FEATURES On Miles, Blu & Exile Strengthen Their Chemistry and Revisit Their Roots By Danny Schwartz July 07, 2020

On Dancing in the Rain, from Blu & Exiles 2007 debut album Below the Heavens, rapper Blu describes a symbolic act of defiance. He clocks out of work in a rainstorm and discovers that hes short on bus fare. In response to this stroke of bad luck, he turns up his headphones, kicks off his shoes, and stomps gleefully in the puddles near the bus stop. This spiritof a resilient working-class bluesman, navigating the ups and downs of everyday lifeanimates Below the Heavens, which today remains a pillar of backpack rap, a union of two dedicated classicists who werent trying to reinvent the wheel but ended up paving their own lane. On Miles: From An Interlude Called Life, their first full-length album in eight years, Blu & Exile stay true to their roots.

Exile builds his boom-bap beats around soul and jazz loopsTony Bennett, cool-era Miles Davis, Philadelphia souland Blu delivers the striving, aspirational energy of a rap romantic whos been down and out without a dollar for food. The albums title pays tribute to Miles Davis, of course, as well as Blu & Exiles winding journeys, both together and apart. It felt like we had been miles away from where we started, and it felt like we had a lot to say about all those miles that weve traveled since weve begun, Blu says. Just miles carries multiple meanings, the albums themes surface in part through repetition of keywords, like black and blue. As Blu filters his identity as a Black man through familial and historical lenses, Miles comes into focus.

Blu and Exile started piecing together a trap album in 2015 by trading beats and verses over email. They scrapped it in 2017. It wasnt as genuine, especially for our fan base, Blu explains. I was being a little more experimental, which Im known to be with some of my projects. We decided to go back to the drawing board. We went back to our old music. They began on the album that would become Miles with a more intentional, in-person form of collaboration. They cut 40 songs in all for the project. We were kind of disconnected as friends, he says. We were still working, creatively, but once we built back on our friendship again, it built back on our chemistry to be able to create an album that we love.

Miles is a spacious, 20-track double album that gives Blu time to take several lengthy strolls down memory lane, through his childhood in South Central Los Angeles. Together, these memories offer a clear window into Blus upbringing and the preconditions for his rap career, which he believed would deliver him from his familys financial struggles. Rap and family are intertwined; on Music is My Everything, he recalls how his cousin taught him what a bassline was, and other pearls from his early musical education, like, Memories of Eazy-E when I was 3, my auntie dated him, my papa would bang him on the way to the beach. On Blue As I Can Be, he remembers, First song I ever recorded felt important, I had to paint my portrait enormous. That early idealism continues to color Blus music today.

On Miles, Blu places his personal history alongside a much broader Black history, as he draws himself into a lineage that predates civilization and extends back to the first humans, who lived in Africa, and their diaspora. (More miles than Africans into Asia.) On Roots of Blue, the albums nine-minute centerpiece, he rattles off a dizzying list of namesEgyptian gods, characters from the Bible, key 20th century Black figures like James Baldwin, Jackie Robinson, and Elijah Muhammad, and everyone else creating Black history that lives with me every day. Blu scribbles lists like these across Miles, giving shout outs to everyone from legendary Black artists to Africans shipped over on the Middle Passage to present-day victims of police violence. The breadth of these references affirms a fundamental Black bond, a connection between Blu and every Black human who has ever lived. Black skin, he raps on African Dream, black bones, Black man from the Black planet, black sand, black lamb. Referencing back to our roots, basically, is just a way of reflecting and going back miles, he says on the phone. And I went back as far as I could go, really.

Blu has worked extensively with many producers, including Flying Lotus and Madlib, but he is still most closely associated with Exile. The two of them agree that their friendship is the foundation that has allowed their musical partnership to endure. Exile calls himself and Blu two artistic brothers. Weve been through a lot of things that pulled us apart and brought us back together, he muses.

I think it gets easier as we go, Blu adds. The older we get, the closer we get to understanding each other. The music becomes easier to make.

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Most universities plan to start the new academic year with a combination of remote teaching and socially distanced face-to-face experiences for practical and other key elements. But a new survey has found that prospective students have a raft of concerns.

According to a poll of 516 prospective students for the Universities and Colleges Union (UCU), almost half fear funding cuts, as a result of the pandemic, will damage their education, and just under a quarter worry that that their university will go bust. Significantly, over two-thirds support a delayed start to the year if it means more face-to-face teaching. The survey follows another in May that found 17% more students than usual were considering deferring in the new academic year.

It is hardly surprising that students are anxious, says UCU general secretary Sally Hunt. It is now critical that government agrees to provide increased financial backing. No university should jeopardise the safety of staff or students to try and offer a more traditional university experience. Government needs to guarantee funding so institutions [can] put welfare first, and plan for a delayed start if this is the safest course of action.

Budgetary pressures are nothing new for chemistry departments. Heads have spent the past few years looking at ways to diversify income, improve efficiency and share resources, and this process will continue post-pandemic, says Lizzy Ostler, spokesperson for the Heads of Chemistry UK (HCUK). Chemistry departments are collaborating on finding the best ways to ensure that students continue to experience excellent teaching. But delayed starts are unlikely, as departments couldnt compress content into a shortened year with a late start date, and a January start would require teaching undergraduates into the summer, which could interfere with postgraduate and research students work.

However, Ostler would like to reassure new students. HCUK is in the early stages of reorganising courses to ensure high-class theoretical and practical learning opportunities but its confident that the value of a degree, and associated experiences, will be maintained.

Emma Raven, head of the chemistry department at the University of Bristol, also strikes an optimistic note. Some of the blended learning approaches proposed for the 2020 entry have been well received because they allow students to learn at their own pace. So there are clear advantages. She also notes that universities managed the transition to online exams well. So I have confidence that the academic offerings in chemistry in the autumn will be modern, interesting and of high quality.

However, Nick Hillman, director of the Higher Policy Education Institute, is worried about university finances. Sciences do risk being in line for cuts because they are so often cross-subsidised by things like international student fees, which are currently under threat. Universities are looking at making redundancies but they are also talking to government about additional support and thinking creatively about ways to tackle short-term cash flow challenges.

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Prospective students anxious over financial future at UK universities - Chemistry World

The research report on Textile Chemical market provides vital data regarding the consumption rate as well as revenue projections of this business landscape. Based on production patterns, the study comprises of crucial details such as the gross remuneration and manufacturing processes of the industry players. The unit cost deployed by these companies across various regions during the analysis timeframe is also stated in the document.

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The worldwide lockdown as a result of COVID-19 pandemic has not only led to economic slowdown but also halted the operations of numerous enterprises as well as manufacturing facilities. Moreover, inadequate supply of raw materials and scarcity of labor workforce owing to the disease outbreak are estimated to result in alterations in the growth of Textile Chemical market in the subsequent years.

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A new study shows for the first time that the collapse of terrestrial ecosystems during Earths most deadly mass extinction event was directly responsible for disrupting ocean chemistry.

The international study, led by the University of Leeds, highlights the importance of understanding the inter-connectedness of ecosystems as our modern environment struggles with the devastating effects of a rapidly warming planet.

The Permian-Triassic extinction, also known as the Great Dying, took place roughly 252 million years ago. It saw the loss of an estimated 90% of marine species, 70% of land species, widespread loss of plant diversity and extreme soil erosion.

While the exact cause of the terrestrial mass extinction is still debated, it is becoming apparent that the terrestrial ecosystems were wiped out prior to the marine ecosystems. However, until now it was unclear if or how the terrestrial extinction consequently impacted the chemistry of Earths ancient oceans.

The team built a computer model that mapped chemical changes in Earths oceans during the period of the Permian-Triassic extinction. The model tracks the cycling of the poisonous element mercury, which is emitted from volcanoes but also gets incorporated into living organisms. By tracing both the mercury and carbon cycles, and comparing to measurements in ancient rocks, the team were able to separate out biological and volcanic events.

This revealed that a massive collapse of terrestrial ecosystems cascaded organic matter, nutrients, and other biologically-important elements into the marine system.

While further research is needed to understand the exact effect this had on marine life, the fact that many marine species rely on chemical stability in their environment means that it is unlikely it was without consequence.

Study co-author Dr. Jacopo Dal Corso, who conceived the study during a research placement at Leeds said: In this study we show that during the Permian-Triassic transition, roughly. 252 million years ago, the widespread collapse of the terrestrial ecosystems caused sudden changes in marine chemistry.

This likely played a central role in triggering the most severe known marine extinction in Earths history. This deep-time example shows how important the terrestrial reservoir is in regulating global biogeochemical cycles and calls for the greater conservation of these ecosystems.

Study co-author Dr. Benjamin Mills, from the School of Earth and Environment at Leeds said: 252 million years ago the effects of mass plant death and soil oxidation appear to have seriously altered the chemistry of the oceans. This is an uncomfortable parallel with our own human-driven land use change, and we too are transferring large quantities of nutrients and other chemicals to the oceans.

As we look to re-start the worlds economies in the wake of the current pandemic, protecting our life-sustaining ecosystems should be a priority.

Reference: PermoTriassic boundary carbon and mercury cycling linked to terrestrial ecosystem collapse by Jacopo Dal Corso, Benjamin J. W. Mills, Daoliang Chu, Robert J. Newton, Tamsin A. Mather, Wenchao Shu, Yuyang Wu, Jinnan Tong and Paul B. Wignall, 11 June 2020, Nature Communications.DOI: 10.1038/s41467-020-16725-4

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New Insight Into the Great Dying Earths Most Deadly Mass Extinction Event Disrupted Ocean Chemistry - SciTechDaily

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The chemical factory in the Indian state of Gujarat, where a boiler blast on June 3 killed eight workers and injured 50 others, is insured for more than 3.1 billion Indian rupees ($41 million), The Times of India reported citing sources. The factory owner Yashasvi Rasayan Pvt. Ltd. has an industrial all risk policy of INR 2.6 billion for property damage and INR 500 million for business interruption, with The New India Assurance Co. Ltd. being the lead insurer.

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Blasted chemical factory insured for more than $40 million - Business Insurance

The temporary restraining order (TRO) granted by Judge R. Brooke Jackson applies to the City and County of Denver, and specifically the Denver Police Department and those assisting the department.

The ruling came after four Denver residents who participated in demonstrations following the death of George Floyd, filed a complaint Thursday challenging the Denver Police Department's use of chemical agents and rubber projectiles during protests.

The plaintiff's allege in some cases the Denver Police Department "violated their First Amendment right to free speech and their Fourth Amendment right against excessive force by using pepper spray, pepper balls, rubber bullets, flashbang grenades, and tear gas to punish plaintiffs for demonstrating against police brutality."

"In issuing this relief I do not seek to prevent officers from protecting themselves or their community," Jackson said in the ruling. "I seek to balance citizens' constitutional rights against officers' ability to do their job. However, the time is past to rely solely on the good faith and discretion of the Denver Police Department and its colleagues from other jurisdictions."

Restrictions on use of projectiles and chemicals

Under the temporary restraining order, only on-scene supervisors holding the rank of Captain or above are allowed to authorize the use of non-lethal projectiles and chemical agents such as tear gas and pepper spray after personally witnessing "specific acts of violence or destruction of property."

Jackson also included additional stipulations for the use of the non-lethal projectiles and the chemical agents by officers. They include:

Kinetic Impact Projectiles ("KIPs") and all other non- or less-lethal projectiles may never be discharged to target the head, pelvis, or back.

KIPs and all other non- or less-lethal projectiles shall not be shot indiscriminately into a crowd.

Non-Denver officers can not use any demonstration of force or weapon beyond what Denver itself authorizes for its own officers. Any non-Denver officer permitted to or directed to be deployed to the demonstrations shall be considered an agent of Denver and the city can ensure the officer is limiting their use of force to that which is authorized.

All officers deployed to demonstrations must have their body-worn cameras recording at all times, and they may not intentionally obstruct the camera or recording.

Chemical agents or irritants (including pepper spray and tear gas) may only be used after an order to disperse is issued.

Any and all orders to disperse must be followed with adequate time for the intended audience to comply, and officers must leave room for safe egress. If it appears that the intended audience was unable to hear the order, the order must be repeated prior to the use of chemical agents or irritants.

Request for modifications

Following the ruling, the Denver Police Department said in posts on Twitter that it would comply with the order, but is asking the judge for some modifications.

"A federal judge issued a Temporary Restraining Order (TRO) clarifying #DPD use of non-lethal dispersant devices. In the meantime, we will comply with the judge's directions, many of which are already in line with our community-consulted Use of Force Policy," the post said. "We are asking for modifications to the Order that would account for limitations on staffing and body-worn cameras so the directions can be operationalized."

On Friday night, the city and county of Denver filed an emergency motion for modification of the temporary restraining order.

The motion asked the court to allow officers at the rank of lieutenant to authorize the deployment of chemical agents or projectiles in response to specific acts of violence or destruction of property because of limitations in staffing.

"This is not feasible under the command structure of the Denver Police Department because currently there are only four police officers with the rank of Captain and one Commander responsible for the downtown area," the motion said.

The motion also requested to eliminate the requirement regarding the body cameras, claiming the order would prevent the department from receiving assistance from other agencies that do not have body cameras. The city also cited technical limitations of the body cameras as another reason for eliminating the requirement.

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Temporary restraining order prohibits Denver Police from using chemical agents or projectiles against peaceful protesters without supervisor approval...

Under regular circumstances, the Department of Chemistrys Instrumentation Facility (DCIF) is a 24/7 operation that services nearly 100 individual research labs from not only the MIT community, but external universities and corporations alike, at a rate of approximately 300 users a month. In 2018, the DCIF benefited immensely from the generous support of alumni and friends who contributed to a fundraising drive to replace and renewoutdated equipment in the facility.

When the Covid-19 pandemic forced all on-campus activity to come to a screeching halt last March, the stewards and staff of the DCIF were faced with the challenge of quickly adapting their policies and procedures to accommodate the newly instituted guidelines for safely working at a social distance, all while preventing contamination.

Addressing contamination potential

Walt Massefski, the DCIF director, worked with his staff Operations Manager John Grimes, Research Scientist Mohan Kumar, and Research Specialist Bruce Adams to implement the necessary changes to day-to-day activities in the subbasement of the Dreyfus Building. First, the group took into consideration the two types of contamination they were facing: airborne contamination, the result of virus that is exhaled by an infected individual traveling through the air to another individual, and is minimized by proper use of masks and social distancing; and touch contamination, the result of an infected individual either breathing on or touching a surface (door handle, keyboard, and the like) and another individual touching that surface and subsequently touching their eyes, nose, or mouth.

We developed our plan to limit airborne contamination by strict adherence to MITs mask and social distancing guidelines: Masks must be worn by all individuals in the lab at all times, and all individuals must stay six feet from each other (if two people can extend their arms and touch fingertips, they are too close), says Massefski. We also designed our lab-use plan to meet the time and space guidelines instituted by the vice president for research: no more than one person in every 160 square feet of lab space, and no more than 10 minutes in that space at one time.

The considerable size of the DCIF and the need for the seven nuclear magnetic resonance (NMR) instruments it houses to social distance, even when there isnt a pandemic made the distance guidelines relatively easy to meet in the NMR space. The facilitys mass spectrometry space, on the other hand, was another story.

During Phase 1, we significantly restricted the use of the mass spectrometry part of the lab, explains Massefski. During Phase 2, we have adopted a rotating reservation system for the instruments that are close to each other.

We developed our plan to limit touch contamination based on a double-barrier model that I learned while working at an MIT-affiliated molecular diagnostics startup earlier in my career; users of the lab must wash their hands when they arrive in the lab, don a fresh pair of gloves, and keep those gloves on while they are in the lab, says Massefski. Gloves are discarded as users exit the lab. Since everyone in the lab is wearing gloves (and a mask), accidental touch contamination for any reason by one individual is limited to the surface, and not transferred to the next individual, hence the double-barrier. By washing when you arrive, you limit the possibility that you will carry virus from outside the lab to the inside the lab; by wearing gloves inside the lab, you limit the possibility that you will carry virus from inside the lab to outside the lab, again a double-barrier approach. While we hope that no one enters the lab infectious, these steps, along with regular surface cleaning, are the best approach we can think of to maximize transmission control.

Implementing these new policies involved extensive communication between the DCIF lab and lab staff and users of the lab. Massefski and his team sent out a number of detailed email notifications, and developed signage to remind everyone of the important steps to take for transmission control. To their credit, the facilitys users were happy to follow the new processes. Users have been respectful of the importance of ensuring a safe work environment for all, and receptive of reminders to wash hands and wear gloves in the instance of a user forgetting the newly instated policies.

The difficulty has been for me to keep in mind some of the policies in my daily workflow, says John Grimes, the DCIFs operations manager. A large amount of my time is spent interacting with students, be it to answer their questions or train them to use our instruments. When I am trying to show them how software works, or how to load their samples in a robot, doing so from a two-meter distance can be challenging. It is easy for both of us to end up closer than that. I must constantly remind myself and them that we cant both lean in at the same time to see what it is I am talking about.

Adjusting to the new normal

Throughout this ordeal, the DCIF staffs priority has been to continue to train young scientists and make key resources available to them in the social distancing and restricted-access environment. The group relied on their honed skills of both applying software automation to instrument access and managing a complex, computer-driven lab.

As a shared facility, we used to get more users, interesting discussions, and it was always a really busy place, says research scientist Mohan Kumar. The new guidelines can make it feel like we are not doing science and not working in the lab.

However, despite how things may feel, the lack of population in the lab itself has no bearing on its scientific productivity. All of the facilitys systems are networked, so from the inception of the lab, the systems were built in such a way that that chemists could access their NMR and MS data as easily from home as they could from their lab.

Because of this, when the pandemic hit, the DCIF was mostly ready to meet data-access needs. At the start of Phase 1, they rapidly designed and implemented remote automation tools so that someone could drop samples at the door of the lab, or the building, or at a remote location, and a DCIF staff member could efficiently add those samples to running NMR queues. They developed processes in which users of the DCIF high-resolution mass spectrometers could spend a few minutes in the lab adding samples to the instrument platform, then work remotely to acquire essential data from these samples, limiting the amount of time they actually spent in the lab.

Now that the campus has entered Phase 2, the DCIF staff and stewards have extended their ability to effectively conduct new-user trainings using a combination of video and slide presentations, as well as providing instrument access over a Virtual Network Computing or remote desktop connection and a Zoom link. Massefski credits the facilitys trial-by-fire implementation of Phase 1 protocols as being instrumental in helping his staff smoothly transition into the Phase 2 regulations. Mirroring the Institutes policies, the facility had to learn to walk in a Covid-19 society before it could run.

We gave significant thought to how we would prepare for a research reopening during the shutdown, including conversations with colleagues from labs all over the world to hear their advice about best practices, says Massefski. Since the shutdown was fairly extensive, we had plenty of time to consider the advice of others and to think about how the social distancing restrictions might impact lab operations. Once the details of the VPR guidance were available, we were able to put a proposal out to the department and our faculty advisor, chemistry professor Mo Movassaghi. His experience as advisor for the lab has been invaluable, and he was a touchstone for our transition to Phase 2.

In addition to taking on contamination control training in the lab, staff members took on the task of receiving requests from users to run samples or carry out
experiments that they would normally have done themselves. Massefski remarks, Considering the size of our user base, even at the 25 percent level at which that labs were operating in Phase 1, this became a considerable effort. The DCIF staff contributed an outstanding level of skilled communication and professionalism in handling these requests. Though the DCIF staffs work is ongoing, and the effects of the pandemic are far from over, the results of their efforts are both impactful and sincerely appreciated.

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Instrumentation in a pandemic: How the Department of Chemistry Instrumentation Facility rapidly adapted to Covid-19 - MIT News

The Vadodara-based company has fixed the price band of the IPO at Rs 338-340 per share.

The Rs 318 crore IPO of Chemcon Speciality Chemicals, a manufacturer of specialized chemical products, will open for bidding on Monday i.e. September 21. The issue will be open between September 21 and September 23. The Vadodara-based company has fixed the price band at Rs 338-340 per share.

The book-building IPO of Chemcon Speciality Chemicals comprises fresh issuance of equity shares amounting to Rs 165 crore and an offer for sale of up to 45 lakh equity shares by the promoters.

The IPO will have a lot size of 44 shares. Investors will be eligible tobid for a minimum 1 lot of 44 shares and in multiples thereof, up to 13 lots. The minimum application money for retail investors willbe Rs 14,960, at the upper price band.

Ahead of the public offering, Chemcon Speciality Chemicals raised more than Rs 95 crore from 13 anchor investors, including the likes of IDFC Mutual Fund, ICICI Prudential Mutual Fund, IIFL, HSBC Global and Mirae Asset Mutual Fund.

The company plans to utilise the fresh issue proceeds to expand its manufacturing facility, fund working capital requirements and for general corporate purposes. It will, however, not receive any proceeds from the offer for sale as that would go to selling shareholders.

Chemcon Speciality Chemicals is a leading manufacturer of specialised chemicals such as HMDS (Hexamethyldisilane) & CMIC (Chloromethyl isopropyl carbonate), which are used in the pharma industry.

The company's key domestic customers include Laurus Labs, Aurobindo Pharma and Ind-Swift Laboratories. It also exports to overseas markets including the US, Germany, Italy, South Korea, Japan and Russia, among others.

Link Intime India is the registrar of the IPO, whereas Intensive Fiscal Services and Ambit Capital are the book running lead managers.

Read the original:
Chemcon Speciality Chemicals IPO To Open On September 21. Key Things To Know - NDTV Profit

GREENSBORO, N.C., June 01, 2020 (GLOBE NEWSWIRE) -- NOVA Thin Film Pharmaceuticals LLC (NTFP) announced today its formation and the commencement of its soluble thin film operations. NTFP is commercializing its patented DepoFilm technology. NTFP is based in North Carolina with a research and development facility in Greensboro and manufacturing in Wilmington. NTFPs manufacturing is located at Quality Chemical Laboratories (QCL)s state of the art manufacturing and laboratory facilities in Wilmington. QCL is also a lead investor in NTFP.

NTFPs Chief Executive Officer, Joseph Fuisz, commented: NOVA Thin Film is founded on a simple premise: that existing film technology is too complex and too costly to meet market needs. Thin film offers valuable benefits to patients and NOVA Thin Films superior technology will address formulation, scale up and cost challenges.

Patented DepoFilm represents thin film technology 2.0. DepoFilm addresses the challenges in conventional wet-cast thin film, and enables entirely new product concepts not possible with conventional technologies. This makes NOVA Thin Film the partner of choice for the industry.

NOVA Thin Film starts with the right film technology, the right manufacturing partner, the right investors and the right Board of Directors. These advantages, coupled with management execution, will drive value for NOVA Thin Film and its partners.

Madhu Hariharan, NTFPs Chief Operating Officer, stated:

DepoFilm technology has game-changing implications for soluble film drug delivery. It allows for rapid prototyping and shortened product development timelines with more efficient API usage. The added advantage of a low cost and high yield manufacturing process makes DepoFilm a compelling and disruptive innovation.

Our partnership with Quality Chemical Laboratories has provided the capital, facilities and know-how to enable us to provide world-class production and analytical capabilities from day one. We are immediately positioned to deliver value for ethical, generic and consumer healthcare companies.

Richard C. Fuisz, M.D., the noted drug delivery inventor and entrepreneur credited with pioneering two novel dosage form classes, orally disintegrating tablets and oral soluble film, serves on our Board of Directors. Dr. Fuisz is, together with Joseph Fuisz, the inventor of our issued DepoFilm patents.

Dr. Fuisz remarked: The beauty of DepoFilm lies in its elegant simplicity, and the move of thin film manufacture into a single stage integrated manufacturing process from film formation to final primary packaging, together with the virtual elimination of yield issues that have bedeviled wet-cast manufacturers. This new effort represents an important contribution to drug delivery.

Dr. Yousry Sayed is the founder and Chief Executive Officer of QCL. QCL is NTFPs partner and lead investor. Dr. Sayed has joined the Board of Directors. QCL provides cGMP manufacturing facilities and world class laboratory and quality capabilities to NTFP.

Dr. Sayed stated: We are delighted to enter into partnership with NOVA Thin Film as an investor and also a provider of manufacturing and laboratory services. NOVA Thin Film is based on a unique technology platform that offers a great benefit to drug companies and patients. We are pleased to partner with NOVA Thin Film and excited about what this investment will mean for Wilmington and patients near and far.

About NOVA Thin Film Pharmaceuticals LLC (NTFP): NTFP is a drug delivery company focused on commercializing thin film pharmaceutical products using its patented DepoFilm technology. NTFP is based in North Carolina, with facilities in Greensboro and Wilmington. Learn more at http://www.novathinfilm.com, or contact us using info@novathinfilm.com.

Excerpt from:
NOVA Thin Film Pharmaceuticals and Quality Chemical Laboratories Announce Partnership in Formation and Commencement of Soluble Thin Film Operations -...

To the untrained eye, the photograph looks likea riot of colours and shapes, in the vein of abstract art.

Itis art and it's also science, a literal snapshot of Stephanie Gallant's chemistry research at Memorial University, that's now on digital display and up for public votingas part of a national contest of scientific research images.

But what exactly is the jumble?

"You're looking at crystals, and it might not seem like crystals like we think, becausethey're on a very different size scale, but they are crystals," said Gallant.

The crystals,made of cobalt, iron and oxygen, are almost unimaginably small, ranging between 60 to 500 nanometres a poppyseed is 10,000 times the size of the largest of them.

Gallant made the tiny, magnetic nanoparticles in a lab, as part of her research work in materials chemistry, andeven she grapples with their size.

"Ican barely visualize it, because it's something we wouldn't be able to see with our naked eye on that scale," she said.

Lucky for her, and the wider world of science, there is an instrument that can visualize it: a scanning electron microscope.Gallant used one to capture the image, and then she took some artistic licence to make the particles visually pop with teal, pink and mustard hues.

"It's falsely coloured. The images that come from the scanning electron microscope are black and white," she told CBC Radio's Weekend AM.

"That's kind of the artistic part of what I've done, is that I've digitally coloured it afterwards, trying to highlight the different shapes that you see."

The colourshelp her and other scientists distinguish between the different forms of the crystals.Those shapes form part of Gallant's research, as she delves into why the crystals, which all have the same chemical composition, take on different shapes.

Regardless of size, they all serve a purpose as a material chemist, Gallant works to find practical uses for various creations.

"Believe it or not these beautiful little crystals can actually be used for sensing of pollutants," she said.

Gallant hadlong hoped to submit an image tothe Science Exposed contest, run by the federal Natural Sciences and Engineering Research Council of Canada.

"I've been following this contest for years, just out of interest. Ilove art, Ilove science, and it's the perfect in-between of the two," she said.

The contest aims to showcase scientific research across Canada, and doubles as an artistic exhibition forbiologists, physicists, chemists and anyone working in the field.

"There's something visually interesting in every science, Ipersonally think, and you can see that in the contest entries," said Gallant.

Images from 2020 include a closeup look at a bee's compound eye, a fluorescent ovarian tumour biopsy sample, and the spiky balls within a lithium ion battery.

"It gives a little glimpse into what we do every day," said Gallant.

"As a chemist, I know not everyone knows what people in chemistry do every day, so it's a nice little piece of that to explain, this is what I spend my time doing, and this is what it could be used for."

Voting for the contest, which runs until Sept. 13, takes place on the Science Exposed website.

Read more from CBC Newfoundland and Labrador

More:
Striking photo by MUN chemist in national contest that celebrates the art of science - CBC.ca

Residents from Long Beach to Orange County noticed a strange odor in the air on Thursday, Sept. 10 the result of a chemical spill near Compton, officials said.

Workers cleaning by an oil well in the 200 block of Alsina Street in Los Angeles knocked over a tank of liquid mercaptan, a non-toxic chemical used to add a detectable smell to natural gas and other hazardous materials, at about 11:15 a.m., Los Angles County Fire Department officials said.

The substance gave off an odor as it evaporated and was blown south.

Its highly concentrated in its liquid form, said Marvin Lim, a Fire Department spokesman. It went up into the air, and the winds carried it.

The odor could be smelled throughout the region, as far away as Anaheim and Buena Park, officials in those cities said.

Although only two gallons of the chemical was spilled, it can be quite pungent, Fire Department inspector Sean Ferguson said. It has a rotten egg or skunk smell to it.

People were able to smell it over a wide area, Ferguson said. It got picked up over the winds, so we had folks in scattered pockets getting a smell of this, calling 911 thinking it was a gas leak.

Fire officials helped mop up the chemical.

The odor did not pose any health risks, but those with sensitive senses of smell were advised to stay indoors until it dissipated.

Excerpt from:
Strange odor in Long Beach and Orange County from chemical spill in LA - OCRegister

Credit: Yang H. Ku/C&EN

Many chemistry professors teach name reactions in their undergraduate organic classes.

Scientists have been naming ideas, theorems, discoveries, and so on after other scientists for a very long time (Newtons laws of motion, anyone?). Chemists are no different. Theyve been naming reactions after each other since about the early to mid 1800s. Nowadays, organic chemists in particular use them as a kind of shorthand. However, because the majority of name reactions honor white men, some organic chemists wonder if using these names is exclusionary. In the latest episode of Stereo Chemistry, host Kerri Jansen and reporter Leigh Krietsch Boerner hear from a plethora of organic chemists on how reactions get named, who theyre named after, and whether the practice should stop.

Share your thoughts with us on Twitter! Tweet at us @cenmag, @absoluteKerri, and @LeighJKBoerner, using the hashtag #namereactions.

Read about the 2020 class of C&ENs Talented 12 at cenm.ag/t12.

Register for C&ENs Futures Festival at FuturesFestival.org.

Subscribe to Stereo Chemistry now on Apple Podcasts, Google Play, or Spotify.

The following is the script for the podcast. We have edited the interviews within for length and clarity.

Maria Gallardo-Williams: All the name reactions that we teach in organic one and organic two are named after all white men. So I find that very discouraging to women in the field or people of color in the field because it looks like nobodys ever going to name a reaction around your name.

Kerri: That was Maria Gallardo-Williams, an organic chemistry teaching professor from North Carolina State University. Shes describing a cultural practice in chemistry that has increasingly come under scrutinynaming certain chemical reactions after the scientists who discovered them, or someone who advanced the technique in a significant way. We call these name reactions. For example, the Grignard reaction, the Swern oxidation, or the Diels-Alder reaction. These names are widely used, but chemists have raised concerns that the highly visible roster of reaction names doesnt reflect the current demographics of the chemistry community. And these scientists question whether the culture of name reactions is serving chemists well.

Maria Gallardo-Williams: I mean its subtle, right? Its not, it shouldnt be a big deal. It shouldnt be a big deal, but it is a big deal.

Kerri: It turns out chemists have a lot of different perspectives on this particular issue, which were going to delve into in this episode of Stereo Chemistry. Im your host, Kerri Jansen. And Ive asked C&EN reporter Leigh Krietsch Boerner to join us, since shes the organic chemistry expert around here. Hi, Leigh.

Kerri: So I know that youve been talking to a lot of chemists about this subject over the last few weeks. What have you learned?

Leigh: Well, what really brought this to my attention was actually a Twitter thread started by Maria, whom we heard at the beginning of this episode. In early June, she posted about how shes trying to include more references to Black chemists in her teaching, to balance out the mentions of reactions named after white men. Mark Levin, an organic professor at the University of Chicago, jumped in to say that maybe organic chemists should remove names of scientists from undergraduate organic classes altogether. The thread then quickly turned to whether using name reactions is elitist or exclusionary, what the purpose of them is, and if the practice should continue. If Im remembering correctly, the phrase Death to named reactions was used.

Kerri: Well definitely link to that thread if you want to read more. But it sounds like there are some strong opinions about this.

Leigh: Yeah. I talked to almost 20 people, including several organic chemists that well hear from in this episode, and their perspectives were all over the board. And its actually kind of a sensitive subjectnot everyone is super into talking about this. But I was able to get a sense of what some of the key concerns are around name reactions, and what people think their future should be.

Kerri: Lets start with some background. How did this practice get started of naming reactions after people?

Leigh: Well a reaction is usually named after the person who discovered it or developed it. So one reason chemists started this practice was to honor a contribution to chemistry. This goes back to the mid 1800s, although its pretty hard to pin down what the first name reaction was.

Today, there are hundreds of these things. The Merck Index, a huge authoritative collection of chemicals, drugs, and biologicals, lists about 470 name reactions. But then I found out about a 3,800-page tome called the Comprehensive Organic Name Reactions and Reagents. The author, Zerong Daniel Wang, told me there are around 675 name reactions, although hes getting ready to put out a new edition, and hes going to add even more.

Kerri: So organic chemists learn 675 reactions?

Leigh: No. Thats a bit nuts. But some organic chemists have probably around 300 or so memorized.

Kerri: Thats still a lot of things to memorize.

Leigh: It is. But when practicing organic chemistry, its useful to have a shorter way to help simplify what might be a complicated chemical transformation. So instead of talking about it like a 3,3 sigmatropic rearrangement of an allyl vinyl ether, you can just say Claisen rearrangement.

Kerri: Right. Thats definitely easier.

Leigh: Exactly, and thats another big part of why the use of name reactions is so widespread. I spoke with Vy Dong, an organic professor at the University of California, Irvine, to learn more about how name reactions are used.

Vy Dong: Its a sort of language when you say, you know, performed an asymmetric Sharpless epoxidation. There, in just three words, you pretty much have conveyed a ton of information to the other person youre speaking to.

Leigh: Vy says she does use name reactions in her classroom and lab, but shes not super formal about them.

Vy Dong: I think for me, I dont expect students to just sit down and memorize the named reactions. But I say that its a really handy way to make an extra connection in your brain to something thats maybe more personal, more human. You know, I do remember meeting Kulinkovich, and trying to learn to pronounce his name exactly. Learning about his named reaction, introducing him at a talk. And now, like, Ill never forget the Kulinkovich reaction.

Kerri: Which is making cyclopropanol derivatives with a Grignard reagent and an ester over a titanium (IV) isopropoxide catalyst.

Leigh: Of course. Now, some other people I spoke with noted that being able to connect a name reaction with a face is maybe less useful for beginners in organic chemistry, who may not have ever heard of these people before. For students, knowing name reactions may be more about showing that they should be taken seriously as chemistry students.

Amanda Bryant-Friedrich: It was in my head all of my academic career. And of course, I perpetuated that with my own students by telling them, you need to know the names of these reactions, because that is how youre going to show people that youre competent, and that you understand organic chemistry.

Leigh: Thats Amanda Bryant-Friedrich, professor of pharmaceutical sciences and dean of the graduate school at Wayne State University. Referring to name reactions is part of thinking of yourself as an organic chemist, she says.

Amanda Bryant-Friedrich: You know, the interesting thing is that its part of the culture. When youre an organic chemist, you almost wear it as a badge of honor, if you can say every reaction by name thats out there.

Kerri: So knowing a bunch of name reactions is kind of proof that you know your stuff, youre on the inside.

Leigh: Yeah, and a lot of people I talked to said this, that students, especially graduate students, should, and are expected to, know some name reactions. And even thoug
h most say that memorizing these names has nothing to do with a students ability to understand the chemistry, there are some that use it as a sort of test. And if students fail this test, they might be looked down upon, in a way. So someone who doesnt know all the right name reactions, for whatever reason, may feel like they cant participate fully in organic chemistry. Heres Maria again.

Maria Gallardo-Williams: So there is a degree of snobbery, theres a degree of being selective. If you cant keep up with all these name reactions, then maybe you shouldnt be an organic chemist, which I hate. I hate things that are exclusionary by design, right? I mean, to me, thats the opposite of what we should be doing.

Leigh: And looking at that roster of name reactions gets at a bigger issue, which is who those names representor dont. Heres Amanda again.

Amanda Bryant-Friedrich: One of the questions that were walking around and one of the things that were not talking about is that most of these are white men. And so the fact that they are white men means that the idea of name reactions and the reactions in organic chemistry, theyve almost all been given to one sector of the world population: white men. And I would imagine that if you even talk to a young woman and told her about the Goldberg reaction, she would definitely first think that thats a man, and its a white man.

Leigh: Its actually not. That ones named after Irma Goldberg, one of the few reactions named after a woman.

Amanda Bryant-Friedrich: Theres a problem with that. Definitely. As we move forward now in science, and we look at these names, we have to be more aware of the fact what it is that were doing. Were being very exclusive there. Its an exclusive group of individuals and I dont know if that will serve us well in the future.

Kerri: OK, to hear that the bulk of reactions from the 19th to the mid 20th centuries were named after white men does not exactly surprise me. But Im curiouswhats the breakdown like today for these hundreds of name reactions?

Leigh: Well, its hard to know the exact numbers, because sometimes theres not that much information about the history of a reaction, and sometimes that would involve us making a call about race, ethnicity, or gender that may not be correct. To get a better handle on this, I called up Kevin Shea, an organic chemistry professor at Smith College. In 2010, Shea and one of his undergraduate students, Julie Olson, wrote a paper in the journal Accounts of Chemical Research called Named Reactions Discovered and Developed by Women.

Kevin Shea: When we started looking into reactions named for women, it was really kind of depressing.

Leigh: Basically, because there were so few, and sometimes who the reaction is named after is not straightforward.

Kevin Shea: A couple of them, its ambiguous, right? Because its like husband and wife, same last name. Right.

Leigh: Almost all of the women that worked in chemistry back in the early to mid part of the last century were married to chemists. Irma Goldberg was married to chemist Fritz Ullmann, but she didnt change her name.

Kerri: So thats how many?

Leigh: Lets see, theres the Piloty-Robinson pyrrole synthesis, the Robinson part after Gertrude and Robert Robinson; the Hunsdiecker reaction, after Clre and Heinz Hunsdiecker; the Goldberg reaction; the Jourdan-Ullmann-Goldberg reaction; the Catellani reaction, discovered by Marta Catellani in the 70s; and most recent, the StaudingerBertozzi ligation, partly after Carolyn Bertozzi. Thats six total. But since we cant be sure that the Robinson and Hunsdieker reactions were named after the female half of those couples, that makes four for sure.

Kerri: Four out of 600-something.

Leigh: Yeah. There are also a handful named after Asian men, for example Sonogashira coupling, the Suzuki reaction, and a few more. Its even harder to find reactions named after Black, Latinx, or Indigenous people. The name reactions list is definitely heavy with chemists who are male and whitetypically American or European. As Kevin and others I spoke with pointed out, thats partly the result of the fields long legacy of denying access to people who did not fit that profile. Heres Amanda again.

Amanda Bryant-Friedrich: Oh yeah, thats what its all about right? Its about access. So you can think about the amount of time that people, lets say African Americans, have actually been involved in academic science and the ways that weve actually become a part of those communities. Yeah, Im sure weve missed a lot. Weve missed a lot. Weve seen stories out there, like people who developed surgical methods that were attributed to people of color, but they did not get the actual recognition for that, because they didnt have the right title. So access has been, and always probably will be in my lifetime, one of the biggest issues that colors everything that were talking about right now.

Leigh: Who was allowed to be in the room, both in the past and now, of course has a giant, giant influence on the people we see represented in name reactions. And as several chemists I spoke with noted, not only does a lack of reactions named for women and people of color highlight a broader systemic issue within chemistry, but it also has the potential to be discouraging to chemists who dont see people who look like them on these lists.

Amanda Bryant-Friedrich: When I was learning about the name reactions and becoming a chemist myself, I recognized pretty early on that there was no one that looked like me or sounded like me or anything that was actually represented by those names. Did it mean that I felt like I could never have my own name reaction? No. It is, of course, a problemits just like walking into buildings where there are these portraits of all white men everywhere.

This is just not a visual, its written, its ingrained in our disciplines. So yeah, its definitely exclusive, and I think for future generations is going to be even more of that.

Leigh: But she says that she hopes that chemists will recognize this and change it. But that brings up the process of naming reactions itself.

Kerri: Righthow does that work? Who decides which reactions get named, and what theyre called? And which scientists are important enough to have the reaction named after them?

Leigh: Well, unlike how we name elements or chemicals, theres no central organization that decides how chemists name reactions. I spoke with Eric Jacobsen, an organic chemistry professor at Harvard University who has a reaction named after him: the Jacobsen epoxidation. He says that the process is pretty subjective.

Eric Jacobsen: You know, it seems, its kind of an arbitrary thing. And, first of all, its almost never the person who discovers the reaction who names it after themselves. There are a few very, very sort of peculiar exceptions to that, but for the most part, the vast majority of cases, other people name it, and its, I think its probably most often people who use the reaction in a synthesis will then refer to that reaction by the persons name.

Leigh: Many chemists say that this system, or lack thereof, can be problematic. Its such a word of mouth phenomenon.

Kerri: An organic process, you might say?

Leigh: Sure. But the point is that what each reaction gets called depends on who you are. For example, is it the Buchwald-Hartwig amination or is it the Hartwig Buchwald? If we think of it as a language, everybody has their own dialect, based on what theyve learned from the people around them. As Carmen Drahl wrote in C&EN in 2010, many people refer to the Mizoroki-Heck reaction as just the Heck reaction, even though Tsutomu Mizoroki developed a lot of the chemistry behind it.

Eric Jacobsen: You know, it gets messy if different people discovered the reaction and made it practical, lets say. Or if competing groups were working on the same reaction at the same time. How do you parse credit that way? Theres often an unpleasantness to it, even though its probably intended to be a nice thing, a thing of
recognition, but it often can be divisive and actually hurtful to people if theyre not recognized, even though they made important contributions to it.

Leigh: As a postdoc, Eric worked on a reaction later named after his advisor, Barry Sharplessthats the Sharpless dihydroxylation reaction. Then in 1990, shortly after Eric started his own lab, a C&EN reporter covering a method for catalytic asymmetric epoxidation of unsubstituted olefins dubbed it the Jacobsen epoxidation. The name stuck, although Eric remembers having mixed feelings about it at the time.

Eric Jacobsen: At the time I was kind of, frankly terrified, because at that point, the reaction wasnt very useful yet, and I wasnt sure if it ever would be. And, um, you know, it just seemed like a lot, a lot more attention than it should be getting. I mean, obviously, on some level, I was happy that I was getting attention and my students in my group were excited about it, but yeah, frankly I was embarrassed and I thought it was a little bizarre.

Leigh: Hes been name dropped more recently too, but C&EN had nothing to do with it this time.

Eric Jacobsen: A paper came out a couple of years ago, where in the title it said it used the Jacobsen amine. And I, frankly, didnt know what that was. I really didnt know that I had an amine. And I had to read the paper to find out what it was.

Leigh: Eric says trying to get things named after him isnt his goal as a chemist, but it was flattering. His personal experiences aside, he says chemists need to think carefully about whether using name reactions does make women and people of color feel excluded.

Eric Jacobsen: I think its important to ask people in that situation if thats the case. I hope that we all have this goal to increase representation in our field and to attract the very best people, the very best scientists for our field regardless of their race and gender. So if something like that dissuades people or discourages people, we definitely should think about it carefully.

Leigh: So how organic chemists use the language of name reactions can potentially have an impact on people that dont look like the white men that reactions are mainly named after. And chemists are trying to figure out how to deal with these issues.

Kerri: Were going to take a short break, and then well hear from these chemists and others about what they see in the future for organic chemistrys culture of name reactions.

Gina Vitale: Hi. Im Gina Vitale, an assistant editor at C&EN. If youre interested in the future of chemistry across all disciplines, check out this years class of Talented 12 early-career chemists. Every year, C&EN highlights a dozen rising stars in chemistry, who are using their creativity and chemical know-how to solve some of sciences toughest problems. The class of 2020 includes researchers who are hunting for compounds in interstellar space, figuring out better ways to diagnose tuberculosis, and dreaming up blueprints for building the next generation of computer chips.

Read all about the 2020 Talented 12 at cenm.ag/T12. Well include that link in this episodes description. You can also listen to the dazzling dozen share their research at the C&EN Futures Festival, a virtual event coming up on Aug. 2526. As well as catching the Talented 12 speak, you can also tune in to hear leaders from across the chemistry enterprise discuss the people, ideas, and discoveries that will shape the future of science. C&ENs Futures Festival is a free event, and you can register at FuturesFestival.org. Itll be recorded, too, so you can catch up with the action on-demand at FuturesFestival.org. Now back to the show.

Kerri: So Leigh, coming back to our discussion about name reactions in organic chemistry. Weve now heard reasons in favor of using name reactions, and reasons against. Youve heard from a lot of people on this subject, even though we couldnt include all of them in this episode. Where do these people think we should go from here? Will organic chemists continue to use name reactions?

Leigh: Well, some chemists would like to see more of an emphasis on descriptive names for reactions instead, like the aldol condensation or olefin metathesis, which is sometimes called the Grubbs reaction. But others, such as Jin-Quan Yu, an organic chemistry professor at Scripps Research, see the culture of name reactions as motivational, and want to keep the tradition going.

Jin-Quan Yu: For myself, Im a person of color. And when I see name reactions, my first feeling is, you know, Im inspired, because basically I admire whoever the scientists are who discovered the reaction, and Im grateful to them for their discovery, and Im enjoying, you know, benefiting from those discoveries. And I can only be inspired to dream maybe one day, my name, you know, will be attached to a reaction. If Im a student, I hope thats how they would be inspired.

Leigh: Jin says hes confident that, while the roster of name reactions is pretty white and male at the moment, that will change, and its already changing as new generations of chemists have a shot at discovering reactions. And some, like Vy from UC Irvine, do not see the use of name reactions as detrimental to the field.

Vy Dong: I could imagine if we put so much emphasis on the importance of having a named reaction or memorizing all of these 450 reactions and knowing who all the people that invented them were, I could see how that could be a problem. I just dont think that thats sort of something that drives the field right now.

Kerri: Theres also the question of what to do with all the existing name reactions, if the practice were ended. Would chemists just stop using them?

Leigh: Right. That is a hard question to answer. Eric from Harvard noted that at the very least, new chemists will need to know name reactions in order to understand references to them in the literature.

Eric Jacobsen: If we were to start from scratch right now, I might make the argument that theres no value to it at all, especially if those names alienate people in any way or discourage people in any way because theyre sort of, its a restricted list. But were not starting today, right? So theres this history to the field and theres a literature to the field and for people, you know, graduate students need to learn how to read the literature. And they also need to learn how to do new chemistry based on existing chemistry. You know, I think that it is important for them to know name reactions, or at the very least, to know where to look them up or where to find them.

Leigh: Amanda, from Wayne State, also notes that we have to work with what we have.

Amanda Bryant-Friedrich: We know in that world that were always talking about the exact same reaction, by giving it that name. Now could we have done that by giving it a name thats related to the actual functional groups involved or the mechanism involved? Sure. But that was not what we actually inherited. So I think it works very well for people now to use those names. I would love to see just having more inclusion of others. And I would imagineand I have never done the research myselfbut I would imagine that there are women, there are people of color who have done important things that we could add to that library, so that people would know that there were diverse people out there who contributed to the advancement of organic chemistry, and are name worthy. Making that list more inclusive would probably be a better way of attacking it than getting rid of it altogether.

Leigh: In fact, most of the people I spoke with do not want to end the use of name reactions. But there is a growing movement to include more context around those reactions when teaching them, and to recognize that there have been reactions named for men whove exploited the work of women, people of color, and even their own white male colleagues.

Amanda Bryant-Friedrich: I wish that there was a way where we could make that known, when people learn the reactions or . . . I know its just too difficult to take the name away, especially i
f its been around for hundreds of years or whatever. But its, it really can trigger in your mind when you know the history behind that person. If that person was someone who, honest to goodness took away opportunities from people, and took away the access that we just talked about. And then we constantly commemorate their contributions. Thats hard. That is hard.

Leigh: Of course, trying to build a more representative environment for organic chemistry doesnt end at discussing the history of named reactions in chemistry classes. What many people that I talked to agreed on is that the organic chemistry community needs to do a better job at inclusion, and work harder to highlight more women and people of color in the classroom and lab. Brandon Quillian, an associate professor of organic chemistry at Georgia Southern University, agrees.

Brandon Quillian: I think, especially from the perspective of where you can find women and minorities, I think that would definitely be very inspiring. I think it would be more of an attention-getter for those select people, because it would have helped me out, without a doubt.

Leigh: Kevin, from Smith College, says that professors can help students see past the white wall of history, by talking about how the field is changing, and pointing out modern women and people of color who are doing important work in organic chemistry.

Kevin Shea: You have to admit that it is exclusionary. Theres no question that it is. And I think if you dont address that in your classes, then youre perpetuating the exclusionary nature of that.

Leigh: As for Maria, from NC State, shes hoping organic chemists will do away with name reactions for good, abandoning them to the trash bin along with other outdated techniques like mouth pipetting.

Maria Gallardo-Williams: I mean, I dont see the need to teach my students all these names. Theyre not, theyre not going to enhance their understanding of chemistry, right? But then at the same time, if theyre going to go to graduate school, I dont want them to look like fools and not know that there are name reactions. So its really, youre like between a rock and a hard place because you have to make sure that your students look good when they get to grad school. So you have to let them know that this is a thing that other people do. They do it because weve always done it that way. And to look like a cultured and smart organic chemist, you had to do it, you know, you had to drop names, and you had to use name reactions, because it was the way we spoke. That doesnt mean that we have to speak like that forever.

Kerri: Well, thank you, Leigh, for helping us examine this issue. So what happens next? Are chemists going to do anything to change this?

Leigh: Well, not everyone thinks its a problem. But several people I interviewed said: You know, Ive never really thought about this before. Yeah, we should really examine that. Vy from UC Irvine pointed me toward a Carolyn Bertozzi tweet from a few days ago, referring to the Cope rearrangement as the Hardy-Cope. Elizabeth Hardy was a student of Arthur Copes, and the reaction was part of her thesis work. Organic chemists have the ability to change the narrative here. And most people I talked to said that they hope this podcast will launch a bigger conversation around it.

Kerri: And wed like to know what you think about this subject. You can find C&EN on Twitter @cenmag, Im @absoluteKerri.

Leigh: And my Twitter handle is @LeighJKBoerner. Well include those in this episodes description. Use the hashtag #namereactions so others can find your comments.

Kerri: And if Twitters not your thing, you can always email us at cen_multimedia@acs.org.

Leigh: And Id like to thank all the people who talked to me about this, both those that we included in the podcast and the following people we couldnt fit in: Carolyn Bertozzi, Scott Denmark, John Hartwig, Kami Hull, Mark Levin, Jie Jack Li, Jeff Seeman, Stephen Stinson, Zerong Daniel Wang, and the people who spoke to me on background.

Kerri: This episode of Stereo Chemistry was written by Leigh Krietsch Boerner and produced by me, Kerri Jansen. It was edited by Michael Torrice and Amanda Yarnell. Heather Holt was our copy editor. The music in this episode was Uncle Jojo by Dialgo and DuDa by Ian Post.

Stereo Chemistry will be back next month with a new episode. Be sure to subscribe so you dont miss it. Stereo Chemistry is the official podcast of Chemical & Engineering News, which is published by the American Chemical Society.

Leigh: Thanks for listening.

Chemical & Engineering News

Read the original here:
Podcast: Chemists debate the value of name reactions in organic chemistry - Chemical & Engineering News

The infusion of Lucas Zelarayan and Youness Mokhtar back into the lineup on Saturday night at Nipper Stadium against FC Cincinnati improved the Crews possession, but it didnt give the club the offensive lift it needed to come away with three points.

A scoreless draw with its top lineup against FC Cincinnati, less than two months after a 4-0 win against the same team, wasn't so much a regression for the Crew offense as it was a reflection of the new normal the team is navigating as it tries to reestablish what made the offense successful in the MLS is Back tournament.

Like New York City FC in the previous game, FC Cincinnati deployed its defense deep and the Crew struggled to break it down and create opportunities. Future opponents will likely see that as a recipe for success against the team in second place in the Eastern Conference through eight games.

To break down compact defenses such as Cincinnati used, chemistry between attacking players must be sublime. And with playmakers Zelarayan and Mokhtar having missed multiple games and weeks of training, the Crew can only now begin to rebuild what was lost in the offense.

"Those little connections, that little bit of sharpness and, for sure, that chemistry in the final third with our front players we need to get back where we were at early in Orlando," Crew coach Caleb Porter said after Saturdays match.

"I'm confident we'll be back where we were and even better. Tonight, I think you saw we had some good moments, but we need to keep working on it and we just need time. It's that simple."

Zelarayan had his best scoring chance Saturday night in the 51st minute with a ball from Milton Valenzuela at the top of the box. With just enough space to get a clean shot off, Zelarayan hit the side netting just wide of the left post.

Whenever Zelarayan, Mokhtar or winger Pedro Santos had possession and tried to play through the middle from a wide position, the Cincinnati defense blocked passing lanes and pressured the ball. With a back line of five defenders, the Crew was often outnumbered in the box, and crosses from the outside backs or wingers were cleared away consistently.

Zelarayan had the most pressure on him as soon as a pass was directed his way and was uncharacteristically dispossessed multiple times. Defender Josh Williams said that was evidence to him that it takes time coming back from injury because the speed, physicality and sharpness of decision making required in a game cant truly be replicated in training.

"Even a guy like Lucas who, to me, I watch him in training and I don't think he ever loses the ball," Williams said. "As those guys get going, I think you're going to see their play rise and rise, and eventually they'll be back to their old selves and causing havoc for upcoming defenses."

The Crew offense hasnt been completely absent, and theres no reason to panic. Theres time for the Crews execution in the final third to improve with the team being at full strength again and two more days in this upcoming three-game window starting Wednesday at home against Philadelphia compared to the previous window.

"We'll get better with time and more games where we'll play the same group and dig into some of those little final third details," Porter said.

jmyers@dispatch.com

@_jcmyers

Originally posted here:
Crews top playmakers Lucas Zelarayan and Youness Mokhtar working on their chemistry - The Columbus Dispatch

Aug. 21 (UPI) -- Lili Reinhart and Austin Abrams star in Amazon's romance drama Chemical Hearts, Netflix's Lucifer is back with Season 5 Part 1 and an all-star cast present a virtual table read of Fast Times at Ridgemont High this weekend.

In addition, DC Comics will be releasing new trailers and footage for its biggest projects at the DC FanDome virtual event, WWE airs SummerSlam with marquee championship matches and RuPaul's Drag Race is releasing a new docuseries on VH1.

Here's a rundown of some of the films, TV shows and virtual events that are taking place this weekend.

Films

'Chemical Hearts' -- Amazon

Lili Reinhart is high school transfer student Grace who starts dating Austin Abrams' character Henry in Chemical Hearts, which comes to Amazon Prime on Friday. Grace was involved in a car accident that killed her previous boyfriend.

'The Vanished' -- VOD

Thomas Jane and Anne Heche are two parents who are desperately looking to find their missing daughter after stopping at an RV park in The Vanished, which comes to video-on-demand services on Friday. Actor Peter Facinelli wrote and directed the film.

'The One and Only Ivan' -- Disney+

Ivan, a gorilla, wants to return to the wild and leave behind the circus he is stationed at in The One and Only Ivan, which hits Disney+ on Friday. Sam Rockwell voices Ivan with Angelina Jolie as Stella the elephant, Danny DeVito as Bob the dog and Bryan Cranston as the circus owner.

TV

'Lucifer' Season 5 Part 1 -- Netflix

Lucifer returns with the first part of Season 5, which arrives onto Netflix with eight episodes on Friday. Tom Ellis, Lauren German, Kevin Alejandro, D.B. Woodside, Lesley-Ann Brandt and Rachel Harris star. Season 5 will include 16 episodes in total.

'RuPaul's Drag Race: Vegas Revue' -- VH1

RuPaul's Drag Race series presents a new docuseries that premieres Friday on VH1 at 8 p.m. EDT. Vegas Revue will follow former Drag Race legends as they prepare for the RuPaul's Drag Race Live! residency show in Las Vegas.

'Love in the Time of Corona -- Freeform

Freeform is airing a four-part limited series about the search for love and connection during the COVID-19 pandemic that begins Saturday at 8 p.m. EDT. Leslie Odom Jr., Nicolette Robinson, Tommy Dorfman, Rainey Qualley, Gil Bellows, Rya Kihlstedt, Ava Bellows and L. Scott Caldwell star.

'WWE SummerSlam' -- WWE Network

WWE presents its second biggest show of the year Sunday at 7 p.m. EDT on the WWE Network. The Fiend Bray Wyatt challenges Braun Strowman for the Universal Championship while WWE Champion Drew McIntyre defends his title against the malicious Randy Orton.

Streaming

'Fast Times at Ridgemont High' table read -- Facebook, TikTok

An all-star cast will present a live, virtual table read of Fast Times at Ridgemont High to benefit COVID-19 relief efforts Friday at 8 p.m. EDT on CoreResponse's Facebook page and TikTok. Sean Penn, Brad Pitt, Jimmy Kimmel, Jennifer Aniston, Morgan Freeman, Julia Roberts, Matthew McConaughey, Shia LeBeouf and Henry Golding are taking part in the table read.

'DC FanDome' -- DCFanDome.com

DC Comics is offering fans a virtual event that will feature new trailers and information regarding Wonder Woman 1984, The Batman, The Suicide Squad , Black Adam and more at DC FanDome, which begins Saturday at 1 p.m. EDT at DCFanDome.com. The event will also showcase new video games and comic books.

Link:
What to stream this weekend: 'Chemical Hearts,' 'Lucifer' - UPI News

If one thing isnt slowing down, its the future of superhero movies. Matt Reeves The Batman, which stars Robert Pattinson as Bruce Wayne, is set to resume production in London in September. In further Batman news, Ben Affleck is set to return as the Caped Crusader in the upcoming The Flash.

This comes on the heels of the news that Michael Keaton might also be reprising his role as Batman for the film, making it clear that the film would be spanning multiple timelines and universes.

Spider-Woman is also set to have her own big-screen adventure soon under the eye of Booksmart director Olivia Wilde. But the Spider-verse news doesnt stop there, as the villain Kraven the Hunter is set to be the subject of his own spin-off from Triple Frontier director J. C. Chandor.

While we wait for those movies, here are the best new movies you can watch at home this weekend.

Where to watch it: Rent on digital, $5.99 on Amazon, $6.99 on Apple

Michael Almereydas biopic of the inventor Nikola Tesla eschews all the conventions of the genre, using anachronisms and breaks in the fourth wall to tell the cult figures story. Ethan Hawke stars as Tesla, with Kyle MacLachlan as Thomas Edison. From our review:

The films experimental nature makes it tougher to swallow than a conventional biopic, but also more interesting and rewarding to engage with. Great performances help keep the whole enterprise anchored Hawke and MacLachlan are wonderful as men caught in conflict with each other and the anachronisms provide food for thought long after the film has ended. Teslas eeriness is appropriate to the man who inspired it.

Where to watch it: Streaming on Amazon Prime Video

Riverdales Lili Reinhart stars in this adaptation of the Krystal Sutherland novel of the same name. When Henry (Austin Abrams) first meets new girl Grace (Reinhart), he doesnt think much of her, but slowly begins to fall in love with her when theyre both chosen to edit the school newspaper.

Where to watch it: Streaming on Shudder

Random Acts of Violence, directed by Jay Baruchel, stars Jesse Williams as Todd, a comic book creator who discovers that a fan is using his creation Slasherman as inspiration for carrying out a series of murders. People at the convention Todd is attending start dropping like flies, and it looks like Todd might be next.

Where to watch it: Rent on digital, $5.99 on Amazon, Apple, and Google Play

In Stage Mother, Jackie Weaver (Silver Linings Playbook) stars as Maybelline, a conservative church choir director whose life is turned upside down when she inherits her late sons drag club. As she struggles to save the club from bankruptcy, she begins to open up and find a new calling in life. The film also stars Lucy Liu as one of Maybellines sons friends.

And heres what dropped last Friday:

Where to watch it: Streaming on Apple TV Plus

The documentary Boys State follows a thousand teenage boys as they participate in a leadership even in which they are charged with creating a state government from the ground up. We were blown away back at Sundance, where the film premiered. From our review:

One of the many things that makes Boys State entertaining as well as relevant is the way Moss and McBaine capture these kids different facets, and track how their combined ambition and navet play into the big picture. On the one hand, the participants clown around with the process, proposing legislation to address the looming threat of alien invasion and the difficulty of pronouncing the letter W. (The wag who introduces that bill demands that Boys State officially change the letter to dubya.) A favorite leadership tactic involves getting them to chant, howl, or hoot like apes in order to focus their attention. Theres a lot of young male energy in these proceedings.

Where to watch it: Rent on digital, $5.99 on Amazon, $6.99 on Apple and Google Play

At the height of the Cold War, a Soviet spacecraft crashes on Earth after a failed mission. The only survivor of the crash is the the missions commander, who has no memory of what happened. Unfortunately, as it turns out, the lone survivor isnt entirely alone: He may have brought back an alien parasite, too.

Where to watch it: Rent on digital, $6.99 on Amazon, Apple, and Google Play

Stranger Things Joe Keery stars in this thriller as Kurt, a young man who dreams of becoming famous on social media. His latest gambit is rigging out his car, which he uses to work for an Uber-esque ride-sharing company, to stage a nonstop stream. This catches the eye of another social-media-famous wannabe, stand-up comedian Jessie (Sasheer Zamata), who sets out to stop him. This is another Sundance find that surprised us. From our review:

Considering how heavy that sounds, theres not too much under the surface of Kurts violent ride. [Director Eugene] Kotlyarenko keeps Spree from becoming a present-set Black Mirror by opting for jokes over profound moments of psychological dissection. The result is a movie gushing with gags and a few moments that get too real for its own good. Killing a clichd Los Angeles club-goer with a motorized drill is wacky! Brutal gun violence baked into an emoji-filled livestream gets a bit uncomfortable. Luckily, the tonal whiplash is rare for Spree, which zips from vignette to vignette on the back of an all-in performance.

Read the original:
Tesla, Chemical Hearts, and 7 new movies you can now watch at home - Polygon

TSUKUBA, Japan, Aug. 21, 2020 /PRNewswire/ -- A team at the International Center for Materials Nanoarchitectonics (WPI-MANA) has demonstrated controlled addition reactions at specific sites on a single molecule by using an atomic force microscope's (AFM) local probe at low temperature. This work enables the synthesis of functional carbon nanostructures that cannot be obtained by conventional chemistry. Thanks to their superior electrical properties, such nanostructures are expected to find applications in nanoelectronic devices.

(Image: https://kyodonewsprwire.jp/prwfile/release/M105739/202008183185/_prw_PI5fl_0QP3Fe05.jpg)

The team synthesized three-dimensional graphene nanoribbons (3D-GNR) by on-surface chemical reaction. Then, taking advantage of the AFM's ability to conduct tip-induced assembly, they demonstrated the nanoribbons' capability as a framework for local probe chemistry. This could allow sequential reactions, particularly addition reactions (in which two molecules combine to create a bigger one), by a local probe at the single-molecule level.

The AFM's probe, terminated with a small carbon monoxide molecule, allows direct observation of the inner structures of both single molecules, as well as the products of on-surface chemical reactions.

It also allows researchers to conduct single molecule chemistry via tip-induced reactions. The local probe can be used to generate highly reactive radical species by tip-induced dehydrogenation, dehalogenation or deoxidization on surfaces. However, since these organic redox reactions are conducted with planar molecules, the molecule-substrate interaction has to be reduced by inserting thin insulating films. In contrast, if a 3D hydrocarbon is used, the out-of-plane moiety can be used for local probe chemistry in a similar way to recent measurements of intermolecular interactions.

The WPI-MANA team noted that direct addition reactions at specific sites like the ones they demonstrated can advance chemistry toward synthesis of single compounds atom by atom. Such extremely fine control offers the ability to create unprecedented new functional materials.

This research was carried out by Shigeki Kawai* (Principal Researcher, Nano Functionality Integration Group, Nano-System Field, WPI-MANA, National Institute for Materials Science (NIMS)) and his collaborators.*Present affiliation: Group Leader, Nanoprobe Group, Nano Characterization Field, Research Center for Advanced Measurement and Characterization, NIMS

Shigeki Kawai et al., SCIENCE ADVANCES, Feb. 28, 2020:https://advances.sciencemag.org/content/6/9/eaay8913

SOURCE International Center for Materials Nanoarchitectonics (WPI-MANA), National Institute for Materials Science (NIMS)

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WPI-MANA Uses AFM's Probe to Induce Chemical Reactions at Specific Sites on Single Molecule - PRNewswire

As a dated and experienced manufacturer of glass machinery, R.C.N. SOLUTIONS has come to the conclusion the chemical tempering of the glass is open to several advantages and different applications.

CT900 - Chemical tempering plant,"RIVA by RCN"

The process is preferred for all those jobs where thin tempered glass is demanded, a limitation the thermal tempering ovens cannot overcome, albeit some manufacturers have recently extended the thermal tempering to thin glass as well. However, the optical quality is far to be equal to the glass chemically tempered, because the chemical process does not provoke distorsion on the glass surface, not a minor detail , and not the only benefit.

The chemical process consists of submerging the glass into fused potassium salt bath and exposing the glass to an ion exchange process, at a temperature of 450C.

The process provokes a space reduction between the glass particles that are compressed by the bigger size of the potassium ions. The glass surface is under compression (300/400 N/mq) while the core is not in compensating tension.

Thou the chemical tempering requires more time process than the thermal one, the advantages are significant: glass chemically tempered can be processed later -drilling, cutting, edging, polishing, sandblasting; curved glass can also be tempered, special curves in particular. The absolute flatness is essential for the lamination process and the lack of distorsion is a crucial matter in some architectural projects too.

For this reasons RCN, in cooperation with an expert having more than 40 years experience in manufacturing chemical tempering plants, has developped its new chemical tempering line, "Riva by RCN" and it is not by chance that international companies such as AGC, Schott, Europtec and Luxottica have chosen RCNas supplier.

This new line perfectly matches with the other RCN machinescombining a full production "team": bending, tempering and lamination. The winning solution resonding to the latest market requirements, but also granting a free access to several, different applications, giving your products the high added value you are looking for.

R.C.N. SOLUTIONS SRL - Italy

http://www.rcnsolutions.it

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R.C.N. Solutions Srl and the chemical tempering plant - Glass on Web

If youre anything like this author, you got a C- in high school chemistry and never looked back. With a newfound interest in the topic, Im hoping to revisit the molecular science of some of the most popular materials in 3D printing to understand themnot just in terms of applications and physical properties, but chemical makeup.

According to its Polymer Additive Manufacturing Markets and Applications: 2020-2029 report,SmarTech Analysis expects polymer 3D printing to create as much as $11.7 billion in revenue in 2020, driven by sales of polymer AM hardware and all associated material families. In particular, thepolyaryletherketone (PAEK) family of plastics is one of the most important in the additive space due to the high strength, temperature resistance and chemical resistance. This group includes PAEK, polyether ketone ketone (PEKK) and polyether ether ketone (PEEK). PAEKs differ from their lower cost alternative, polyetherimide (PEI), which is most recognizable under the SABIC brand ULTEM and often discussed in the same context as PAEK polymers.

Due to the above properties, PAEKs are well known in high performance industries, such as aerospace, oil and gas, and automotive. Their ability to undergo sterilization without breaking down makes them well suited for medical applications as well, including medical implants like artificial hips. Unlike other materials, PEI for additive manufacturing (AM), in particular, has received the necessary certifications to be used in critical aerospace applications.

To learn about the chemistry of the PAEK family, we reached out to Victrex, who is the leading provider of PAEK polymers for 3D printing and invented PEEK specifically in 1926. John Grasmeder, chief scientist at Victrex, was able to provide us with an explanation of what gives PAEK plastics their unique physical properties at the molecular level.

Its not so much about the atoms themselves, which are principally carbon, hydrogen and oxygen, but the molecular structure which these atoms form. PolyArylEtherKetones molecular structures comprise the following building blocks:

The aryl and ketone groups are fairly rigid and provide stiffness which means high strength combined with resistance to heat. The ether groups provide some degree of flexibility, for good toughness, and like the aryl and ketone groups are unreactive, so all three building blocks provide resistance to chemical attack, Grasmeder said.

The number and arrangement of ether and ketones in the polymer chains of PAEK plastics (PAEK vs PEEK vs PEKK, etc.) determines the glass transition temperatures and melting point of the plastic, as well as its heat resistance and processing temperature. The higher the ratio of ketones to ether, the more rigid, thus increasing the glass transition temperature and melting point.

In particular, PAEK has a continuous operating temperature of 250 C (482 F) and can even handle loads for a short period of time in temperatures of up to 350 C (662 F). When burned, PAEK puts out a low amount of heat and its fumes are the least toxic and corrosive. PAEK also has good chemical resistance. The material does not break during an unnotched Izod impact test, has a tensile strength of 85 MPa (12,300 psi), a Youngs modulus of 4,100 MPa (590,000 psi) and yield strengths of 104 MPa (15,100 psi) at 23 C (73 F) and 37 MPa (5,400 psi) at 160 C (320 F).

Whereas PEKK possesses all of the same properties as PAEK mentioned above, PEKK can exhibit greater compression strength than PEEK and also has a much wider of processing parameters than PEEK. It can be printed at a lower temperature than PEEK with better layer adhesion.

OXPEKK plastic from Oxford Performance Materials.

This combination of stiffness and flexibility locates PAEK plastics into the semi-crystalline category of thermoplastics. Grasmeder explained how these characteristics manifest in terms of physical performance. The presence of a significant degree of crystallinity ensures that the polymers are more resistant to friction, wear, heat, creep (long-term deflection under temperature and load), fatigue (repeated application of a cyclic stress) and resistant to chemicals. Without crystallinity, these properties would be severely compromised, Grasmeder said.

Whereas PAEK polymers are semicrystalline, PEI is amorphous, meaning that the polymer chains are randomthey have no particular order or arrangement. In turn, PEI is less expensive, has a lower impact strength, and a lower usable temperature.

While PAEKs can be processed using pretty much any manufacturing technology, they present a particular issue for 3D printing, which all polymers face: interlayer bonding. Due to the weakness of the bonds between layers in printed objects, the Z-axis of these parts lack the same strength exhibited in the X- and Y-axes. In turn, PEEK used for injection molding cant simply be taken and used for fused filament fabrication (FFF).

For this reason, Victrex has recently released a PAEK-based filament, VICTREX AM 200, that is meant to be optimized specifically for AM. Grasmeder claims that it is intended to address this weakness in 3D printing PEEK. For some time before the FFF material, Victrex was already well known for its development of PAEKs for use in laser sintering. Specifically, powdered PAEKs were meant to have improved thermal stability for recycling unsintered powder, to lower the costs of printing with the material by ensuring high reusability.

Due to the characteristics described, PAEK family of materials and PEI are becoming increasingly attractive alternatives to metal parts that can be potentially made at a lower cost. This is in part being driven by the third generation of FFF systems that, after the expiration of some Stratasys patents, incorporate heated build chambers and high temperature printheads necessary for 3D printing PAEK plastics and PEI. In particular, PAEK manufacturers are targeting aircraft interiors and some structural components, such as brackets, for light-weighting.

A printed part made with VICTREX AM 200 PAEK filament using an Intamsys FUNMAT PRO 410 3D printer, representative of the third wave of FFF 3D printers. Image courtesy of Victrex.

As we have noted, chemical companies are increasingly looking to take advantage of the shift from fossil fuels to renewable energy in global infrastructure, with oil companies looking to shift revenue streams to petroleum-derived plastics. However, from an ecological perspective, this doesnt address the ecological issues associated with the extraction of the ingredients for these materials or the lifecycles of these materials. Therefore, its important to consider the possibilities of biopolymer alternatives.

Grasmeder said that, while there are not yet any biopolymer equivalents to PAEKs, they may exist in the future.

At present to my knowledge there are no commercially available PAEKs which are wholly based on renewable sources but PAEKs have their own sustainable credentials in the form of lightweighting and recyclability potential in applications, Grasmeder explained. As an aside, the molecules used to make PAEK that are mentioned above are ultimately manufactured from basic chemical building blocks, such as benzene and toluene. There are already bio-based routes to these building blocks being developed and scaled. Its a reasonable assumption that as the bio-based chemical industry expands, the bio-based raw materials that we need to make bio-based PAEK may become available sometime in the future.

Continue reading here:
3D Printing Chemistry 101: The Molecular Makeup of PAEK, PEKK and PEEK Plastic - 3DPrint.com

The Hartford Athletic have been training at Dillon Stadium ahead of the USL Championship season opener. With a new coach and some new players on the roster, the team is using this time to build team chemistry on the field.

After an usual offseason, the players are excited to be back working face to face and theres a sense of optimism that this years team can do something special.

Theres a certain hunger that I think exists right now in our group, said midfielder Nicky Downs. Its a younger group than we had last year. Guys that really want to get after it and work hard and will buy into the system that Coach is trying to implement.

Radhi Jaidi took over as head coach of the Athletic after the club completed its inaugural season. The USL Championship is tentatively scheduled to begin the 2020 season on July 11.

Originally posted here:
Hartford Athletic Continue to Build Team Chemistry - NBC Connecticut

Bids Due July 28, 2020

OTTAWA, Ill., July 7, 2020 /PRNewswire/ --Located just 70 miles from Chicago, Illinois, investment group headed by Federal Equipment Company and Holland Industrial Group is accepting offers for the Cristal Metals (Tronox) production facility in Ottawa, Illinois. The facility is fully configured to produce and process titanium powder and can be converted to many other products. Turnkey for its existing function as a calcining and drying operation, the plant can be used across multiple chemical processes. A $200 million investment was made to build this facility in 2010 and it was operated from 2010-2019.

Bids for the facility are due July 28, 2020.

The facility includes calciners, rotary tray dryers, liquid slurry, filtering, and more. It also features CSX rail spurs branching into (2) buildings.

The sale of this turnkey operation is a unique opportunity:

For more information, to view sale brochure, and bidder packet, please visit: https://fedequipblog.fedequip.com/for-sale-chemical-plant-ottawa-il/.

Contact:Interested parties should contact David Winger for further information: +1 216.536.0309| david@fedequip.com.

Auction Scenario:Should an acceptable sealed bid offer not be received by the July 28, 2020 deadline, an auction of the company's M&E assets will commence, with all assets sold on a piecemeal, "as is, where is" basis. The auction will be conducted online at the end of August or early September 2020. A second inspection of the assets will be made available to interested buyers.

About Holland Industrial Group:

With over 30 years of experience in plant liquidations and equipment auctions, Holland Industrial Group serves large and small corporations in asset recovery for their idle and surplus assets. Our Real Estate arm allows us to help companies understand their short-term and long-term value of their property. We have the capabilities to buy all-cash to complete a smooth transaction in connection with the disposition of all plant assets including the real estate. For more information, please visit HollandIndustrialGroup.com.

About Federal Equipment Company:Federal Equipment Company offers 60 years of expertise buying and selling processing and packaging equipment. We optimize the value you recoup for surplus equipment and ensure you get the equipment you need quickly from our broad, on-hand inventory of reliable used machines. For more information, please visit: fedequip.com.

View original content to download multimedia:http://www.prnewswire.com/news-releases/turnkey-state-of-the-art-calciningchemical-facility-and-equipment-available-for-sale-301088596.html

SOURCE Federal Equipment Company

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Turnkey State-of-the-art Calcining/Chemical facility and equipment available for sale - Yahoo Finance