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Nano, Nanotechnology, Technology, Science, Research.
can follow the phenomenon as it happens. For the first time, it enables the luminescence thermometry using the nanoparticle’s lifetime with a moving sample. “Compared to existing thermometry techniques, SPLIT is faster and has higher resolution. This allows a more accurate temperature sensing with | medium | 3,225 |
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both an advanced and economical solution,” adds Professor Liang, an expert in ultra-fast imaging. Professors Liang and Vetrone believe that SPLIT technology could, among other things, increase the ability to detect and treat skin cancers. At present, the capacity to detect melanomas, and more | medium | 3,226 |
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specifically micro-melanomas, is still limited. Existing diagnostic approaches are restricted by their invasiveness, resolution and accuracy, which leads to a large number of unnecessary biopsies. Optical thermometry could thus be used to detect cancer cells, whose rapid metabolism leads to a | medium | 3,227 |
Nano, Nanotechnology, Technology, Science, Research.
higher temperature than that of normal tissue, making them more visible with SPLIT. To detect melanoma, clinics can use a thermal camera, but the resolution is low. “SPLIT marks an important step in the technical development. With high resolution, the technology could be used to precisely locate | medium | 3,228 |
Nano, Nanotechnology, Technology, Science, Research.
the cancerous mole,” says Professor Liang. Beyond detection, this technology could also be used to monitor the light dose during certain types of treatment. For example, photothermal therapy attacks cancer cells through the heat generated by exposure to near-infrared light. “We want to eradicate | medium | 3,229 |
Nano, Nanotechnology, Technology, Science, Research.
the cancer, but not the surrounding tissue, so if the temperature is too high, the treatment could be decreased or stopped for a while. If it’s too low, we can increase the light to get the right dose,” says Vetrone. In 2020, the Canadian Cancer Society estimated that 8,000 Canadians had been | medium | 3,230 |
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diagnosed with this form of cancer alone. Fast wide-field upconversion luminescence lifetime thermometry enabled by single-shot compressed… Photoluminescence lifetime imaging of upconverting nanoparticles is increasingly featured in recent progress in optical…www.nature.com Highly Efficient | medium | 3,231 |
Nano, Nanotechnology, Technology, Science, Research.
Photothermal Conversion and Water Transport During Solar Evaporation Enabled by Amorphous Hollow Multishelled Nanocomposites by Xuanbo Chen et al in Advanced Materials Global drinking water scarcity is a severe problem for humans. Water purification consumes a large amount of fossil energy and | medium | 3,232 |
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generates secondary pollution. Solar-thermal interfacial evaporation has been considered the most promising strategy for addressing this problem. However, developing an optimized material featuring both efficient solar-vapor conversion and good environmental tolerance still remains challenging. | medium | 3,233 |
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Researchers from the Institute of Process Engineering (IPE) of the Chinese Academy of Sciences have developed an ultra-stable amorphous Ta2O5/C nanocomposite with a hollow multishelled structure (HoMS) for solar evaporation, which can improve the efficiency of water purification. “The precise | medium | 3,234 |
Nano, Nanotechnology, Technology, Science, Research.
atomic and composition control in the building block of HoMS realizes an indirect bandgap structure with abundant energy states around the Fermi level, which enhances nonradiative relaxation to facilitate photothermal conversion,” said Prof. Wang Dan, the corresponding author of the study, “The | medium | 3,235 |
Nano, Nanotechnology, Technology, Science, Research.
unique hollow multishelled structure can efficiently enhance light absorption like a blackbody.” HoMS decreases the energy required for water evaporation. Simulation results show that HoMS establishes a thermal field gradient, thus providing the driving force for vapor evaporation. “HoMS also | medium | 3,236 |
Nano, Nanotechnology, Technology, Science, Research.
benefits water transport,” said Wang, “The confined cavities in HoMS promote liquid water diffusion owing to the capillary pumping effect, and the nanopores in HoMS induce water molecules to evaporate in the form of clusters, thus enabling evaporation with less enthalpy.” With highly efficient | medium | 3,237 |
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photoabsorption and photothermal conversion, a super-fast evaporation speed of 4.02 kg m-2h-1 has been achieved. The evaporation speed barely changed after 30 days, and with no salt accumulation, indicating a long-term stability. Notably, the concentration of pseudovirus SC2-P could be decreased by | medium | 3,238 |
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six orders of magnitude after evaporation. This amorphous Ta2O5/C composite is readily fabricated, carried, stored, and recycled. It can be applied to the purification of seawater, or to heavy metal- or bacteria-containing water, obtaining drinkable water that meets the standard of the World Health | medium | 3,239 |
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Organization. The scientists from IPE are preparing a prototype of seawater desalination for the residents on isolated islands. Highly Efficient Photothermal Conversion and Water Transport During Solar Evaporation Enabled by… Xuanbo Chen , Nailiang Yang , Jiangyan Wang , Ranbo Yu , Lin Gu , | medium | 3,240 |
Nano, Nanotechnology, Technology, Science, Research.
Chunying Chen , Suojiang Zhang , Dan Wang …onlinelibrary.wiley.com Soft X‐ray Detectors Based on SnS Nanosheets for the Water Window Region by Babar Shabbir et al in Advanced Functional Materials Scientists in Australia have used tin mono-sulfide (SnS) nanosheets to create the thinnest X-ray | medium | 3,241 |
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detector ever made, potentially enabling real-time imaging of cellular biology. X-ray detectors are tools that allow energy transported by radiation to be recognized visually or electronically, like medical imaging or Geiger counters. SnS has already shown great promise as a material for use in | medium | 3,242 |
Nano, Nanotechnology, Technology, Science, Research.
photovoltaics, field effect transistors and catalysis. Now, members of the ARC Centre of Excellence in Exciton Science, based at Monash University and RMIT University, have shown that SnS nanosheets are also excellent candidates for use as soft X-ray detectors. Their research, published in the | medium | 3,243 |
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journal Advanced Functional Materials, indicates that SnS nanosheets possess high photon absorption coefficients, allowing them to be used in making ultrathin soft X-ray detectors with high sensitivity and a rapid response time. These materials were found to be even more sensitive than another | medium | 3,244 |
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emerging candidate (metal halide perovskites), boasting a faster response time than established detectors and are tuneable for sensitivity across the soft X-ray region. The SnS X-ray detectors created by the team are less than 10 nanometres thick. To put things in perspective, a sheet of paper is | medium | 3,245 |
Nano, Nanotechnology, Technology, Science, Research.
about 100,000 nanometres thick, and your fingernails grow about one nanometre every second. Previously, the thinnest X-ray detectors created were between 20 and 50 nanometres. Considerable work remains to explore the full potential of the SnS X-ray detectors, but Professor Jacek Jasieniak of | medium | 3,246 |
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Monash’s Department of Materials Science and Engineering, the senior author of the paper, believes it’s possible this could one day lead to real-time imaging of cellular processes. “The SnS nanosheets respond very quickly, within milliseconds,” he said. “You can scan something and get an image | medium | 3,247 |
Nano, Nanotechnology, Technology, Science, Research.
almost instantaneously. The sensing time dictates the time resolution. In principle, given the high sensitivity and high time resolution, you could be able to see things in real time. “You might be able to use this to see cells as they interact. You’re not just producing a static image, you could | medium | 3,248 |
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see proteins and cells evolving and moving using X-rays.” Why are such sensitive and responsive detectors important? X-rays can be broadly divided into two types: “Hard” X-rays are the kind used by hospitals to scan the body for broken bones and other illnesses. Perhaps less well known but just as | medium | 3,249 |
Nano, Nanotechnology, Technology, Science, Research.
important are “soft” X-rays, which have a lower photon energy and can be used to study wet proteins and living cells, a crucial component of cellular biology. Some of these measurements take place in the “water window,” a region of the electromagnetic spectrum in which water is transparent to soft | medium | 3,250 |
Nano, Nanotechnology, Technology, Science, Research.
X-rays. Soft X-ray detection can be conducted using a Synchrotron, a particle accelerator like the Large Hadron Collider in Switzerland, but access to this type of hugely expensive infrastructure is difficult to secure. Recent advances in non-synchrotron soft X-ray laser sources may allow lower | medium | 3,251 |
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cost, portable detection systems to be designed, providing an accessible alternative to Synchrotrons for researchers around the world. But for this approach to work, we will need soft X-ray detector materials that are highly sensitive to low energy X-rays, provide excellent spatial resolution, and | medium | 3,252 |
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are cost effective. Some existing soft X-ray detectors use an indirect mechanism, in which ionizing radiation is converted into visible photons. This approach allows for multiple energy ranges and frame rates to be studied, but is difficult to prepare and offers limited resolutions. Direct | medium | 3,253 |
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detection methods are easier to prepare and offer better resolutions, because the detector material can be thinner than indirect approaches. Good candidate materials need a high X-ray absorption coefficient, which is calculated using the atomic number of the absorbing atoms, X-ray incident energy, | medium | 3,254 |
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density and atomic mass of an atom. High atomic mass and low energy X-rays favor high absorption, and soft X-rays are more strongly absorbed in thin materials compared to hard X-rays. Nanocrystal films and ferromagnetic flakes have shown promise as certain types of soft X-ray detectors, but they | medium | 3,255 |
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are not well equipped to handle the water region. That’s where the SnS nanosheets come in. One of the lead authors, Dr. Nasir Mahmood of RMIT University, said the sensitivity and efficiency of SnS nanosheets depends greatly on their thickness and lateral dimensions, which are not possible to | medium | 3,256 |
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control through traditional fabrication methods. Using a liquid metal-based exfoliation method allowed the researchers to produce high quality, large area sheets with controlled thickness, which can efficiently detect soft X-ray photons in the water region. Their sensitivity can be further enhanced | medium | 3,257 |
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by a process of stacking the ultrathin layers. They represent major improvements in sensitivity and response time compared to existing direct soft X-ray detectors. The researchers hope their findings will open new avenues for the development of next-generation, highly sensitive X-ray detectors | medium | 3,258 |
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based on ultrathin materials. First author Dr. Babar Shabbir of Monash’s Department of Materials Science and Engineering said: “In the long run, to commercialize this, we need to test a many-pixel device. At this stage we don’t have the imaging system. But this provides us with a knowledge platform | medium | 3,259 |
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and a prototype.” Phys.org - News and Articles on Science and Technology Daily science news on research developments, technological breakthroughs and the latest scientific innovationsphys.org Low Power MoS 2 /Nb 2 O 5 Memtransistor Device with Highly Reliable Heterosynaptic Plasticity by Jae Hyeon | medium | 3,260 |
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Nam et al in Advanced Functional Materials Researchers in Korea succeeded in developing a core material for the next-generation neuromorphic (neural network imitation) semiconductor for the first time in the country. This is a result of a research team led by Dr. Jung-dae Kwon and Yong-hun Kim of | medium | 3,261 |
Nano, Nanotechnology, Technology, Science, Research.
the Department of Energy and Electronic Materials of the Korea Institute of Materials Science, together with Professor Byungjin Cho’s research team at Chungbuk National University. KIMS is a government-funded research institute under the Ministry of Science and ICT. This new concept memtransistor | medium | 3,262 |
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uses a two-dimensional nanomaterial with a thickness of several nanometers. By reproducibly imitating the electrical plasticity of nerve synapses with more than 1,000 electrical stimulations, the researchers succeeded in obtaining a high pattern recognition rate of about 94.2% (98% of | medium | 3,263 |
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simulation-based pattern recognition rate). Molybdenum sulfur (MoS2), widely used as a semiconductor material, works on the principle that defects in a single crystal are moved by an external electric field, which makes it difficult to precisely control the concentration or shape of the defect. To | medium | 3,264 |
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solve the problem, the research team sequentially stacked an oxidic layer of niobium oxide (Nb2O5) and a molybdenum sulfur material and succeeded in developing an artificial synaptic device having a memtransistor structure with high electrical reliability by an external electric field. In addition, | medium | 3,265 |
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they have demonstrated that the resistance switching characteristics can be freely controlled by changing the thickness of the niobium oxidic layer, and that brain information related to memory and forgetting can be processed with a very low energy of 10 PJ (picojoule). Currently, as artificial | medium | 3,266 |
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intelligence hardware consumes large amounts of power and costs in the form of GPUs, FPGAs, and ASICs, it is expected to generate explosive demand as the industry grows in the future. The wearable AI market is expected to reach $42.4 billion by 2023, at a CAGR of 29.75% from about $11.5 billion in | medium | 3,267 |
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2018. A research team led by Dr. Jung-dae Kwon and Yong-hun Kim at KIMS said, “Using a high-reliable, new-concept memtransistor structure-based AI semiconductor can greatly reduce the circuit density and driving energy. It is expected to be applied to low-power edge computing and wearable AI | medium | 3,268 |
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systems in the future.” Low Power MoS2/Nb2O5 Memtransistor Device with Highly Reliable Heterosynaptic Plasticity (Adv… Heterosynaptic Plasticity In article number 2104174, Jung-Dae Kwon, Yonghun Kim, Byungjin Cho, and co-workers…onlinelibrary.wiley.com Ultrasound-Assisted Synthesis of Luminescent | medium | 3,269 |
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Micro- and Nanocrystalline Eu-Based MOFs as Luminescent Probes for Heavy Metal Ions by Stefaniia S. Kolesnik et al in Nanomaterials Scientists at St Petersburg University, Sirius University of Science and Technology, and St Petersburg Academic University have synthesized the smallest nano-sized | medium | 3,270 |
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metal-organic frameworks to detect heavy metal ions in water. The results and outcomes of the experiments and description of the properties of the crystals are published in Nanomaterials. Metal-organic polymers, or metal-organic frameworks (MOFs), are crystals composed of metal ions interconnected | medium | 3,271 |
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by organic molecules, i.e. organic linkers. Various concentrations of the metal ions and organic linkers can be used to synthesize materials with different structures and properties. MOFs are widely used to design electro-chemical sensors as reaction catalysts in chemical industry or propellant | medium | 3,272 |
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additives. Some of the MOFs are luminescent MOFs. They emit light caused by UV rays, electromagnetic field, or other disturbances. Luminescent MOFs are actively used as LED components and luminescent thermometers. Additionally, they are used in diagnosis of cancer. Luminescent MOFs are also used as | medium | 3,273 |
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luminescent sensors for pollutants. St Petersburg University chemists synthesized the smallest nano-sized crystals by the ultrasound-assisted wet-chemical method. They were synthesized by a slow mixing of sodium terephthalate and europium chloride aqueous solutions by using the ultrasound-assisted | medium | 3,274 |
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wet-chemical method, precipitated in the form of a polycrystalline solid. Ultrasonication ensured a better mixing of solution, slowed growth of particles, prevented the aggregation of the microparticles, and resulted in the formation of individual microparticles. Photo of microparticles. Credit: | medium | 3,275 |
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SPbU The scientists synthesized particles of various sizes. The average particle size can be equal 8 nm up to hundreds micrometers. Today, the reported europium(III) terephthalate tetrahydrate (Eu2bdc3·4H2O) metal-organic frameworks nanoparticles are the smallest nano-sized rare-earth-based MOF | medium | 3,276 |
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crystals. “We did not expect that a twofold decrease in the concentration of reagents could lead to size reduction for several orders. Presumably, this effect may be due to europium-terephthalate 1:1 complex. This can accelerate the growth process of the particles. Earlier, scientists could | medium | 3,277 |
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synthesize nano-sized particles of terephthalate that were equal to 40 nm or even more. We managed to synthesize particles with the fivefold smaller size,” said the head of the research, Associate Professor in the Department of Laser Chemistry at St Petersburg University and Doctor of Chemistry | medium | 3,278 |
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Andrey Mereshchenko. The developed method to synthesize nanoparticles can make a positive contribution to nanotechnology and coordination chemistry. By using this method, we can synthesize nanoparticles from other MOFs. The experiments also reported the selective luminescence quenching by heavy | medium | 3,279 |
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metal ions. As a result, the synthesized nanoparticles can be used as sensors to detect heavy metal ions in water. “This discovery has a potential to develop efficient sensors to monitor heavy metal ions in drinking water. Our luminescent MOFs demonstrate significantly lower limits of detection on | medium | 3,280 |
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heavy metal ions. This will ensure more accurate measurements of pollutants in water, even in small concentrations,” said Viktor Nosov, a co-author of the article and a student in Chemistry at St Petersburg University. The reported nanoparticles can also be used as luminescent sensors to detect | medium | 3,281 |
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Cu2+, Cr3+, and Fe3+ ions in water. The presence of these metals in water poses a threat to human beings and animals. Heavy metal accumulation in the body can effect human metabolism and lead to nervous system diseases, vascular diseases, and digestive disorders. The chemists are planning to | medium | 3,282 |
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continue the research and develop an express test to detect heavy metal ions in drinking water and waste. Ultrasound-Assisted Synthesis of Luminescent Micro- and Nanocrystalline Eu-Based MOFs as… The luminescent coarse-, micro- and nanocrystalline europium(III) terephthalate tetrahydrate | medium | 3,283 |
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(Eu2bdc3·4H2O)…www.mdpi.com Plasmonic Cu27S24 nanocages for novel solar photothermal nanoink and nanofilm by Min Xi et al in Nano Research Recently, researchers developed high-performance solar thermal copper sulfide photothermal ink and photothermal film, marking big progress in the field of | medium | 3,284 |
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Plasmonic Solar photothermal Materials. The team was led by Prof. Wang Zhenyang from the Institute of Solid State Physics, Hefei Institutes of physical science, Chinese Academy of Sciences. The relevant results were published on Nano Research. Scientists have been seeking strategies to achieve high | medium | 3,285 |
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efficient solar energy utilization for various applications, such as: solar water heaters, energy-saving buildings, drying systems and other fields. In this study, researchers used the Kirkendall reaction to synthesize hollow copper sulfide (Cu27S24) nanocages. Compared to traditional noble metal | medium | 3,286 |
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plasmonic nanomaterials (gold or silver), which shows plasmon photothermal phenomena given the condition of illumination with visible light, Cu27S24 nanocages as semiconducting material that have lower interband transition and scattering loss. Besides, the hollow nanocage structure can further | medium | 3,287 |
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expand the available light harvesting range and further improve the light-to-heat conversion efficiency. Novel plasmonic solar thermal materials developed to reserve Sun heat. Credit: XI Min The researchers combined first-principles calculations and finite element method (FEM) simulations to fit | medium | 3,288 |
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the optical properties of the nanocage, and predicted its excellent solar photothermal performance. Based on the evaluation results, solar photothermal nanoink and nanofilm were further developed. This work preliminarily proves that the hollow copper sulfide nanocage has broad prospects in | medium | 3,289 |
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plasmonic photothermal applications. Plasmonic Cu27S24 nanocages for novel solar photothermal nanoink and nanofilm - Nano Research Copper sulfide (CuxS) as a plasmonic solar photothermal semiconductor material that expands the light collection range…link.springer.com Hybrid artificial neural | medium | 3,290 |
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networks and analytical model for prediction of optical constants and bandgap energy of 3D nanonetwork silicon structures by Shreeniket Joshi et al in Opto-Electronic Advances In a new publication from Opto-Electronic Advances, Shreeniket Joshi and Amirkianoosh Kiani from Ontario Tech University, | medium | 3,291 |
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Ontario, Canada, discuss hybrid artificial neural networks and analytical model for prediction of optical constants and bandgap energy of 3D nanonetwork silicon structures. This study introduces a reliable method to determine optical properties for novel silicon thin films (nanomaterial). Silicon | medium | 3,292 |
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thin films were deposited on glass by bombarding silicon wafers with pulsed laser beams. Finding optical properties of novel nanomaterials is challenging as limited experimental data is available. The existing models for finding optical properties were found to be complex and prone to errors, this | medium | 3,293 |
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study proposes a new method of using analytical models with artificial neural networks. The purpose of using artificial neural networks was to develop a mathematical function to predict optical constants for novel thin films. This method proposed was found to be 95 percent accurate. The research | medium | 3,294 |
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group of Dr. Amirkianoosh Kiani from Ontario Tech University proposed this study to find optical properties of novel silicon thin films and the method was validated with conclusive proof to be accurate and reliable. For transparent novel materials, optical properties can be determined using | medium | 3,295 |
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experimental data for transmittance and reflectance. However, it’s challenging to do the same for opaque materials as in this case only reflectance data is available. This study can be used to establish a mathematical relation between the available experimental data and shows promising potential | medium | 3,296 |
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for predicting optical properties for opaque materials from reflectance data alone. Further, the optical properties determined for the novel silicon thin film discussed in this study was found to have an energy band gap of 1.648, this value is close to materials used for harvesting solar energy. As | medium | 3,297 |
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silicon thin films have a phenomenal surface area, a material with this energy band gap can prove to be highly efficient in solar applications. The research group also intends to use this method for exciting materials like titania, gold nanoparticles, etc. which are used in biomedical applications. | medium | 3,298 |
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Hybrid artificial neural networks and analytical model for prediction of optical constants and… Joshi S, Kiani A. Hybrid artificial neural networks and analytical model for prediction of optical constants and…www.oejournal.org MISC Subscribe to Paradigm! Medium. Twitter. Telegram. Telegram Chat. | medium | 3,299 |
Industrial Mep Bim, Industrial Mep, Bim.
In the realm of industrial construction, the integration of Mechanical, Electrical, and Plumbing (MEP) systems is a critical aspect that demands meticulous planning and execution. With the advent of Building Information Modeling (BIM), the landscape of industrial MEP projects has undergone a | medium | 3,301 |
Industrial Mep Bim, Industrial Mep, Bim.
significant transformation, offering unprecedented opportunities for efficiency, collaboration, and optimization. At the heart of every industrial MEP BIM project lies the ability to navigate complexity with precision and foresight. BIM serves as a digital backbone, allowing stakeholders to | medium | 3,302 |
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visualize, simulate, and analyze MEP systems with unparalleled accuracy. From intricate HVAC ductwork to intricate electrical layouts and plumbing networks, BIM provides a comprehensive platform for integrating these systems seamlessly within the industrial infrastructure. One of the primary | medium | 3,303 |
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advantages of leveraging BIM in industrial MEP projects is the ability to optimize system performance while minimizing risks and errors. Through advanced simulations and clash detection capabilities, potential conflicts between MEP components can be identified and resolved during the design phase, | medium | 3,304 |
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preventing costly rework and delays during construction. Additionally, BIM facilitates real-time collaboration among multidisciplinary teams, enabling stakeholders to work cohesively towards common project goals. Furthermore, BIM enables the implementation of sustainable design principles within | medium | 3,305 |
Industrial Mep Bim, Industrial Mep, Bim.
industrial MEP systems. By incorporating energy-efficient HVAC solutions, intelligent lighting systems, and water-saving plumbing fixtures, industrial facilities can minimize their environmental footprint while maximizing operational efficiency. BIM serves as a valuable tool for evaluating various | medium | 3,306 |
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sustainability strategies and assessing their impact on overall project performance. Here are some additional points to explore in the context of Industrial MEP BIM projects: Improved Facility Management: Beyond the construction phase, BIM continues to deliver value by providing comprehensive | medium | 3,307 |
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data-rich models that serve as valuable assets for facility management. Facility operators can leverage BIM data to streamline maintenance activities, conduct asset tracking, and plan future upgrades or expansions with greater efficiency. Cost Savings through Clash Detection: Clash detection | medium | 3,308 |
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functionality in BIM software allows for early identification of conflicts between MEP systems and structural elements. By addressing these clashes during the design phase, costly on-site rework and modifications can be avoided, resulting in significant cost savings for industrial projects. | medium | 3,309 |
Industrial Mep Bim, Industrial Mep, Bim.
Enhanced Safety: BIM technology enables the visualization of MEP systems in a virtual environment, allowing stakeholders to identify potential safety hazards and design solutions to mitigate risks. By proactively addressing safety concerns during the planning and design stages, industrial projects | medium | 3,310 |
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can prioritize worker safety and minimize the likelihood of accidents on-site. Integration with Building Automation Systems: BIM models can be seamlessly integrated with building automation systems (BAS) to create smart industrial facilities that optimize energy usage, enhance occupant comfort, and | medium | 3,311 |
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improve overall operational efficiency. Through BIM-BAS integration, industrial facilities can achieve greater control and automation of MEP systems, leading to enhanced performance and sustainability. Compliance with Regulatory Requirements: BIM enables industrial MEP systems to be designed in | medium | 3,312 |
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compliance with local building codes, regulations, and industry standards. By incorporating regulatory requirements into the BIM model, stakeholders can ensure that MEP systems meet all necessary criteria, reducing the risk of non-compliance issues during construction and occupancy. Lifecycle | medium | 3,313 |
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Analysis and Decision-Making: BIM facilitates lifecycle analysis of industrial MEP systems, allowing stakeholders to evaluate the long-term performance and cost implications of various design alternatives. By conducting comprehensive lifecycle assessments, project teams can make informed decisions | medium | 3,314 |
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that optimize performance, durability, and maintainability over the entire lifecycle of the facility. Scalability and Flexibility: Industrial MEP BIM projects offer scalability and flexibility to accommodate future changes and expansions. BIM models can be easily updated to reflect modifications or | medium | 3,315 |
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additions to MEP systems, ensuring that industrial facilities remain adaptable to evolving business needs and technological advancements. In conclusion, the adoption of BIM in industrial MEP projects heralds a new era of innovation and efficiency in construction. By leveraging advanced technologies | medium | 3,316 |
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and collaborative workflows, industrial stakeholders can navigate the complexities of MEP systems with confidence and precision. From optimizing system performance to promoting sustainability, BIM emerges as a transformative force in shaping the future of industrial infrastructure. | medium | 3,317 |
Data Platforms, Sql, Speakers, Learning, Data.
Discover the must-attend sessions and networking opportunities in SQLBits 2024 from the viewpoint of a speaker. Find out what to anticipate from the top conference for SQL and data platform specialists, including the newest developments in technology and priceless industry insights. Sqlbits There | medium | 3,318 |
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is a tangible sense of excitement in the SQL community and data platform as SQLBits 2024 approaches. Renowned for its coverage of SQL, Fabric, PowerBI, and Azure topics, this event has consistently been shining for professionals looking to broaden their network and enhance their expertise. I am | medium | 3,319 |
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especially looking forward to SQLBits this year, and I would like to share my plans and expectations for this important conference. Network SQLBits has always been a gathering place for the most innovative thinkers in the data platform space. I anticipate that this year’s event will push the | medium | 3,320 |
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envelope even further by providing a wide range of sessions that explore the most recent developments and industry best practices in SQL, Fabric, PowerBI, and Azure. I’m excited that there will be a fair with a variety of important industry players because it offers a special chance to network with | medium | 3,321 |
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innovators and thought leaders. SQLBits’ core values are centered around networking moments. Whether intentional or accidental, these encounters frequently result in enlightening conversations. With the breadth of data platforms growing and the complexity of challenges in our field growing, I | medium | 3,322 |
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expect these moments to be even more fulfilling this year. Sqlbits 2023 Sessions I’m Eager to Attend There are so many sessions on the SQLBits 2024 schedule that interest me. I’ll adjust my schedule closer to the event, but here’s a sample of the sessions I probably will be at: Time Series with SQL | medium | 3,323 |
Data Platforms, Sql, Speakers, Learning, Data.
Server 2022 Relational or Non-Relational? Choosing the Best Database for the Task Navigating Microsoft Fabric — Choosing the Right Workload for Your Needs Building Tomorrow’s Warehouse Today: Modern Data Warehouse Modelling Insights. Fabric security: everything you need to know! Setting yourself up | medium | 3,324 |
Data Platforms, Sql, Speakers, Learning, Data.
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