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The ashes of Scotty from Star Trek are aboard the International Space Station – The Verge

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The ashes of the late James Doohan, who played chief engineer Montgomery Scott on the original Star Trek television series, have been aboard the International Space Station for 12 years— and the Times of London has the fascinating backstory of how it happened. Doohan died in 2005 at the age of 85, and his family wanted to fulfill his wish of getting on the ISS.

Official requests to bring Doohan’s ashes on the ISS were denied, but Richard Garriott— one of the first private citizens to travel on the space station— managed to smuggle some of Doohan’s ashes into the space station’s Columbus module. Garriott says he took a laminated a picture of Doohan and some of his ashes and put it in under the floor of the Columbus. He didn’t tell anyone about the scheme— only he and Doohan’s family knew until now.

“It was completely clandestine,” Garriott told the Times. “His family were very pleased that the ashes made it up there but we were all disappointed we didn’t get to talk about it publicly for so long. Now enough time has passed that we can,”

It’s not the first time Doohan’s ashes have made into the heavens. A portion of his ashes were aboard SpaceX’s Falcon 1 rocket in 2008, but that rocket failed minutes after launch. And in 2012, an urn with some of Doohan’s ashes flew into space aboard the SpaceX Falcon 9. According to the Times, Doohan’s ashes have traveled some 1.7 billion miles across space, and have orbited the Earth more than 70,000 times.

Doohan’s son Chris thanked Garriott for smuggling his late father’s ashes aboard the ISS. “What he did was touching—it meant so much to me, so much to my family and it would have meant so much to my dad,” he said.

Years after his death, Scotty is still boldly going… well, you know the rest.

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Three more COVID-19 cases at GRT – KitchenerToday.com

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Grand River Transit is confirming three more COVID cases.

All the affected employees are bus drivers.

Two of them last worked on January 15, while the third was last on the job on Jan. 11.

GRT points out all three are now self-isolating at home.

So far in Janaury, nine employees have tested positive for the virus.

Grand River Transit lists COVID-19 cases on its website for transparency purposes, but some details are not released due to privacy concerns.

Since the on-set of the pandemic, multiple safety precautions have been put in place to protect drivers and riders, including barriers and mandatory masks.

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Microplastics could be eliminated from wastewater at source – E&T Magazine

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A team of researchers from the Institut national de la recherche scientifique (INRS), Quebec, Canada, have developed an electrolytic process for treating wastewater, degrading microplastics at the source.

Microplastics are fragments of plastic less than 5mm long, often contained in toiletries or shedding from polyester clothing. They are present in virtually every corner of the Earth, and pose a particularly serious threat to marine ecosystems. High concentrations of microplastics can be carried into the environment in wastewater.

There are no established degradation methods to handle microplastics during wastewater treatment; although some techniques exist, these involve physical separation as a means of filtering the pollutant. These techniques do not degrade microplastics, which requires additional work to manage the separated fragments. So far, research into degradation of microplastics has been very limited.

The INRS researchers, led by water treatment expert Professor Patrick Drogui, decided to try degrading plastic particles through electrolytic oxidation – a process that does not require the addition of chemicals.

“Using electrodes, we generate hydroxyl radicals to attack microplastics,” Drogui said. “This process is environmentally friendly because it breaks them down into CO2 and water molecules, which are non-toxic to the ecosystem.”

Drogui and his colleagues experimented with different anode materials and other parameters such as current intensity, anode surface, electrolyte type, electrolyte concentration and reaction time. They found that the electrolytic oxidation could degrade more than 58 ± 21 per cent of microplastics in one hour. The microplastics appeared to degrade directly into gas rather than breaking into smaller particles.

Lab-based tests on water artificially contaminated with fragments of polystyrene showed a degradation efficiency as high as 89 per cent.

“This work demonstrated that [electrolytic oxidation] is a promising process for degradation of microplastics in water without production of any waste or by-products,” the researchers wrote in their Environmental Pollution report.

Drogui envisions this technology being used to treat microplastic-rich wastewater emerging from sources such as commercial laundries.

“When this commercial laundry water arrives at the wastewater treatment plant, it is mixed with large quantities of water, the pollutants are diluted and therefore more difficult to degrade,” he explained. “Conversely, by acting at the source, i.e. at the laundry, the concentration of microplastics is higher, thus more accessible for electrolytic degradation.”

Next, the researchers will move on to experimenting with degrading microplastics on water outside the artificial laboratory environment. Real commercial laundry water contains other materials that can affect the degradation process, such as carbonates and phosphates, which can trap radicals and limit degradation. If the technology is effective under these circumstances, the researchers plan to conduct a study to determine the cost of scaling up this treatment to implement in laundries.

Last week, researchers from the University of Barcelona published a study suggesting that encouraging a greater proliferation of seagrass meadows in the shallows of oceans could help trap, extract and carry marine plastic debris to shore.

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Eliminating microplastics in wastewater directly at the source – EurekAlert

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IMAGE: Electro-analytical system used to identify appropriate electrodes for anodic oxidation processes.
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Credit: INRS

A research team from the Institut national de la recherche scientifique (INRS) has developed a process for the electrolytic treatment of wastewater that degrades microplastics at the source. The results of this research have been published in the Environmental Pollution journal.

Wastewater can carry high concentrations of microplastics into the environment. These small particles of less than 5 mm can come from our clothes, usually as microfibers. Professor Patrick Drogui, who led the study, points out there are currently no established degradation methods to handle this contaminant during wastewater treatment. Some techniques already exist, but they often involve physical separation as a means of filtering pollutants. These technologies do not degrade them, which requires additional work to manage the separated particles.

Therefore, the research team decided to degrade the particles by electrolytic oxidation, a process not requiring the addition of chemicals. “Using electrodes, we generate hydroxyl radicals (* OH) to attack microplastics. This process is environmentally friendly because it breaks them down into CO2 and water molecules, which are non-toxic to the ecosystem,” explains the researcher. The electrodes used in this process are more expensive than iron or steel electrodes, which degrade over time, but can be reused for several years.

An effective treatment

Professor Drogui envisions the use of this technology at the exit of commercial laundries, a potential source of microplastics release into the environment. “When this commercial laundry water arrives at the wastewater treatment plant, it is mixed with large quantities of water, the pollutants are diluted and therefore more difficult to degrade. Conversely, by acting at the source, i.e., at the laundry, the concentration of microplastics is higher (per litre of water), thus more accessible for electrolytic degradation,” explains the specialist in electrotechnology and water treatment.

Laboratory tests conducted on water artificially contaminated with polystyrene showed a degradation efficiency of 89%. The team plans to move on to experiments on real water. “Real water contains other materials that can affect the degradation process, such as carbonates and phosphates, which can trap radicals and reduce the performance of the oxidation process,” says Professor Drogui, scientific director of the Laboratory of Environmental Electrotechnologies and Oxidative Processes (LEEPO).

If the technology demonstrates its effectiveness on real commercial laundry water, the research group intends to conduct a study to determine the cost of treatment and the adaptation of the technology to treat larger quantities of wastewater. Within a few years, the technology could be implemented in laundry facilities.

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About the study

The article “Treatment of microplastics in water by anodic oxidation: A case study for polystyrene”, by Marthe Kiendrebeogo, Mahmoodreza Karimiestahbanati, Ali Khosravanipour Mostafazadeh, Patrick Drogui and Rajeshwar Dayal Tyagi, was published in the Environmental Pollution journal. The team received financial support from the Fonds de recherche du Québec – Nature et technologies (FRQNT), the CREATE-TEDGIEER program, the Natural Sciences and Engineering Research Council of Canada (NSERC) and the Canadian Francophonie Scholarship Program (CFSP).

About INRS

INRS is a university dedicated exclusively to graduate level research and training. Since its creation in 1969, INRS has played an active role in Quebec’s economic, social, and cultural development and is ranked first for research intensity in Quebec and in Canada. INRS is made up of four interdisciplinary research and training centres in Quebec City, Montreal, Laval, and Varennes, with expertise in strategic sectors: Eau Terre Environnement, Énergie Matériaux Télécommunications, Urbanisation Culture Société, and Armand-Frappier Santé Biotechnologie. The INRS community includes more than 1,400 students, postdoctoral fellows, faculty members, and staff.

Source :

Audrey-Maude Vézina

Service des communications de l’INRS

418 254-2156

audrey-maude.vezina@inrs.ca

Disclaimer: AAAS and EurekAlert! are not responsible for the accuracy of news releases posted to EurekAlert! by contributing institutions or for the use of any information through the EurekAlert system.

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