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[ Album ]\ud83c\udf93<\/b><\/i> In Quantum Mechanics an orbital is a mathematical function which portrays the wave-like behavior of an electron pair, electron or nucleons.Atomic orbitals are the 3D regions of space around the nucleus of an atom. Atomic orbitals allow the atoms to make covalent bonds. s, p, d and f orbitals are the most commonly filled orbitals. These orbitals have a variety of shapes. As defined by the Pauli Exclusion Principle, only two electrons can be found in any orbital space.But there are also nodes. Node is a region where the probability of finding the electron will be zero. The nodal plane is the plane that passes through the nucleus on which the probability of finding an electron is zero.#science<\/a> #quantum<\/a><\/div><\/div>\n\n
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3D printed diagnostic tools.Lateral flow testing is widely used for pregnancy tests and more recently for mass coronavirus testing. A team working at KU Leuven has developed a new 3D printing technique using porous polymers to produce advanced diagnostic tests quickly, cheaply, and easily.The method can be seen in action at: https:\/\/www.youtube.com\/watch?v=qRVa7X_LnV4<\/a>#sciencenews<\/a> #healthcare<\/a> #medicine<\/a> #polymers<\/a><\/div>\n \n <\/i>\n YouTube<\/div>\n \n
3D printing technique for lateral flow diagnostics<\/div>\n
A 3D printing technique developed at the Ameloot Group (KU Leuven) promises to bring the kind of rapid diagnosis seen with lateral flow tests for Covid-19 to other medical conditions. The goal is to produce a wide range of sophisticated diagnostic tests that\u2026<\/div>\n<\/a>\n
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Terahertz spectroscopy of quantum wells.A collaboration between physicists in Japan and Germany applied terahertz emission spectroscopy to understand the 3D dynamics in quantum wells. Their non-contact, non-destructive method can be applied to assessing the ultrafast carrier dynamics, strain physics, phonon dynamics, and ultrafast dielectric responses at the local level in new materials.Their work can be found in Advanced Optical Materials: https:\/\/onlinelibrary.wiley.com\/doi\/10.1002\/adom.202100258<\/a> #sciencenews<\/a> #THz<\/a> #spectroscopy<\/a> #SmartMaterials<\/a><\/div>\n \n <\/i>\n Wiley Online Library<\/div>\n \n
Ultrafast Terahertz Nanoseismology of GaInN\/GaN Multiple Quantum Wells<\/div>\n
Ultrafast terahertz (THz) emission from laser-excited Ga0.8In0.2N\/GaN multiple quantum wells (MQWs) consists of three distinct, differently timed signals. They originate from i) laser-induced dynamic...<\/div>\n<\/a>\n
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How to get involved in research if you are undergraduate student? Undergraduate student Jasmin joins Anna and Kate from STEMM Global to discuss how to get your first research experience.Whether you\u2019re going on to a Masters or PhD, or aiming to work in a research lab over the summer, learn what potential supervisors are looking for in an applicant here<\/a>Subscribe STEMM Global Audio Learning Podcast <\/a>and join the STEMM Global Scientific Community<\/a>#podcast<\/a> #PhD<\/a> #interview<\/a> #Career_In_Science<\/a><\/div>\n \n <\/i>\n Audioboom<\/div>\n \n
How to get involved in research if you are undergraduate student?<\/div>\n
An Audioboom post by STEMM Global Audio Learning<\/div>\n<\/a>\n
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Self-learning robots.Researchers from AMOLF's Soft Robotic Matter group have shown small, autonomous, self-learning robots can adapt easily to changing circumstances. They connected a group of simple robots in a line, after which each individual robot taught itself to move forward as quickly as possible.The results are available in PNAS: https:\/\/www.pnas.org\/content\/118\/21\/e2017015118\/tab-article-info<\/a> #sciencenews<\/a> #AI<\/a> #robots<\/a><\/div>\n \n \n
PNAS<\/div>\n <\/i>\n Continuous learning of emergent behavior in robotic matter<\/div>\n
In the last century, robots have been revolutionizing our lives, augmenting human actions with greater precision and repeatability. Unfortunately, most robotic systems can only operate in controlled environments. While increasing the complexity of the centralized\u2026<\/div>\n<\/a>\n
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A health boost from nature.Access to nature increases city-dwellers\u2019 physical activity and overall health. Researchers from Stanford University explain that parks, lakes, trees and other urban green spaces are a necessary part of creating more healthy, equitable, and sustainable cities.Learn more from their article in PNAS: https:\/\/www.pnas.org\/content\/118\/22\/e2018472118<\/a>#sciencenews<\/a> #medicine<\/a> #healthcare<\/a> #health<\/a><\/div>\n \n \n
PNAS<\/div>\n <\/i>\n An ecosystem service perspective on urban nature, physical activity, and health<\/div>\n
Nature underpins human well-being in critical ways, especially in health. Nature provides pollination of nutritious crops, purification of drinking water, protection from floods, and climate security, among other well-studied health benefits. A crucial, yet\u2026<\/div>\n<\/a>\n
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Ending childhood respiratory infections.Human parainfluenza viruses are the leading cause of childhood respiratory infections. There are currently no available vaccines for the most prevalent of these viruses. Research from the University of Wisconsin shows that engineering suitable short chunks of protein can prevent the attachment of human parainfluenza viruses to cells.The work has recently been published in JACS: https:\/\/pubs.acs.org\/doi\/10.1021\/jacs.1c01565<\/a>#sciencenews<\/a> #healthcare<\/a> #health<\/a> #medicine<\/a> #vaccine<\/a><\/div>\n \n \n
ACS Publications<\/div>\n <\/i>\n Engineering Protease-Resistant Peptides to Inhibit Human Parainfluenza Viral Respiratory Infection<\/div>\n
The lower respiratory tract infections affecting children worldwide are in large part caused by the parainfluenza viruses (HPIVs), particularly HPIV3, along with human metapneumovirus and respiratory syncytial virus, enveloped negative-strand RNA viruses.\u2026<\/div>\n<\/a>\n
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Artificial muscles.Universidad Carlos III de Madrid researchers offer guidance on the design of magneto-active structural systems that can be applied to stimulate wound healing and artificially replicate muscle tissues. They describe their method as creating an \u2018athletic track for cells\u2019.Two articles on their work have been published recently in Composites Part B: Engineering and International Journal of Solids and Structures: https:\/\/doi.org\/10.1016\/j.compositesb.2021.108796<\/a> https:\/\/doi.org\/10.1016\/j.ijsolstr.2020.10.028<\/a>#sciencenews<\/a> #AI<\/a> #bioengineering<\/a><\/div>\n \n <\/i>\n Sciencedirect<\/div>\n \n
Influence of elastomeric matrix and particle volume fraction on the mechanical response of magneto-active polymers<\/div>\n
Magneto-active polymers (MAPs) are revolutionising the fields of material science and solid mechanics as well as having an important presence in the b\u2026<\/div>\n<\/a>\n
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Diagnosing prostate cancer with light.Prostate cancer is the second most common cancer globally in men, but rapid and accurate screening remains a challenge. Researchers from Chernivtsi National University & University of Oulu demonstrate a diagnostic method using polarized light that can quickly analyze prostate tissue samples for signs of cancer.The results are published in Scientific Reports: https:\/\/www.nature.com\/articles\/s41598-021-83986-4<\/a> #sciencenews<\/a> #medicine<\/a> #healthcare<\/a> #health<\/a> #light<\/a><\/div>\n \n <\/i>\n Nature<\/div>\n \n
3D Mueller matrix mapping of layered distributions of depolarisation degree for analysis of prostate adenoma and carcinoma diffuse\u2026<\/div>\n
Scientific Reports - <ArticleTitle Language="En" OutputMedium="All" xml:lang="en">3D Mueller matrix mapping of layered...<\/div>\n<\/a>\n
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A graphene key for computing.Current silicon technology exploits microscopic differences between computing components to create secure keys, but AI techniques can be used to predict defects and gain access to data. Penn State researchers have designed a way to make the encrypted keys harder to crack using graphene.The results are presented in Nature Electronics: https:\/\/www.nature.com\/articles\/s41928-021-00569-x<\/a>#sciencenews<\/a> #AI<\/a> #computing<\/a> #graphene<\/a><\/div>\n \n \n
Nature<\/div>\n <\/i>\n Graphene-based physically unclonable functions that are reconfigurable and resilient to machine learning attacks<\/div>\n
Nature Electronics - Disorder in the charge carrier transport of graphene-based field-effect transistors can be used to construct physically unclonable functions that are secure and can withstand...<\/div>\n<\/a>\n
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Light emitters for quantum circuits. The promise of a quantum internet depends on harnessing light to transmit information over fiber optic networks. Researchers in Sweden have developed integrated chips emit single photons on demand without the need for low temperatures.The work is published in the journal Advanced Quantum Technologies: https:\/\/onlinelibrary.wiley.com\/doi\/10.1002\/qute.202100032<\/a> #sciencenews<\/a> #quantum<\/a> #optics<\/a> #light<\/a><\/div>\n \n <\/i>\n Wiley Online Library<\/div>\n \n
Deterministic Integration of hBN Emitter in Silicon Nitride Photonic Waveguide<\/div>\n
A deterministic process for integrating room-temperature hexagonal boron nitride (hBN) single photon source in silicon nitride waveguides is presented. The encapsulated emitter maintains high single-...<\/div>\n<\/a>\n
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Cold solar cells.The economic value of solar panels depends upon their lifespan and power conversion efficiency. University of New South Wales researchers have developed new and improved solar panels that improve the device lifetime by operating at lower temperatures.Their results are reported in Progress in Photovoltaics: Research and Applications: https:\/\/onlinelibrary.wiley.com\/doi\/10.1002\/pip.3405<\/a>#sciencenews<\/a> #physics<\/a> #solarenergy<\/a> #energy<\/a><\/div>\n \n \n
Wiley Online Library<\/div>\n <\/i>\n Singlet fission and tandem solar cells reduce thermal degradation and enhance lifespan<\/div>\n
The operating temperature of PV modules affects the rate of degradation. We show the extent to which module operating temperature can be reduced by increasing the efficiency of the PV module via a ta...<\/div>\n<\/a>\n
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The future of LED displays?Small and efficient micro-LEDs are a promising technology for the next generation of displays. A new red light micro-LED developed at KAUST promises to boost the future of full-colour displays based on just a single semiconductor.Details of their device can be found in Optics Letters: https:\/\/www.osapublishing.org\/ol\/fulltext.cfm?uri=ol-46-8-1912&id=450025<\/a> #sciencenews<\/a> #physics<\/a> #light<\/a> #optics<\/a><\/div>\n \n <\/i>\n www.osapublishing.org<\/div>\n \n
Investigation of InGaN-based red\/green micro-light-emitting diodes<\/div>\n
We investigated the performance of InGaN-based red\/green micro-light-emitting diodes (\u00b5LEDs) ranging from 98\u00d798\u00b5m2 to 17\u00d717\u00b5m2. The average forward voltage at 10A\/cm2 was independent of the dimension of \u00b5LEDs. Red \u00b5LEDs exhibited a larger blueshift of the\u2026<\/div>\n<\/a>\n
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Improving optical fiberss.Distortions in the signals passed through optical fibers are a massive challenge for modern communications infrastructure. University of Rochester researchers have devised a novel technique where pre-shaping the wave front and polarization of the optical signal reduces distortions during transmission. The results can be viewed in Nature Communications: https:\/\/www.nature.com\/articles\/s41467-021-22071-w<\/a>#sciencenews<\/a> #optics<\/a> #physics<\/a> #smartmaterials<\/a><\/div>\n \n \n
Nature<\/div>\n <\/i>\n High-fidelity spatial mode transmission through a 1-km-long multimode fiber via vectorial time reversal<\/div>\n
Nature Communications - The use of long multimode fibers for multiplexed quantum communication is hindered by modal crosstalk and polarisation mixing. Here, the authors use an auxiliary laser beam...<\/div>\n<\/a>\n
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Why are women under-represented in science?Women are in the minority in scientific disciplines, but it shouldn\u2019t be that way. What are the barriers that prevent women from gaining equal representation? What solutions should be implemented? How do the challenges vary around the world?STEMM Global gathered a diverse international panel of Women in Science at the SNAIA 2020 conference to discuss and debate<\/a> the issues they\u2019ve seen in their careers so far. Joining Anna and Kate from STEMM Global are:Monica Craciun (University of Exeter)Yue Wang (University College London)Silvia Giordani (Dublin City University)Olga Smolyanskaya (ITMO University)Madhu Bhaskaran (RMIT University)Sophie Mancha (University of Wisconsin)Subscribe STEMM Global Audio Learning Podcast<\/a> and join the STEMM Global Scientific Community<\/a>#podcast<\/a> #womeninstemm<\/a> #mothersinstemm<\/a> #equality<\/a><\/div>\n \n <\/i>\n Audioboom<\/div>\n \n
Why are women under-represented in science?<\/div>\n
An Audioboom post by STEMM Global Audio Learning<\/div>\n<\/a>\n
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Enhanced Raman scattering.Devices at the single nanometre scale require characterisation at the atomic level. A team at the Japanese Institute for Molecular Science and the Fritz-Haber Institute has demonstrated a huge enhancement of Raman scattering at the atomic point contact of a plasmonic silver tip.The results are available in ACS Nano Letters: https:\/\/pubs.acs.org\/doi\/10.1021\/acs.nanolett.1c00998<\/a>#sciencenews<\/a> #spectroscopy<\/a><\/div>\n \n \n
pubs.acs.org<\/div>\n <\/i>\n Atomic Point Contact Raman Spectroscopy of a Si(111)-7 \u00d7 7 Surface<\/div>\n
Tip-enhanced Raman scattering (TERS) has recently demonstrated the exceptional sensitivity to observe vibrational structures on the atomic scale. However, it strongly relies on electromagnetic enhancement in plasmonic nanogaps. Here, we demonstrate that atomic\u2026<\/div>\n<\/a>\n
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AI-powered\u200c \u200cmicroscopes.\u200c \u200cLight\u200c \u200cfield\u200c \u200cmicroscopy\u200c \u200callows\u200c \u200cthe\u200c \u200cneuronal\u200c \u200csignals\u200c \u200cin\u200c \u200cthe\u200c \u200cbrain\u200c \u200cto\u200c \u200cbe\u200c \u200cimaged\u200c \u200cin\u200c \u200creal\u200c \u200ctime,\u200c \u200cbut\u200c \u200cthe\u200c \u200cimages\u200c \u200care\u200c \u200coften\u200c \u200clacking\u200c \u200cquality\u200c \u200cand\u200c \u200ctake\u200c \u200ca\u200c \u200clong\u200c \u200ctime\u200c \u200cto\u200c \u200cprocess\u200c \u200cfor\u200c \u200cvisualisation.\u200c \u200cEuropean\u200c \u200cMolecular\u200c \u200cBiology\u200c \u200cLaboratory\u200c \u200cscientists\u200c \u200care\u200c \u200cusing\u200c \u200cartificial\u200c \u200cintelligence\u200c \u200cto\u200c \u200cboost\u200c \u200cthe\u200c \u200cimage\u200c \u200cprocessing\u200c \u200cspeeds\u200c \u200cfrom\u200c \u200cdays\u200c \u200cto\u200c \u200cseconds.\u200c \u200cLearn\u200c \u200cabout\u200c \u200ctheir\u200c \u200ctechnique\u200c \u200cin\u200c \u200cNature\u200c \u200cMethods:\u200c \u200c https:\/\/www.nature.com\/articles\/s41592-021-01136-0\u200c<\/a> #sciencenews<\/a> #AI<\/a> #science<\/a> #microscopy<\/a><\/div>\n \n <\/i>\n Nature Methods<\/div>\n \n
Deep learning-enhanced light-field imaging with continuous validation<\/div>\n
A deep learning\u2013based algorithm enables efficient reconstruction of light-field microscopy data at video rate. In addition, concurrently acquired light-sheet microscopy data provide ground truth data for training, validation and refinement of the algorithm.<\/div>\n<\/a>\n
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Liquid light.Researchers at St. Petersburg State University have experimentally observed the formation of a Bose-Einstein condensate in molybdenum diselenide. The condensate contains thousands of exciton polaritons, or \u2018liquid light\u2019 quanta, which can be used to carry information in quantum computing applications.The work has recently been published in Nature Materials: https:\/\/www.nature.com\/articles\/s41563-021-01000-8<\/a> #sciencenews<\/a> #physics<\/a> #light<\/a> #Quantum<\/a><\/div>\n \n \n
Nature<\/div>\n <\/i>\n Bosonic condensation of exciton\u2013polaritons in an atomically thin crystal<\/div>\n
Nature Materials - A coherent condensate of exciton\u2013polaritons, extending spatially up to 4 \u00b5m and spin-polarizable with an external magnetic field, is observed at cryogenic...<\/div>\n<\/a>\n
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Writing with graphene.A Rice University laboratory can fabricate high resolution conductive patterns at the micron-scale using a laser-induced graphene synthesis process. The graphene patterns can be formed on surfaces including wood, paper, and even food. Their work has been published in ACS Nano: https:\/\/pubs.acs.org\/doi\/10.1021\/acsnano.1c01843<\/a> #sciencenews<\/a> #graphene<\/a> #physics<\/a><\/div>\n \n \n
ACS Publications<\/div>\n <\/i>\n High-Resolution Laser-Induced Graphene from Photoresist<\/div>\n
The fabrication of patterned graphene electronics at high resolution is an important challenge for many applications in microelectronics. Here, we demonstrate the conversion of positive photoresist (PR), commonly employed in the commercial manufacture of\u2026<\/div>\n<\/a>\n
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STEMM Global & Engineering Seminars Series (University of Exeter)Recent advances in microrobotics have demonstrated remarkable locomotive capabilities such as hovering flights, impulsive jumps, and fast running in insect-scale robots. However, most microrobots that are powered by power-dense rigid actuators have not achieved insect-like collision resilience. Meanwhile, the agility of most soft-actuated microrobots remains limited compared to that of rigid-actuated robots. In this talk, Prof Kevin Chen will present their recent effort in developing a new class of microrobots \u2013 ones that are powered by high bandwidth soft actuators and equipped with rigid appendages for effective interactions with environments. Their work demonstrates for the first time that soft aerial robots can achieve agile and robust flight capabilities absent in rigid-powered micro-aerial vehicles, thus showing the potential of a new class of hybrid soft-rigid robots.Prof. Chen is currently the D. Reid Weedon, Jr. \u201941 Career Development Assistant Professor at the Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology (MIT)- He received his PhD in Engineering Sciences at Harvard University in 2017 and his bachelor\u2019s degree in Applied and Engineering Physics from Cornell University in 2012. - His work focuses on developing multifunctional and multimodal insect-scale robots. - His research interests also include developing high bandwidth and robust soft actuators for microrobot manipulation and locomotion. - He is a recipient of the best student paper award at the International Conference on Intelligent Robots and Systems (IROS) 2015 and a Harvard Teaching Excellence Award. - He was named to the \u201cForbes 30 Under 30\u201d list in the category of Science.Join us right now on Youtube<\/b>: https:\/\/www.youtube.com\/watch?v=qc1wzprifPQ<\/a><\/div>\n \n <\/i>\n YouTube<\/div>\n \n
Agile and robust micro-aerial-robots powered by soft artificial muscles with Kevin Chen (MIT, USA)<\/div>\n
Engineering Seminar Series (University of Exeter) Agile and robust micro-aerial-robots powered by soft artificial musclesRecent advances in microrobotics have demonstrated remarkable locomotive capabilities such as hovering flights, impulsive jumps, and\u2026<\/div>\n<\/a>\n
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