C\/p\u003E\u003Cp\u003E\u003Cem\u003E\u003Cstrong\u003EDOI:\u003C\/strong\u003E \u003C\/em\u003E\u003Ca href=\u0022https:\/\/doi.org\/10.1021\/jacs.4c18150\u0022\u003E\u003Cem\u003Ehttps:\/\/doi.org\/10.1021\/jacs.4c18150\u003C\/em\u003E\u003C\/a\u003E\u003C\/p\u003E\u003Cp\u003E\u003Cem\u003E\u003Cstrong\u003EFunding:\u003C\/strong\u003E \u003Cstrong\u003EU.S. Department of Energy\u003C\/strong\u003E, Office of Science, Basic Energy\u003C\/em\u003E\u003Cbr\u003E\u003Cem\u003ESciences; \u003Cstrong\u003ENational Science Foundation\u003C\/strong\u003E (NSF); \u003Cstrong\u003EAir Force Office of Scientific Research\u003C\/strong\u003E (AFOSR) under support provided by the Organic Materials\u003C\/em\u003E\u003Cbr\u003E\u003Cem\u003EChemistry Program; \u003Cstrong\u003EGeorgia Tech Research Institute\u003C\/strong\u003E (GTRI) Graduate\u003C\/em\u003E\u003Cbr\u003E\u003Cem\u003EStudent Researcher Fellowship Program (GSFP). Computational resources were provided by the \u003Cstrong\u003ECenter for Integrated Research Computing\u003C\/strong\u003E (CIRC) at the\u003C\/em\u003E\u003Cbr\u003E\u003Cem\u003EUniversity of Rochester.\u003C\/em\u003E\u003C\/p\u003E\u003Cp\u003E\u003Cem\u003EAlong with Jason Azoulay, Georgia Tech co-authors also include \u003Cstrong\u003EParamasivam Mahalingam\u003C\/strong\u003E, \u003Cstrong\u003ETyler Bills\u003C\/strong\u003E, \u003Cstrong\u003EAlexander J. Bushnell\u003C\/strong\u003E, and \u003Cstrong\u003ETanya A. Balandin\u003C\/strong\u003E.\u003C\/em\u003E\u003C\/p\u003E","summary":"","format":"limited_html"}],"field_subtitle":[{"value":"Physicists have developed a new type of molecule that could offer a groundbreaking material for computer chips.  "}],"field_summary":[{"value":"\u003Cp\u003EPhysicists from Georgia Tech, University of Miami, and University of Rochester have developed a new type of molecule that could offer a groundbreaking material for computer chips.\u0026nbsp;\u003C\/p\u003E","format":"limited_html"}],"field_summary_sentence":[{"value":"Physicists have developed a new type of molecule that could offer a groundbreaking material for computer chips.  "}],"uid":"34528","created_gmt":"2025-05-02 20:46:28","changed_gmt":"2025-05-02 20:50:56","author":"jhunt7","boilerplate_text":"","field_publication":"","field_article_url":"","location":"Atlanta, GA","dateline":{"date":"2025-05-02T00:00:00-04:00","iso_date":"2025-05-02T00:00:00-04:00","tz":"America\/New_York"},"extras":[],"hg_media":{"677029":{"id":"677029","type":"image","title":"(Rendering: Second Bay Studios)","body":null,"created":"1746219016","gmt_created":"2025-05-02 20:50:16","changed":"1746219016","gmt_changed":"2025-05-02 20:50:16","alt":"(Rendering: Second Bay Studios)","file":{"fid":"260889","name":"Full_D5_Gold65-web.jpg","image_path":"\/sites\/default\/files\/2025\/05\/02\/Full_D5_Gold65-web.jpg","image_full_path":"http:\/\/hg.gatech.edu\/\/sites\/default\/files\/2025\/05\/02\/Full_D5_Gold65-web.jpg","mime":"image\/jpeg","size":2190871,"path_740":"http:\/\/hg.gatech.edu\/sites\/default\/files\/styles\/740xx_scale\/public\/2025\/05\/02\/Full_D5_Gold65-web.jpg?itok=uxPpGaA0"}}},"media_ids":["677029"],"related_links":[{"url":"https:\/\/cos.gatech.edu\/news\/georgia-tech-welcomes-first-gra-distinguished-investigator-new-eminent-scholar","title":"Georgia Tech Welcomes First GRA Distinguished Investigator, New Eminent Scholar"},{"url":"https:\/\/cos.gatech.edu\/experts\/nsf-invests-725m-design-revolutionary-materials","title":"https:\/\/cos.gatech.edu\/experts\/nsf-invests-725m-design-revolutionary-materials"}],"groups":[{"id":"1237","name":"College of Engineering"},{"id":"1278","name":"College of Sciences"},{"id":"1188","name":"Research Horizons"},{"id":"85951","name":"School of Chemistry and Biochemistry"}],"categories":[],"keywords":[{"id":"187915","name":"go-researchnews"}],"core_research_areas":[],"news_room_topics":[],"event_categories":[],"invited_audience":[],"affiliations":[],"classification":[],"areas_of_expertise":[],"news_and_recent_appearances":[],"phone":[],"contact":[{"value":"\u003Cp\u003E\u003Ca href=\u0022mailto:jess@cos.gatech.edu\u0022\u003EJess Hunt-Ralston\u003C\/a\u003E\u003Cbr\u003EDirector of Communications\u0026nbsp;\u003Cbr\u003ECollege of Sciences at Georgia Tech\u003C\/p\u003E","format":"limited_html"}],"email":["jess@cos.gatech.edu"],"slides":[],"orientation":[],"userdata":""}}}