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How can electronic waste, also known as e-waste, be recycled without resulting in negative environmental impacts that are often produced with traditional e-waste recycling methods? This is what a recent study published in Nature Chemical Engineering hopes to address as a team of researchers from Rice University investigated a novel approach for improving e-waste recycling while mitigating the negative impacts on the environment. This study holds the potential to help researchers, climate conservationists, and the public better understand how they can contribute to a cleaner environment through recycling.

“Our process offers significant reductions in operational costs and greenhouse gas emissions, making it a pivotal advancement in sustainable recycling,” said Dr. James Tour, who is a T.T. and W.F. Chao Professor of Chemistry at Rice University and a co-author on the study.

For the study, the team built upon past research conducted by Dr. Toru involving flash joule heating (FJH), which uses electric currents to break down metals into other materials. Using FJH for e-waste, the researchers successfully removed precious metals, including tantalum, indium, and gallium, which have commercial uses in capacitors, LCD displays, and semiconductors, respectively. Additionally, this new method was found to provide increased efficiency for metal purity and number of metals, also called yield, at 95 percent and 85 percent, respectively, along with significantly reducing environmental harm since this method does not require acids or water for its reaction.

“Our study is a stark example of how air pollution can substantially alter atmospheric chemistry thousands of miles away,” said Jacob Chalif.

How do fossil fuels influence the atmospheric chemistry of the Arctic? This is what a recent study published in Nature Geoscience hopes to address as a team of scientists investigated how air pollution caused by fossil fuels influences levels of methanesulfonic acid (MSA), which is an airborne byproduct of marine phytoplankton. This study has the potential to help researchers, climate scientists, and the public better understand the long-term consequences of fossil fuels and the steps that can be taken to mitigate them.

This study builds on several past studies, specifically a 2013 ice core research study from Denali National Park, that hypothesized reduced MSA levels resulted from drastic reductions in phytoplankton during the same period. However, the researchers ruled out a connection between MSA and phytoplankton populations but were still puzzled about the drops in MSA levels in the Arctic.

Continue reading “Fossil Fuels and the Arctic: Uncovering the Impact of Air Pollution” »

Arizona-based startup Mechnano has exited “stealth mode” in the research and development of its carbon nanotube (CNT) technology for 3D printing materials.

The company has developed its first product, an electrostatic discharge (ESD) resin that delivers dissipative properties to 3D printed parts without compromising mechanical properties.

“These are extraordinary breakthroughs for additive manufacturing materials,” said Steven Lowder, Mechnano’s Founder and CEO. “By focusing on the nanoscale, or the molecular level, we are able to make exponential improvements in AM materials at the macro-level.

NEW YORK — In a groundbreaking development, scientists have created a revolutionary method to track the spread of cancer throughout the body, potentially paving the way for more effective treatments against this devastating disease. The new technology, developed by researchers at Cold Spring Harbor Laboratory and Weill Cornell Medicine in New York, uses genetic “barcodes” to monitor the movement of individual cancer cells, providing unprecedented insights into the process of metastasis.

A group of Korean researchers have recently succeeded in developing new p-type semiconductor materials and thin-film transistors that will lead the innovation of the semiconductor industry. These new discoveries are expected to be widely utilized to improve the overall performance of next-gen displays and ultra-low power semiconductor devices.

South Korea’s Hogreen Air reveals the world’s first hydrogen-powered drone with a 5,800-mile remote range at the H2 MEET conference in Seoul.

A team of chemical biologists at the University of Washington, working with colleagues at Oxford Nanopore Technologies, has developed a protein sequencing process that involves pulling proteins through nanopores in a lipid membrane. Their paper is published in the journal Nature.

Earth will get a “second moon” this weekend, but it won’t be sticking around for long.

In recent years, the scientific community has made significant strides in the field of gene editing, particularly through the development of the CRISPR (Clustered Regularly Interspaced Short Palindromic Repeats) systems. In 2020, the Nobel Prize in Chemistry was awarded to the scientists for the discovery of CRISPR–Cas9 system, a revolutionary genome editing technology that advanced DNA therapeutics. Subsequently, the CRISPR–Cas13 system has emerged as a potential tool to identify and rectify errors in RNA sequences. CRISPR–Cas13 is a novel technology is specifically engineered for virus detection and RNA-targeted therapeutics. The CRISPR RNA (CrRNA) targets specific and non-specific RNA sequences, and Cas13 is an effector protein that undergoes conformational changes and cleaves the target RNA. This RNA-targeting system holds tremendous promise for therapeutics and presents a revolutionary tool in the landscape of molecular biology.

Now, in a recently published BioDesign Research study, a team of researchers led by Professor Yuan Yao from ZJU-Hangzhou Global Scientific and Technological Innovation Center, Zhejiang University, China has elucidated the latest research trends of CRISPR–Cas13 in RNA-targeted therapies. Talking about this paper, which was published online on 6 September 2024, in Volume 6 of the journal, Prof. Yao says, “By focusing on RNA-;the intermediary between DNA and proteins-;CRISPR-Cas13 allows scientists to temporarily manipulate gene expression without inducing permanent changes to the genome. This flexibility makes it a safer option in scenarios where genome stability is critical.”

RNA plays a central role in carrying genetic information from DNA to protein-synthesizing machinery, and also regulates gene expression and participates in numerous cellular processes. Defects in RNA splicing or mutations can lead to a wide variety of diseases, ranging from metabolic disorders to cancer. A point mutation occurs when a single nucleotide is erroneously inserted, deleted, or changed. CRISPR–Cas13 plays a role in identifying and correcting these mutations by employing REPAIR (RNA editing for programmable A-to-I replacement) and RESCUE (RNA editing for specific C-to-U exchange) mechanisms. Explaining the applications of Cas13-based gene editors, Prof. Yao adds, “The mxABE editor, for example, can be used to correct a nonsense mutation linked with Duchenne muscular dystrophy that can be corrected with mxABE. This approach has proved high editing efficiency, restoring dystrophin expression to levels more than 50% of those of the wild type.”