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Solar trees provide opportunity to meet renewable energy targets without deforestation

With the right technology, solar energy has the potential to meet all of the world’s electricity needs, but we are still a long way off from that point. Still, governments around the world are setting high objectives for renewable energy. Many world leaders have set commitments to phase out coal power and transition away from fossil fuels, and solar panel installations are currently one of the top contenders for implementing these plans.

However, solar energy has a bit of a dark secret. In some places, putting up these massive solar panel installations requires cutting down hundreds or even thousands of hectares of forests over time. In South Korea, deforestation caused by solar installations affected 529 hectares of in 2016, 1,435 hectares in 2017, and 2,443 hectares in 2018.

Of course, there are some solar installations located in deserts or other treeless landscapes that don’t have this issue. But those that do end up cutting out an incredibly important carbon sink, first worsening the problem they are attempting to alleviate. This deforestation then causes further issues with erosion and the destruction of natural habitats.

New AI model advances fusion power research by predicting the success of experiments

Practical fusion power that can provide cheap, clean energy could be a step closer thanks to artificial intelligence. Scientists at Lawrence Livermore National Laboratory have developed a deep learning model that accurately predicted the results of a nuclear fusion experiment conducted in 2022. Accurate predictions can help speed up the design of new experiments and accelerate the quest for this virtually limitless energy source.

In a paper published in Science, researchers describe how their AI model predicted with a probability of 74% that ignition was the likely outcome of a small 2022 fusion experiment at the National Ignition Facility (NIF). This is a significant advance as the model was able to cover more parameters with greater precision than traditional supercomputers.

Currently, nuclear power comes from nuclear fission, which generates energy by splitting atoms. However, it can produce radioactive waste that remains dangerous for thousands of years. Fusion generates energy by fusing atoms, similar to what happens inside the sun. The process is safer and does not produce any long-term radioactive waste. While it is a promising energy source, it is still a long way from being a viable commercial technology.

Carbon nanotube ‘smart windows’ offer energy savings

Half of the sun’s radiant energy falls outside of the visible spectrum. On a cold day, this extra infrared light provides additional warmth to residential and commercial buildings. On a warm day, it leads to unwanted heating that must be dealt with through energy-intensive climate control methods such as air-conditioning. Visibly transparent “smart windows” that can modulate the transmission of near infrared light offer one potential cost- and energy-saving measure for modern infrastructure. To work towards solving this technological challenge, a multidisciplinary team of researchers at

Using nature to fight liver cancer

You may not be aware that most of the medicines that have been approved for treatment are rooted in nature.

For example, the bark of willow trees has been called nature’s aspirin because it contains a chemical called salicin. The human body converts salicin into salicylic acid, which relieves pain and fights fevers.

New research by William Chain, associate professor in the University of Delaware’s Department of Chemistry and Biochemistry, and his lab, uses a molecule found in a tropical fruit to offer hope in the fight against liver-related cancers, one of the world’s top causes of cancer deaths.

Chemistry breakthrough provides pathway to low cost treatments.

What Are the Interferences to Radio Waves?

Radio interference refers to the phenomenon that occurs during radio communication, where some electromagnetic energy enters the receiving system or channel through direct or indirect coupling, resulting in a decrease in the quality of useful received signals, information errors or loss, or even blocking communication.

Radio interference signals are mainly electromagnetic energy that enters the receiving device channel or system through direct or indirect coupling. It can affect the reception of received signals required for radio communication, resulting in performance degradation, quality deterioration, information errors or loss, and even blocking the communication. Therefore, it is generally said that the fact that useless radio signals cause the quality of useful radio signals to decrease or damage is called radio interference.

Previously we have an article about t he analysis and solutions of antenna interference in satellite communication, including polarization interference, adjacent frequency interference, forwarding interference, etc. Please click here to read the full article. Today we will focus on analyzing how to interfere with radio from several aspects, such as physical obstacles, weather conditions, electromagnetic interference (EMI), solar activity, atmosphere, and frequency bands. For example, heavy rain can reduce the signal strength of 12 GHz by 20 dB per kilometer. Solutions include using higher frequencies to obtain clearer paths or placing antennas to avoid reflective surfaces and interference sources. Please go ahead for further details.

LHCb collaboration observes ultra-rare baryon decay

Baryons, composite particles made up of three quarks bound together via the so-called strong force, make up the most visible matter and have thus been the focus of numerous physics studies. Studying the rare processes via which unstable baryons decay into other particles could potentially contribute to the discovery of new physics that is not explained by the Standard Model of particle physics.

Maize plants use a volatile gas to fight off pests in densely crowded fields

When maize fields become too crowded, the plants signal each other to boost their defenses. A research team led by Dongsheng Guo of Zhejiang University found that in crowded conditions, maize plants release a volatile gas called linalool into the air. When it reaches neighboring plants, the gas triggers a defensive response in their roots.

Mathematical model reveals how collapsing matter and expanding voids shape universe’s evolution

A University of Queensland researcher has developed a new mathematical model to explain the evolution of the universe which, for the first time, includes collapsing regions of matter and expanding voids.

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