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​In a world that seems to be drowning in plastic bottles, recycling this waste into useful materials would help to reduce its environmental impact. KAUST researchers have now invented a way to turn plastic bottles into porous membranes that could be used as molecular filters in the chemical industry.

Roughly 40 percent of the chemical industry’s energy used goes into separating and purifying chemicals in heat-intensive processes, such as distillation and crystallization. Using porous membranes to separate molecules from liquids could dramatically reduce that energy consumption. But most conventional membranes are not robust enough to withstand the sort of solvents used in industry, and alternative ceramic membranes tend to be very expensive.

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Image: Bruno Pulido tests the efficiency of the team's synthetic membrane.
© 2019 KAUST

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This project is the first time that the date palm genome has been studied so comprehensively. Dr. Ikram Blilou, Associate Professor of Plant Science at King Abdullah University for Science and Technology (KAUST) and her research team in Saudi Arabia have collected samples from date palms by the Quba mosque in Madinah, some of the most ancient date palms in the world.

"The date palm is one of the few fruit trees that, remarkably, can grow in the desert, a habitat with an arid climate where extreme temperature changes and drought conditions limit plant growth.

"Within KAUST's Center for Desert Agriculture Research we are studying date palms using advanced genome sequencing techniques and have begun to develop new breeding strategies to help palms grow faster and healthier as well as making them more resistant to pathogens and pests like the red palm weevil," says Dr. Blilou.

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Image: Dr. Ikram Blilou, Professor of Plant Science at King Abdullah University for Science and Technology (KAUST) with members of her research team collect date palm samples from the historical farm Al Dabeta by the Quba mosque in Madinah, the oldest mosque in the world.

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​By using proteins that naturally bind and arrange DNA inside cells, a KAUST-led team has devised a plug-and-play strategy for building stable, custom-designed nanostructures.

The versatile yet straightforward method for designing hybrid DNA-protein assemblages now provides engineers with a nanoscale platform for solving problems in science. “The DNA-protein nanotechnology has potential applications in many fields, including medicine, biotechnology and analytical chemistry,” says KAUST’s Professor Satoshi Habuchi, who led the study.

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Image: This air-plasma (the violet-blue glow) facility was used to treat the sample grids used in electron microscopy.
© 2019 KAUST

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​Use of saline water to irrigate crops would bolster food security for many arid countries; however, this has not been possible due to the detrimental effects of salt on plants. Now, researchers at KAUST, along with scientists in Egypt, have shown that saline irrigation of tomato is possible with the help of a beneficial desert root fungus. This represents a new key technology for countries lacking water resources.

“Salt in irrigation water is one of the most significant abiotic stresses in arid and semiarid farming,” says former KAUST postdoc Mohamed Abdelaziz, who worked on the project team alongside Heribert Hirt. “Improving plant salt tolerance and increasing the yield and quality of crops is vital, but we must achieve this in a sustainable, inexpensive way.”

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Image: Mohamed Abdelaziz (left) and Heribert Hirt aim to improve the salt tolerance of crop plants to enable the use of saline water for irrigation.
© 2019 KAUST

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​On September 26 on the University's campus, 28 startups pitched their ideas to a panel of judges and investors to compete for over 2 million SAR in prize money at the finals of the TAQADAM Startup Accelerator Program.


The program—which is now in its third year—was developed in partnership with KAUST and the Saudi British Bank (SABB) to equip new entrepreneurs with the skills and know-how to launch a technology startup. Since beginning in 2016, the TAQADAM Accelerator has successfully graduated 78 startups and awarded over 9 million SAR in funding.

In line with Saudi Arabia's objectives of supporting new ventures, the TAQADAM Accelerator Program focuses on preparing new entrepreneurs for the challenges ahead, offering over six months of business training and mentorship in various industries, including e-commerce, healthcare and technology, in addition to FinTech, gaming and engineering and science.

Two BESE startup teams were amongst the TAQADAM Accelerator Program winners and each received 375,000 SAR ($100,000):
* Peregrine Genomics: Providing accurate premarital genetic diagnoses in half the time and cost.
* GlucoJet: Non-invasive and pain free glucose testing for diabetes patients.

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​Giant clams take up a large fraction of marine microplastics, which could help explain the mystery of the plastic that is "missing" from the Red Sea.

Researchers at the Red Sea Research Center have shown previously that the Red Sea has relatively low amounts of floating plastic debris in its surface waters, yet the reason for this has remained elusive. Now, they have assessed the role of giant clams as a potential sink for marine plastics, with some surprising results.

Twenty-four giant clams collected from the Red Sea were put into aquariums with plastic beads from 53 to 500 micrometers in size—the size range reported as missing from the Red Sea in a 2017 survey. By measuring the change in microplastic concentration after 12 days and counting the beads in the clams’ digestive system and on their shells, they assessed how much plastic the clams captured.

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Image: Silvia Arossa presents a giant clam similar to those used in the team's investigation.
© 2019 KAUST

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​From raindrops rolling off the waxy surface of a waterlily leaf, to the efficiency of desalination membranes, interactions between water molecules and water-repellent "hydrophobic" surfaces are all around us. The interplay becomes even more intriguing when a thin water layer becomes sandwiched between two hydrophobic surfaces, KAUST researchers have shown.

In the early 1980s, researchers first noted an unexpected effect when two hydrophobic surfaces were slowly brought together in water. “At some point, the two surfaces would suddenly jump into contact—like two magnets being brought together,” says Himanshu Mishra from KAUST's Water Desalination and Reuse Center. Mishra’s lab investigates water at all length scales, from reducing water consumption in agriculture, to the properties of individual water molecules.

Researchers were unable to explain the phenomenon at the molecular level, so in 2016, Mishra organized a KAUST conference on the subject. “We brought together leaders in the field—experimentalists and theorists—leading to intense debates on the understanding of hydrophobic surface forces,” he says.

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Image: Measuring forces between hydrophobic surfaces at molecular resolution pin-points the contribution of the quantum nature of water's hydrogen atoms to the hydrophobic interaction.
2019 KAUST; Xavier Pita

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​The microbial communities in a new type of wastewater treatment system are shaped mostly by local factors, according to new research from Pascal Saikaly’s lab at KAUST. Understanding the microbial ecology of these systems will offer clues to help engineers improve them, a pressing need in the face of urbanization and population growth.

Researchers at the Water Desalination and Reuse Center and their international collaborators used mass balance calculations and gene sequencing to study the microbial communities in an aerobic granular sludge (AGS) system in the Netherlands. Their more efficient treatment means AGS systems, in which bacteria are mostly suspended rather than clumped, are gradually replacing conventional activated sludge systems, but “So far nobody has investigated the microbial ecology of these next-generation wastewater treatment systems,” says Muhammad Ali, the study’s lead author.

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Image: This microbial granular system converts wastewater for urban re-use, such as urban agriculture and landscaping.
2019 KAUST; Xavier Pita

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​Bacterial DNA sequencing analyses show date palms that are cultivated over a vast stretch of the Tunisian Sahara Desert consistently attract two types of growth-promoting bacteria to their roots, regardless of the location. This finding could help with improving crop cultivation in a warming climate.

Many factors influence which growth-promoting bacteria associate with plant roots, including  plant species, plant community diversity, agricultural practices applied and soil type. Research conducted on natural ecosystems shows that different types of wild plants attract different growth-promoting bacteria depending on their needs. Studies on conventional agricultural ecosystems have shown plant-root-bacteria associations vary according to the type of soil and the agricultural practices applied. Another KAUST study recently found that the roots of speargrass growing in the Tunisian desert aren’t picky at all: they attract whatever growth-promoting bacteria they can find in the surrounding resource-poor sand.

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Image: KAUST scientists wanted to know the factors that determine which bacteria associated with the roots of cultivated date palm trees.
© 2019 Ramona Marasco