(Mass Appeal) Are you looking to sneak in a little extra education in your childrens day? Have them join you in the kitchen for a lesson in chemical reactions while you make dinner or some tasty muffins. Ashley Tresoline, Owner of Bella Foodie explains how she keeps children engaged in cooking lessons by explaining the chemistry involved with recipes. She also shares her recipe for apple crunch muffins.

Apple Crunch MuffinsBy: Ashley Tresoline

Ingredients:

cup non diary milk plus tbs apple cider vinegar (I use almond milk)1/3 cup applesauce unsweetened cup maple syrup plus 2 tbs. cup melted coconut oil1 egg2 tsp. vanilla extract cup almond flour or almond meal1 cup all purpose flour (can sub 1 to 1 gfree flour)1 tsp. baking powder tsp. baking soda tsp. salt1 tbs. cinnamon tsp. nutmeg1 cup granny smith apples, peeled and diced

Crumble topping1/3 to cup almond meal flour2 tbs. maple syrup2 tbs. coconut sugar almonds, coarsely chopped or your favorite nut2 tbs. coconut oil, meltedPinch of cinnamon

Directions:Preheat the oven to 425and line a muffin tin with paper liners about 9 muffins. Measure out the non-diary milk and add the cider vinegar and set aside. In a small bowl combine all the crumble ingredients and set aside. In a large bowl add the almond flour, all purpose flour, baking powder, baking soda, salt, cinnamon and nutmeg. Whisk the dry ingredients together until well combined. Peel and chop your apple and set aside. In a small bowl combine the wet ingredients milk vinegar mixture, egg, unsweetened applesauce, cup maple syrup, the rest of the coconut oil and the vanilla extract. Whisk together until combined and then add to the dry ingredients and mix together. Once well combined fold in the apples. Fill the muffin tins way. Bake at 425for 5 minutes then lower the oven to 350for 10-15 minutes.

Original post:
Explore the science of chemical reactions by baking some tasty apple muffins - WWLP.com

The money will be used to design ways to remove a group of chemicals from the drinking water of Braintree, Randolph and Holbrook.

BRAINTREE The Tri-Town Water District has received a $200,000 grant from the state to reduce the levels of a "forever chemical" in the water system.

The state has also announced new regulations that will require regular testing of drinking water for a group of chemicals known as PFAS starting next year, and also sets a state limit for the levels of those chemicals. There is no federal standard.

Gov. Charlie Baker said the state is committed to making sure all residents have access to safe and clean drinking water.

"By setting stringent standards for PFAS in drinking water, we can ensure that all public water systems across the commonwealth are testing for these emerging contaminants, while providing them the tools and resources they need to address any contamination," Baker said in a statement.

PFAS is an acronym for per- and polyfluoroalkyl substances, a group of man-made chemicals which have been used in a variety of applications since the 1950s, from nonstick cookware and water-resistant clothing to food packaging materials and firefighting foam. They are considered a "forever chemical" because they don't break down and can accumulate in the body. They have been linked to a number of negative health impacts, from weakening the immune system of children, increasing cholesterol levels and causing tumors. They have also been shown to be a health risk for pregnant and nursing mothers.

Braintree Mayor Charles Kokoros, who is chairman of the Tri-Town Water Board, said the money will be used for the engineering and design work needed for PFAS removal at the proposed regional water plant at Great Pond. The plant will serve the town as well as Randolph and Holbrook, the other tri-town members. The regional plant will replace two outdated treatment plants, one for Braintree and one which serves Randolph and Holbrook.

PFAS were discovered in Braintree's drinking water last year as part of the design process for the new water treatment plant. Braintree officials made changes that brought down the PFAS level in the town's drinking water from 24.5 parts per trillion last fall to 21 parts per trillion in January. In April, the town council approved spending $693,020 to install granular activated carbon in the treatment plant's filter system to further reduce the levels.

The new state limit will be 20 parts per trillion and water systems will be required to take corrective action when the limit is exceeded. Testing for PFAS will be required starting in January for large water systems and public notices will be required when the limit is exceeded.

A total of $1.9 million in grants were awarded to 10 water systems by the state.

Link:
Tri-Town gets grant to remove 'forever chemical' - The Patriot Ledger

Courtesy of D. Sharon Pruitt

Chemists from the Royal Society of Chemistry and cheese experts from the British Cheese Board teamed up to conduct scientific research onthe best way to melt cheese on toast. (No, we arent making this up.)

Like any other scientific experiment, the chemists carried out several tests changing one variable at a time in order to come up with the perfect formula.According tothe Science Executive, Ruth Neale, they testedthree different components: consistency of the temperature of the melted cheese across the slice, the texture of the cheese, and the taste. The chemists focused on the temperature and scientific documentation working alongside the Secretary of the British Cheese Board, Nigel White, who judged the texture of the cheese and the taste.

Courtesy of the Royal Society of Chemistry

Okay, after reading that formula, you probably had one of two reactionseither younerded-outabout the scientific method, or your eyes glazed over and your brain shut down. If you didnt ace your high school chemistry class, dont worry! Well explain what the formula actually means without the scientific jargon:

"We found that the perfect slice can be made by melting 50 grams of sliced hard cheese, such as cheddar, on a slice of white bread, 10mm thick, under the grill. The cheese on toast should sit at a distance of 18cm from the heat sourcewhich in our grill was at a temperature of 115 degrees Celsiusand needs to cook for four minutes to achieve the perfect consistency and taste." Ruth Neale

For those of us who aren't chemists using the metric system, that means use about 1.75 ounces of sliced hard cheese on white bread that's about .4 inches thick. Make sure the heat source is heated to 239 degrees Fahrenheit and is keptabout 7 inches away from the cheese toast.

We're almost certain this might be a publicity stunt to get us interested in studying science, but who cares! It got us talking about a few of our favorite thingscarbs and cheese! What's your favorite type of cheese to melt on toast? Let us know in the comments below.

See the original post here:
There's an Actual Scientific Way to Perfectly Melt Cheese on Toast - ourcommunitynow.com

Catholic World News

September 22, 2020

Continue to this story on USCCB

CWN Editor's Note: A rising threat to the lives of unborn babies is the chemical abortion pill, the US Conference of Catholic Bishops said in an action alert. The number of chemical abortions in the US has gone up dramatically, while the overall number of abortions has decreased. COVID-19 is expected to only make the problem worse, with more women (and teen girls) seeking chemical abortions at homeeven illegally, by mail and without a doctors prescription.

For all current news, visit our News home page.

Sound Off! CatholicCulture.org supporters weigh in.

All comments are moderated. To lighten our editing burden, only current donors are allowed to Sound Off. If you are a current donor, log in to see the comment form; otherwise please support our work, and Sound Off!

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USCCB warns against rising chemical abortions, calls for support for Save Moms and Babies Act | News Headlines - Catholic Culture

RIDGEWAY, N.Y. (WKBW) 3 adults and 2 juveniles are facing charges after chemical tanks were found punctured by bullets and leaking chemicals.

Monday afternoon, the Ridgeway Fire Department was called to the Helena Agri-Enterprises LLC facility on Allis Road due to a chemical leak issue. Once on the scene, first responders determined that the leak was due to bullet holes in the chemical tank itself. It appeared that bullets had ricocheted of nearby buildings and the tank.

The Orleans County Sheriffs Office, NYS DEC, NYS Police and Medina Police all responded to the scene and searched the nearby area. Police found 5 people, 2 adults and 3 juveniles, south of the chemical facility who admitted to target hooting in the area, according to the Orleans County Sheriff's Office.

Investigators believe the chemical facility was directly in line with the target shooting. Jared S. Silva, Stephen J. Jackson, Joe W. Jackson and the 3 juveniles were arrested and charged with reckless endangerment and criminal mischief.

It's estimated that $65,000 in damage was done to the chemical storage tanks.

Read the original here:
Five arrested after chemical tanks struck by gunfire - WKBW-TV

Used in everything from the detergent that washes our clothes to the toothpaste that keeps our mouths clean, chemicals play an integral role in society.

While it's hard to imagine life without them, if not used in a responsible way their effect on the natural world and us can be harmful.

The European Commission has stated that some chemicals "can severely damage our health or the environment," while the World Health Organization has previously estimated that exposure to selected chemicals resulted in the loss of 1.6 million lives in 2016.

It's against this backdrop that the notion of "green chemistry" comes into play. In relatively simple terms, the United States Environmental Protection Agency has defined it as "the design of chemical products and processes that reduce or eliminate the use or generation of hazardous substances."

The EPA goes on to explain that the idea of green chemistry relates to a product's entire life cycle, which includes everything from its design and production to utilization and disposal.

Paul Anastas is the director of Yale University's Center for Green Chemistry and Green Engineering. Speaking on the latest episode of CNBC's Sustainable Energy, he explained how he became interested in the subject.

"When I was a young chemist, I looked around at all of the technological miracles that chemistry produced," he said. "And then I looked at the other side of the equation all of the unintended consequences of pollution and its effect on the environment and on human health," he added.

"So green chemistry is really a way of keeping all of those technological miracles, those innovations, without all of those unintended consequences."

Anastas, together with John Warner a chemist who is now president and chief technology officer of the Warner Babcock Institute for Green Chemistry co-authored the book "Green Chemistry: Theory and Practice," a key body of work in the field.

First published in 1998, the book lists 12 principles of green chemistry, one of which focuses on the prevention of waste, a subject that Anastas expanded upon when speaking to CNBC.

"Waste, we need to recognize, is a man-made concept," he said. "In nature, there is no waste: every time a waste is generated, an organism evolves to use that waste as a feedstock."

He added: "And so, we think about how to do the same thing in industry, how you either prevent or avoid waste, or utilize whatever waste in a valuable way."

With attitudes regarding pollution and the environment shifting in recent years, many governments and businesses are emphasizing their commitments to sustainable practices.

But while actions need to match words and there is clearly a long way to go, Anastas sought to emphasize the changes that were being made.

"I simply cannot name an industry sector that isn't using green chemistry," he said. "Everything from pharmaceuticals, to plastics, everything from cosmetics to the way that we generate, store and transport our energy," he added. "Now, I'm not going to say that companies are doing it systematically or in all of their products, but great strides are being made."

When it comes to the production of chemicals, there is some serious work to be done, however. According to the International Energy Agency (IEA), in 2018 direct carbon dioxide emissions from primary chemical production hit 880 million tonnes, a jump of almost 4% compared to 2017. The IEA goes on to describe the chemical sector as being "the largest industrial consumer of both oil and gas."

Anastas was asked how easy it would be to lower the use of energy in chemical production by applying the principles of green chemistry.

"We've forced chemicals to do things they didn't naturally want to do," he said. "So we've heated them up, we've put them under pressure and we've tortured them to obey and become the things we want them to become," he added.

"But it's not just the quantities of energy that's important, it's the character and the nature of energy that we use: it needs to be renewable and non-depleting, and nontoxic, and not polluting."

Originally posted here:
How 'green chemistry' could have a big part to play in the future - CNBC

It was a very good thing. When lockdown started, we were at home. My wife is a great cook. So, we were enjoying all the great food. So, I was very happy spending time with Vinnie and Oreo (his pet dog). Later, there was a time when I wanted to step out to work. It wasn't like I wasn't enjoying being home but there was this urge within to face the camera, perform. But knowing the fact that pandemic and all, the counts are increasing, I was just hoping for the vaccine to come out as soon as possible, and everything gets sorted. But we started shooting, and hopefully, it's going out quite well. Kundali Bhagya again picked up, and we are at the top. (Photo: Instagram)

More:
Exclusive - Kundali Bhagya's Dheeraj Dhoopar on his offscreen chemistry with Shraddha Arya, pay cut, family planning, and more - Times of India

The senior United Nations disarmament official urged the Security Council to unite and ensure that the use of chemical weapons shall never be tolerated, as she briefed the 15-member body on Feb. 3 on efforts by the Organisation for the Prohibition of Chemical Weapons (OPCW) to verify the destruction of Syrias chemical weapons stockpiles and production facilities.

Izumi Nakamitsu, Under-Secretary-General and High Representative for Disarmament Affairs, said that the COVID-19 pandemic continues to hamper the ability of OPCWs Investigation and Identification Team tasked with identifying the perpetrators of the use of chemical weapons in Syria to deploy in that country.

I say this every month because it bears consistent repeating: There is an urgent need to not only identify but hold accountable all those who have used chemical weapons in violation of international law

She also urged Syria to fully cooperate with the OPCW Technical Secretariat to address 19 issues still outstanding from its initial declaration on its chemical weapons programme, submitted to OPCW in The Hague in 2013. One of those issues is at the heart of a request by the OPCW Technical Secretariat for details about chemical agents produced or weaponized at a facility which, according to Damascus, has never been used for chemical weapons.

Without such action, we are allowing the use of chemical weapons to take place with impunity. It is imperative that this Council show leadership in demonstrating that impunity in the use of these weapons will not be tolerated, she said, adding that the Secretary-General, in his address to Member States on 28January, had underscored the need for Council unity to address todays roiling threats to peace and security.

She urged Damascus to cooperate fully with the OPCW Technical Secretariat, which stands by its assessment that due to unresolved gaps, inconsistencies and discrepancies Syrias initial declaration cannot be considered accurate and complete, as it is required to be under the Convention on the Prohibition of the Development, Production, Stockpiling and Use of Chemical Weapons and of Their Destruction.

She added, as she has said in the past, that international confidence in the full elimination of Syrias weapons programme hinges upon OPCW being able to resolve the outstanding issues. I hope that during the next round of consultations between the [OPCW] Declaration Assessment Team and the Syrian National Authority, to be held later this month, further progress will be made to resolve these issues, she added.

The representative of theUnited Statessaid any use of chemical weapons is a clear thereat to international peace and security, and his country is committed to holding perpetrators to account. The Assad regime has repeatedly used chemical weapons against Syrias people, seeking to avoid accountability by obstructing independent investigations and undermining the work of OPCW. Its allies, including the Russian Federation, have sought to block all efforts to promote accountability, shielding it from responsibility, notably by spreading disinformation, attacking OPCW and seeking to undermine efforts by responsible nations to hold the Assad regime accountable. He hailed OPCW leadership, its Technical Secretariat and its professionalism in carrying out its mandate, and said the United States looks forward to the future reports of the Investigation and Identification Team.

Noting that the Teams first report, in April2020, concluded that the Assad regime had used chemical weapons, he said the decision by OPCW in July 2020requested that Syria take steps to redress the situation. But Damascus has failed to complete any measures outlined in that decision, as communicated by the OPCW Director General in October 2020. Recalling that the United States, along with 45 co-sponsors, submitted a draft decision to the OPCW Conference of the States Parties in response, he called on the Conference to take appropriate action when it reconvenes this spring so as to send a strong message to the Syrian regime.

The Security Council likewise must ensure there are serious consequences for Syrias use of chemical weapons, he said, recalling it had decided that the regime must cooperate fully with OPCW and the United Nations, efforts which the United States supports. Accountability is needed to bring long-overdue justice to the victims, he stressed, as is a broader political process, as called for in resolution2254(2015). The Assad regime must uphold its Convention obligations, while the Council must call out atrocities and hold those who use chemical weapons accountable.

The representative of theUnited Kingdom, Council president for February, underlined in her national capacity that, despite decisions by OCPW and the Security Council, Syrias declaration of its chemical weapons programme cannot be considered complete. She called the 19 unresolved issues substantive and serious in nature, among them, issues pertaining to a production facility which Syria claims has never been used. However, a review of all information and materials collected by the Declaration Assessment Team indicates the production of chemical nerve agents did take place there. That four outstanding issues have been closed demonstrates that such questions can be concluded if Damascus chooses to engage. She pressed Syria to provide complete access to documents and witnesses, stressing that the cat-and-mouse game of explanations and excuses cannot continue. Noting the Declaration Assessment Teams intention to deploy for consultations in February, she outlined the United Kingdoms expectation that Syria provide full responses during those meetings.

The representative ofSyria said that his country no longer has any chemical weapons, as the Head of the Joint Investigative Mission told the Council in June 2014. However, some Western countries, denying that reality, continue to use the chemical weapons issue as a weapon of war and blackmail. For its part, OPCW is forced to produce reports based on conjecture and information from terrorist groups such as the White Helmets which fail to meet even the basic criteria for objectivity. He added that OPCW and the High Representative for Disarmament are trying to serve the Western agenda by denying information provided by the Governments of Syria and the Russian Federation. Despite the hostile Western approach, Damascus is continuing to cooperate with OPCW and its Technical Secretariat, he said, adding that discussions on an OPCW visit took place last week, although no agreement was finalized.

He emphasized that Damascus rejects any attempt to undermine its initial declaration to OPCW or its efforts to cooperate with that organization. A draft resolution before the Conference of the Parties to the Chemical Weapons Convention, if adopted, would represent a hostile act par excellence by levelling false accusations against the Government of Syria while exonerating terrorists and their co-sponsors for the use of chemical weapons, he said. Such a text would also lay the groundwork for hostile unilateral or trilateral acts not unlike the United States attack on the Shayrat airfield in April 2017. He went on to say that Western Governments have seized upon the chemical weapons issues to provide cover for Israels development of nuclear, chemical and biological weapons.

The representative ofTurkeysaid that of the 19 outstanding issues, one requires urgent attention, and that the Syrian regime must be forced to declare the types and quantities of chemical weapons produced at a facility which Syria says was never used for such a purpose. Underscoring the importance of Council unity, he said that his country is a co-sponsor of a draft resolution before the Conference of the Parties to the Chemical Weapons Convention on the Syrian chemical weapons dossier. Going forward, investigations by the fact-finding mission and the Investigation and Identification Team must continue, he said, adding that the Syrian regimes denial of visas to members of the latter is
a violation of the Chemical Weapons Convention. He concluded by saying that ending impunity is indispensable for peace in Syria and that those with influence on the regime bear a special responsibility.

Original post:
UN Official: Impunity in Use of Chemical Weapons Must Not Be Tolerated - Global Biodefense

February 1, 2021• Physics 14, 13

Colliding a large organic molecule with a surface can break a specific chemical bond in the molecule with surprising precision.

The ability to selectively excite and break specific bonds in molecules would open new vistas in synthetic chemistry, allowing the creation of compounds that are difficult to synthesize via conventional chemical techniques. However, decades of research have shown that, with a few exceptions [1], when energy is put into a specific molecular bondwith a laser, for exampleit is quickly redistributed among many vibrations in the molecule long before a reaction may occur. In other words, attempting to selectively put energy into a bond usually leads to the same chemical reaction as heating the reactants on a hot plate. Surprisingly, Lukas Krumbein, at the Max Planck Institute for Solid State Research in Germany, and colleagues have now observed that a bond in a large molecule can be selectively broken by adding energy to the system in the simplest way possibleby colliding the molecule with a surface [2]. The result improves our understanding of the dynamics of large molecules and could offer novel ways to control their reaction products.

The idea that energy imparted during a collision can promote chemical reactionsa process sometimes called splat chemistryhas been around for decades. Researchers have shown, for instance, that the collision of argon atoms onto methane (CH4) molecules adsorbed on a surface can lead to the molecules dissociation [3]. In that experiment, the equivalence of the four CH bonds means that the collision process is not bond specific. What is significant about the work by Krumbein and colleagues is that they demonstrate the cleavage of a particular bond.

The researchers use electrospray ionization and ion-beam deposition to accelerate a 73-atom molecule called Reichardts dye toward a copper surface. Using scanning tunneling microscopy to inspect the scene of the collision, they find that when the molecule collides with the surface at translational energies of 250 eVlarger than the energy associated with thermal excitationit selectively cracks at a specific carbonnitrogen (CN) bond. Breaking this bond results in the molecule opening into a more spread-out configuration. In contrast, when the molecule is simply heated, a different CN bond is broken, which splits the original molecule into two pieces. Krumbein and colleagues also observe this lower-energy splitting reaction in some collisions, but this reaction has a lower probability than the cracking reaction.

Key to the success of their experiment is the sheer size of the molecule involved. Previous studies of surface dynamics have focused on the reactions of small molecules, such as nitric oxide (NO) or CH4. The collision-induced excitation of single bonds in such small molecules is relatively ineffective. For example, when a molecule of NO collides with a surface, the efficient compression of the NO bond would require a perfectly aligned, head-on collision geometry. With any other alignment, the molecule would behave much like an American football, hitting with its long axis at an angle to the surface [4, 5]. This off-axis geometry causes most of the translational energy to be converted into rotational energy, sending the molecule spinning away from the surface but without inducing any chemical change.

The situation is very different for Reichardts dye, named after the doctoral student who developed the molecule while searching for a compound that would change its color depending on the solvent. This large organic molecule consists of seven rings surrounding a central nitrogen atom. When a Reichardts dye molecule hits the surface, the collision doesnt compress a single bond. Instead, the collision causes the entire molecule to undergo a large-scale distortion in a very short period of timemore like a prop-comedy rubber chicken hitting a wall than like a football.

Based on simulations of their experiment, Krumbein and colleagues explain that the fate of the molecule depends on its orientation when hitting the surface. The key difference between the collision geometries is how the large-scale distortion strains the three carbon atoms surrounding the central nitrogen atom (Fig. 1). Collisions that focus the molecules distortion on one particular carbon atom lead to splitting, with the molecule breaking apart into two fragments. Distortions focused on one of the other two (symmetry equivalent) carbon atoms lead to cracking, in which the molecule hinges open but remains in one piece. Other impact configurations produce no reaction, leaving all three bonds unbroken and the molecule intact (Fig. 2).

The experiments demonstrate that, as expected, the probability of a reaction is dependent on the initial translational energy of the molecule. Faster molecules split or crack with higher probability than slower molecules. Using simulations that account for the collision process, the researchers explain the experimental observation that the more common outcome is a cracking reaction, even though splitting is the thermally favored pathway. This is not contradictory, as the reaction rate is controlled both by the activation barrier and by the probability of attaining a suitable molecular configuration for the reaction. The simulations reveal that the collisions selectively strain the central nitrogen atom in a way that promotes CN bond cleavage. In contrast, heating the molecule distributes energy randomly.

The results obtained by Krumbein and colleagues provide important new insight into the localization of energy in molecules: The large-scale distortion of the molecule focuses the energy on a single bond while simultaneously preventing the energy from rapidly delocalizingat least for the picosecond or so that it takes for the molecules geometry to stabilize after the collision. These types of large-scale deformations are common in macromolecules under strain, such as polymers, proteins, and DNA. Accounting for the way that energy is concentrated on specific bonds within these molecules will help predict how they respond to such strain. Insights such as those provided by this work are also important for understanding mechanochemistry, the coupling between macroscopic strain and chemical reactivity. Mechanochemistry underlies important phenomena, such as stress-corrosion cracking and polymer degradation under shear. An atomistic understanding of mechanochemistry is still in its infancy, but Krumbein and colleagues experiment represents a considerable advance.

Melissa A. Hines is a professor of chemistry at Cornell University. Her research focuses on understanding and controlling the chemical reactivity of surfaces to enable advances in areas ranging from photocatalysis and self-cleaning surfaces to the development of stable, high-brightness photocathodes.

Lukas Krumbein, Kelvin Anggara, Martina Stella, Tomasz Michnowicz, Hannah Ochner, Sabine Abb, Gordon Rinke, Andr Portz, Michael Drr, Uta Schlickum, Andrew Baldwin, Andrea Floris, Klaus Kern, and Stephan Rauschenbach

Phys. Rev. Lett. 126, 056001 (2021)

Published February 1, 2021

The rest is here:
Physics - Selective Bond Breaking with Splat Chemistry - Physics

INTRODUCTION

Precisely tuning the properties of nanomaterials to obtain desired characteristics is one of the most important goals of nanoscience. Within this scope, rationally regulating the reactivity of nanomaterials is critical for future multistep programmable processing and applications. Some nanomaterials (or some certain parts) need to be protected to reduce their reactivity under certain specific conditions and to restore their activity after successful deprotection (13).

Scientists have, in the past few decades, proposed plenty of efficient and selective protection-deprotection strategies toward regulating the reactivity of various functional groups in organic chemistry (4, 5). Usually, the functional group (or organic molecule) is linked with the protective group via various chemical/physical interactions (typically covalent bond) to reduce its reactivity, so that the protected functional group (or molecule) can survive in the subsequent steps. Subsequently (after the steps involving the attack of other functional groups), the protective group is removed, restoring the original functional group or molecule. This protective strategy is pervasive in multistep organic syntheses, such as natural product synthesis, solid-phase peptide synthesis, and polymer synthesis (4, 6, 7). Unfortunately, these well-established organic protective-deprotective processes are hardly applicable in inorganic nanomaterials owing to the lack of functional groups in inorganic nanomaterial surfaces, their irreversible agglomeration, surface reconstruction, and particle etching during the complex protective-deprotective process (8, 9). An efficient and facile approach to regulate the reactivity of inorganic nanomaterials remains elusive.

Black phosphorus (BP), a rising star in postgraphene two-dimensional (2D) nanomaterials, is known for its tunable bandgap (from ~0.3 to ~2.0 eV), its good compromise between charge carrier mobility and current on/off ratios, its broadband absorption from the visible to the mid-infrared range (1012), and its excellent biocompatibility (13). These attractive properties position BP to be suitable for application in optoelectronics and biomedical areas (10, 13). However, the high chemical reactivity of BP and oxygen/water leads to BP degradation under ambient conditions, causing functional failure of BP (14, 15). Recent research reveals that the reactivity of BP is directly related to the lone pair electrons of the P atom (internal factor) and the surrounding oxygen/water (external factor) (14). The lone pair electrons of each P atom contribute to the high electron density on the BP surface (16, 17), which gives BP strong reducibility. The surrounding oxygen/water can easily attach to the highly reactive surface of BP and react to form PxOy. To protect BP, a conceivable strategy could be to decrease its surface electron density and prevent oxygen/water from accessing the BP surface. On the basis of this idea, considerable efforts have been made to protect BP from ambient degradation. However, despite the rapid progress in the effective protection of BP, a practical method to deprotect passivated BP has not been developed. It is even more difficult to develop a method that combines protection and deprotection processes to switch BP from a passivated state to a reactive state in response to environmental changes (i.e., passivation by storing under ambient condition, and reactivity resuming to facilitate further functionalization or degradation when necessary) (13, 1720).

Here, we develop a protective chemistrybased strategy (Fig. 1) for rationally regulating the reactivity of BP. We begin by binding the BP with Al3+ ions to decrease its surface electron density, effectively decreasing its reducibility. Then, the hydrophobic 1,2-benzenedithiol (BDT) molecule assembles into a dense array on the surface of BP/Al3+ via the AlS bond, which effectively isolates the nanocomposite from oxygen/water. This protective process offers an ultrastable BP complex (BP/Al3+/BDT), which can be stable under ambient conditions even for 2 months without its key physical/chemical characteristics being altered. Contrary to previous reports, this ultrastable BP/Al3+/BDT can be deprotected by chelator treatment [typically EDTA-tetrasodium (EDTA-4Na)]. This is possible because of the stronger binding affinity between Al3+ and EDTA-4Na in BP that enables the removal of Al3+ and BDT layers from the BP surface. The removal of the Al3+ and BDT layers restores the high surface electron density of BP, resuming its reactivity. To prove this concept, we used the deprotected BP in a degradation study. Expectedly, it exhibited the same behavior as original BP.

Protective step 1: Binding Al3+ ions with lone pair electrons on the surface of P atoms decreases surface electron density of BP, leading to a reduced chemical reactivity of BP. Protective step 2: Self-assembly of the hydrophobic dense array on the BP surface isolates BP from surrounding oxygen/water. Deprotective step: Removal of Al3+ ions and hydrophobic dense array on the BP surface by a chelating agent. The treatment recovers the electron density of BP, restoring the original reactivity of the deprotected BP. BDT, 1,2-benzenedithiol; EDTA-4Na, EDTA-tetrasodium.

Bulk BP was prepared and characterized following a methodology highlighted in a previous report (fig. S1, A to C) (21). BP nanosheets were obtained via the sonication of powdered bulk BP in N,N-dimethylformamide. Scanning electron microscopy and transmission electron microscopy (TEM) images show that the size of the BP is 858.6 89.1 nm (fig. S1, D and E). High-resolution TEM images show a single-crystal BP nanosheet with a lattice spacing of 2.56 , which assigns to the (111) plane of BP (fig. S1F). Atomic force microscopy (AFM) analysis reveals that the thickness of BP is 2.65 0.27 nm, which implies that there are four to six individual phosphorene layers (fig. S1G) (21). X-ray diffraction (XRD) and Raman spectra demonstrate the same crystal characteristic of BP as its bulk form (fig. S1, H and I).

The protective step starts by binding Al3+ to the BP surface. BP/Al3+ is obtained by the simple mixing of BP and AlCl3 in an ethanol solution at room temperature. In our case, besides Al3+, a wide range of metal ions were systematically screened (see note S1). Noble metal ions (such as Au3+, Ag+, and Pd2+) can form a redox pair with BP and quickly react with BP to form noble metal nanoparticles on the BP surface (fig. S2, A to I). Heavy metal ions (such as Cu2+, Zn2+, Ni+, Co2+, Mn2+, Fe2+, and Sn4+) and light metal ions (such as Na+, K+, Mg2+, Ca2+, Al3+, and Ti4+) can form similar BP/metal ion complexes. However, compared to Al3+, most of them show the weaker ability for passivating BP (fig. S2K). A more detailed discussion about the effect of charge and radius on interaction strength can be found in fig. S3 and note S1. Some metal ions (typically Ti4+ and Sn4+) undergo fast hydrolysis, which is not conducive for regulating the reactivity of BP (fig. S3, A to G). Therefore, Al3+ ions are selected to form BP/Al3+ coordination complexes because they have a strong electron-withdrawing ability, relatively high stability, and low reactivity over other metal ions (2224). The changes in zeta potential suggest the successful binding of Al3+ ions on BP (fig. S3D). X-ray photoelectron spectroscopy (XPS) characterization provides further evidence for the successful attachment of Al3+ ions to the BP surface (fig. S3I).

Subsequently, a layer of BDT attaches to the surface of BP/Al3+ via self-assembly to further strengthen the protection of BP. BDT was chosen as the protective layer for the following reasons. (i) It can form an orderly molecular array on the selected substrate owing to its rich electron density and hydrophobic nature (25, 26); (ii) the thiol group, in this case, is more suitable than other functional groups such as carboxyl, oxhydryl, and amino groups for the assembly of a hydrophobic layer on the surface of BP/Al3+ (note S2 and fig. S4); (iii) BDT exhibits less
conformational freedom over the linear n-alkane thiol ligands and thus can assemble into a denser monolayer on the substrate (fig. S4E) (27, 28); and (iv) theoretically, the BDT monolayer is sufficiently thin (~0.50 nm, based on AFM images in fig. S1G and Fig. 2), and as such, it will have little influence on the physical/chemical properties of the coated BP.

(A) TEM image. (B) AFM (height profile along the white line) image. (C) STEMenergy-dispersive x-ray spectroscopy (EDX) elemental mapping images. (D) High-angle annular dark-field (HAADF) image. (E) Magnified HAADF image taken from the selected area in (D). a.u.: arbitrary units. (F) Selected-area electron diffraction (SAED) pattern of BP and BP/Al3+/BDT. (G) FTIR spectra of BP, BP/Al3+, BP/Al3+/BDT, and BDT. (H) 1H NMR spectra of BP, BP/Al3+/BDT, and BDT. (I) Thermogravimetric curves of BP and BP/Al3+/BDT. ppm, parts per million.

The morphology of the obtained BP/Al3+/BDT was investigated. TEM (Fig. 2A) images show that the morphology of BP/Al3+/BDT has a 2D nanostructure without observable defects on its surface. AFM images show that the thickness of BP/Al3+/BDT is 3.75 0.22 nm (Fig. 2B). These suggest that the obtained BP/Al3+/BDT does not show a notable morphological difference from the original BP nanosheets (fig. S1, E and G). The XRD pattern of BP/Al3+/BDT gives the same feature peaks like that of the original BP, indicating that the crystal structure was unaltered (fig. S4H). The conductivity of BP is also preserved after the protective treatment (fig. S4I).

The surface configuration of BP/Al3+/BDT was studied by scanning TEM (STEM). High-angle annular dark-field (HAADF)STEM images and energy-dispersive x-ray spectroscopy (EDX) analysis of BP/Al3+/BDT reveal the uniformity of the distribution of P, Al, and S over the whole nanosheet (Fig. 2C). The HAADF image of BP/Al3+/BDT in Fig. 2D indicates a lattice constant of 0.256 nm, which is consistent with the original BP nanosheets. Figure 2E shows the HAADF image of the enlarged area in Fig. 2D (dashed yellow rectangle). The spots with relatively high contrast (labeled with dashed white circle) located at the central area of the P atom (with low contrast) hexagons can be assigned to the Al3+ ions. The Z-contrast intensity distribution (Fig. 2E, inset, corresponding to the selected area labeled with dashed green rectangle) discloses a P-Al periodic pattern, which further suggests that the Al3+ ions favor a central location in P hexagons. Figure 2F shows the selected area electron diffraction (SAED) pattern of BP and BP/Al3+/BDT. In comparison to BP, the diffraction spots associated with the (001) and (021) lattice planes of BP/Al3+/BDT are almost extinct (labeled with dashed red circle), while the (111) lattice plane of BP/Al3+/BDT gets enhanced (labeled with dashed green circle). The difference in diffraction spots between BP and BP/Al3+/BDT is attributed to the difference in electron beam scattering and interference, further confirming the binding of Al3+ to BP.

The formation of BP/Al3+/BDT was further verified by Fourier transform infrared (FTIR) spectroscopy and proton nuclear magnetic resonance (1H NMR) (Fig. 2, G and H). In comparison with BP, the FTIR spectra of BP/Al3+/BDT show six substantial characteristic bands at 3400, 1637, 1563, 1430, 1024, and 770 cm1, respectively (Fig. 2G). The characteristic bands at 3400 and 1637 cm1 are assigned to the OH stretching vibration (29). A similar characteristic band is also observed in the FTIR spectrum of BP/Al3+, suggesting that a few OH groups were attached to Al3+ in the synthesis of BP/Al3+ (30). The other characteristic bands at 1563, 1430, 1024, and 770 cm1 are attributed to the BDT molecule, suggesting the presence of BDT molecule in the complex. The SH stretching vibration in the spectrum of BDT is found at 2653 cm1, where the FTIR spectrum of BP/Al3+/BDT shows a flat curve (Fig. 2G, red line) (31). The disappearance of the SH stretching vibration in the FTIR spectrum of BP/Al3+/BDT is evidence of bond formation between Al and S. Figure 2H shows 1H NMR spectra of BP, BP/Al3+/BDT, and BDT. A single peak assigned to hydrogen in the SH group is observed in the BDT at 3.6 parts per million (ppm). Contrastingly, no such peaks are observed at 3.6 ppm for BP/Al3+/BDT (Fig. 2H, red line) (32). This further confirms the formation of the AlS bond. In addition, two chemical shifts of the H in the benzene ring of BDT are observed after the self-assembly slightly shifts to 7.16 ppm (7.07 for original BDT) and 7.48 ppm (7.36 for original BDT) (Fig. 2H, inset). This can be attributed to the covalent interaction of BDT and Al3+ ions (33). FTIR and 1H NMR characterization provide robust evidence for the formation of the BP/Al3+/BDT complex. The Raman spectrum of BP/Al3+/BDT further supports the existence of BDT on the BP surface (fig. S4J). Thermogravimetric analysis reveals that the mass ratio of BP:Al:BDT is approximately 11:1:3 (Fig. 2I). BP is fully covered by Al3+/BDT according to the theoretical calculation (theoretical ratio of BP:Al:BDT is 10:1:3, and the mass ratio of BP:Al:BDT is directly affected by the layer number of BP; see fig. S5, A to C, and note S3 for calculation details).

The reactivity (to oxygen/water) of BP/Al3+/BDT was investigated via a polarizing microscope, TEM, XPS, and ultraviolet-visible (UV-vis) spectroscopy. At the initial stage, the polarizing optical microscope images of both as-prepared BP and as-prepared BP/Al3+/BDT showed a perfectly clean and flat surface (Fig. 3, A1 and B1). TEM images of these two samples showed the same 2D nanosheet structures without observable defects (Fig. 3, A1 and B1, insets). The surface of BP exhibited rough and small topographic protrusions (hereafter termed bubbles) after 1 day of ambient exposure (Fig. 3A2). The surface became rougher, and the bubble size increased when the exposure time was extended to 7 days (Fig. 3A3). The corresponding TEM images show the evolution process of structural destruction and surface bubble growth (Fig. 3, A1 to A3, insets). These results suggest that BP is oxidized after ambient exposure for 1 day and heavily oxidized after 7 days. Contrary to BP, the surface of BP/Al3+/BDT remains almost unaltered after 60 days of ambient exposure (Fig. 3B). Furthermore, a crystal structure is observed for BP/Al3+/BDT with a lattice spacing of 2.56 , which is indexed to the (111) plane of BP even after 1 year of ambient exposure. This result is further supported by XRD, Raman spectra, water contact angle, and zeta potential characterizations, demonstrating the long-term ambient stability of BP/Al3+/BDT (see fig. S5D and note S3 for details).

Polarizing microscope images of (A) bulk BP (0, 1, and 7 days) and (B) bulk BP/Al3+/BDT (0, 30, and 60 days). Insets: Corresponding TEM images. Scale bars, 200 nm. (C and D) HR-XPS spectra of P 2p peaks for BP and BP/Al3+/BDT with ambient exposure for various durations. (E and F) UV-vis spectra of BP and BP/Al3+/BDT dispersed in water for various durations. Insets: variation of the UV-vis absorption ratios at 470 nm (A/A0) of BP (A0: original value).

Degradation of BP yields a product of PxOy and, lastly, produces phosphate anions (BPPxOyPO43) (15). With degradation, the content of PxOy on the BP surface or the content of PO43 in the BP aqueous dispersion are conceivably increased. High-resolution XPS (HR-XPS) spectra of P 2p were used to determine the evolution of the content on the PxOy surface during the degradation process of both BP and BP/Al3+/BDT under ambient conditions. As shown in Fig. 3 (C and D), both BP and BP/Al3+/BDT show two peaks. One peak is visible at 128.5 to 131.5 eV and is assigned to P, while the other is visible at 132.5 to 135.2 eV and is assigned to PxOy. At the initial stage, both as-prepared BP and BP/Al3+/BDT display a high-intensity P peak and low-intensity PxOy peak, respectively. After ambient exposure for 7 days, the peak intensity of BP decreases (P: from 87.3 to 10.7%), while the peak intensity of PxOy increases (PxOy: from 12.7 to 89.3%) simultaneously (Fig. 3C). In contrast, for BP/Al3+/BD
T, the peak intensity of P exhibited no significant changes (P: from 89.9 to 76.3%) even after ambient exposure for 60 days (Fig. 3D), while the peak intensity of PxOy slightly increased (PxOy: from 10.1 to 23.7%). In addition, the intensity of PP/PO for BP/Al3+/BDT is very close to that of the original BP, indicating that the BP/Al3+/BDT offers reliable protection to improve the stability. XPS analysis results were consistent with those of polarizing microscopy. This indicates that the stability of BP/Al3+/BDT is superior to that of BP.

To further address the degradation of both BP and BP/Al3+/BDT, we detected the amount of PO43 in BP dispersion and BP/Al3+/BDT dispersion by UV-vis [see experimental procedures in the Supplementary Materials and fig. S5 (E and F) for details] (21). For the initial dispersion, the absorbance intensity of both BP and BP/Al3+/BDT at 470 nm is roughly the same (Fig. 3, E and F), indicating the same concentration of BP in these two solutions. With increasing dispersion time, this absorbance intensity of BP gradually dwindles, and the absorbance intensity of PO43 at 710 nm increases simultaneously (Fig. 3E and fig. S5G). After incubating in aqueous solution for 7 days, the absorbance intensity of BP at 470 nm (A) decreased by 95.5% compared to the original value (A0) (Fig. 3E, inset), while the absorbance intensity of PO43 at 710 nm increased by 93.7% compared to the original value (fig. S5G). These results reveal the fast degradation of BP in aqueous solution. The final concentration of PO43 (6.6 g/ml) in the degraded solution is close to the initial concentration of BP (6.8 g/ml), which is consistent with the UV-vis observation. Contrarily, for BP/Al3+/BDT aqueous dispersion, the UV-vis absorbance intensity of BP/Al3+/BDT and PO43 shows no significant changes after incubating for 60 days (Fig. 3F and fig. S5H). UV-vis spectra prove that the stability of BP/Al3+/BDT is superior to BP.

The above results indicate that our protective strategy through BP/Al3+/BDT successfully embeds BP with an ultrastability and reduces its reactivity. Our strategy relies on the coordinated interaction between Al3+ and BP, which is expected to be stronger than that induced by noncovalent functionalization (34, 35). Furthermore, the BDT hydrophobic layer provides a dense barrier to oxygen/water. Therefore, both internal and external influencers for BP degradation are minimized, rendering an ultrastable BP in comparison to the BP passivated by other methods (table S1). The BP/Al3+/BDT can even survive some harsh oxidation conditions. As shown in fig. S5 (I and J), BP/Al3+/BDT can remain stable in solutions containing strong oxidants (such as noble metal salt water solution HAuCl4, H2PdCl4, and AgNO3) for 8 days, while the as-prepared BP reacts with noble metal salts immediately.

The reducing reactivity of BP/Al3+/BDT can be attributed to two factors: first, the binding of Al3+ to the BP surface, which results in an electron density shift from the BP surface to Al3+, rendering a lower chemical reactivity of BP/Al3+/BDT; second, the self-assembled hydrophobic dense array on the BP surface effectively isolates BP from oxygen and water, preventing further degradation. Decreasing electron density on the BP surface is revealed by XPS spectra and further supported by density functional theory (DFT) simulation. Full-scan XPS spectra (Fig. 4A) reveals the presence of the relevant elements (the signal of Si derives from the substrate). In the BP sample, the P 2p core-level XPS spectrum shows P 2p3/2 and P 2p1/2 doublet at 129.6 and 130.7 eV, respectively, corresponding to the characteristic of crystalline BP (Fig. 4B) (13, 21). In the BP/Al3+ sample, owing to Al-P interaction, P 2p3/2 and P 2p1/2 doublet appears at higher binding energy (shift from 129.6 to 130.2 eV and from 130.7 to 131.2 eV, respectively). The lone pair electrons from the P atom donate to Al3+, which reduces the electron density on the surface of BP (3s and 3p orbitals) (17, 20). The decreased electron density of the BP surface layer causes strong attractive interactions in the inner layer of the P atom (2p orbitals); therefore, the appearance of XPS signals goes to higher binding energy. After BDT functionalization, owing to the formation of AlS bonds, electrons of S enter the empty orbitals of Al3+ (36). In comparison to BP/Al3+ (~74.6 eV), the XPS peak of Al 2p for BP/Al3+/BDT (~75.0 eV) appears at the higher binding energy (Fig. 4C). Meanwhile, partial electrons retrace from Al3+ to P, which leads to the P 2p3/2 and P 2p1/2 doublet of BP/Al3+/BDT shifting to the lower binding energy (Fig. 4B, red line).

(A) Full XPS spectra of BP, BP/Al3+, and BP/Al3+/BDT. (B and C) HR-XPS spectra of P 2p and Al 2p. (D to F) Calculated NBO charge of P atom, Al3+ ion, and S atom. Structure model of (G1) BP/Al3+ and (G2) BP/Al3+/BDT. Computational mapping of electron density difference in (G3) BP/Al3+ and (G4) BP/Al3+/BDT. Green regions indicate increased electron density, and blue regions indicate decreased electron density. Contours are shown at the 0.0001 a.u. level. (H) Water contact angles of BP, BP/Al3+, and BP/Al3+/BDT.

DFT calculations were carried out to investigate the electron transfer during the binding of Al3+ to the BP surface. After geometry optimization, a BP/Al3+ and BP/Al3+/BDT complex combined by coordination interaction was generated without showing the H atom (Fig. 4, G1 and G2). To quantitatively analyze the charge transfer, we calculated natural bond orbital (NBO) charges of BP, BP/Al3+, and BP/Al3+/BDT (Fig. 4, D to F). After the binding of Al3+ to the BP surface, NBO charges for P atoms increased (Fig. 4D), while NBO charges for Al3+ ions decreased (Fig. 4E). These results verify that electron density shifting occurs from BP to Al3+. Theoretically, the electron density of the BP surface should experience a decrease owing to the electron transfer from P to Al3+. This hypothesis is confirmed by mapping the electron density of BP/Al3+ (Fig. 4G3). As expected, a decrease in electron density (blue area) is observed for BP, whereas an increase in electron density (green region) is observed for Al3+ (Fig. 4G3). After BDT functionalization, compared to BP/Al3+, NBO charges for the P atoms decrease slightly, while NBO charges for Al3+ ions remain almost unchanged. Meanwhile, in comparison to BDT, NBO charges for S atoms of BDT increase slightly in the presence of Al3+ ions (Fig. 4F). The variation of NBO charges strongly confirms the electron transfer from Al3+/BDT to BP. These results are also consistent with the electron density mapping of BP/Al3+/BDT. As shown in Fig. 4G4, the electron density of BP increases slightly (green region in Fig. 4G4), while the electron density of Al3+/BDT decreases slightly (blue area in Fig. 4G4).

Self-assembly of a hydrophobic dense array on the BP surface is another crucial factor that contributes to the enhancement of BP stability. Previous reports demonstrated that water and oxygen are key factors in the process of ambient degradation of BP (14). In our case, the BP surface was fully covered by Al3+. However, the Al3+ layer was not hydrophobic enough to prevent water diffusion (contact angle of 12.3 for BP and 24.8 for BP/Al3+, as shown in Fig. 4H), and the monolayer of Al3+ was too thin to block the penetration of oxygen/water. Assembly of the hydrophobic dense array increases the contact angle of the BP surface from 24.8 to 130.5, which, in turn, strongly increases the hydrophobicity of the obtained BP/Al3+/BDT complex. As shown in Fig. 3 and fig. S3L, although the BP/Al3+ shows improved stability (see note S1), further functionalization with the BDT layer promotes the stability of the material over the BP/Al3+ complex even further. The hydrophobic surface of BP can effectively prevent contact between water and BP, decreasing water-induced BP degradation (27, 28).

Beyond the hydrophobic surface, a closed-packed array-like dense molecular film was formed, which effectively isolated BP from oxygen and water. Owing to the interactions among aromatic rings, the BDT could form a highly ordered c
losed-packed array on the surface of BP. The interspace between the BDT molecules was around 3.40 (37), which is slightly smaller than the size of O2 (~3.46 ) and water (~3.50 ) molecules (3840). Thus, oxygen and water were blocked from the molecular layer, preventing BP from being easily degraded by the environment. When BDT was replaced by 2-naphthalenethiol (NAT; a similar aromatic thiol with BDT) for self-assembly on the BP surface (fig. S6), the obtained BP/Al3+/NAT complex demonstrated a stability similar to that of BP/Al3+/BDT (fig. S6E). The enhanced stability of BP/Al3+/NAT can be attributed to the hydrophobic surface (the measured water contact angle was 122.8) and the dense-packed NAT (fig. S6E, inset). However, when a mixture of hydrophobic molecules was used (BDT/NAT = 1/1; fig. S6C), the obtained BP complex was less stable than BP/Al3+/BDT or BP/Al3+/NAT (fig. S6, D to F). Mixed hydrophobic molecule coassembling on the BP surface can induce defects within the closed-packed array (fig. S6, G to I). Thus, although BP/Al3+/BDT-NAT achieved a similar hydrophobicity, water and oxygen invasion would take place at this defect site, inducing degradation of BP (fig. S6F, inset). Therefore, the dense-packed hydrophobic array on the BP surface is also an important factor in isolating oxygen/water for improving the stability of BP.

The ultrastable BP/Al3+/BDT can be deprotected by removal of Al3+ from the BP/Al3+/BDT surface, as shown in Fig. 5A. Here, the removal of Al3+ is realized when EDTA-4Na is added, which is a conventional metal ion chelator (41). The full methodology is described as follows: First, we assess the removal ability of Al3+ in EDTA-4Na aqueous solution. The BP/Al3+/BDT complex is immersed in EDTA-4Na aqueous solution with different concentrations. Then, the residue Al3+ ions on the BP/Al3+/BDT surface are detected via fluorescence photometry using 8-hydroxyquinoline (see the Supplementary Materials for details and fig. S7, A and B) (42). The emission peak at 510 nm, which is a characteristic emission of 8-hydroxyquinoline aluminum salt, disappeared gradually, indicating that Al3+ ions had been successfully removed from the BP/Al3+/BDT surface. The removed amount of Al3+ ions by EDTA-4Na is directly correlated to the concentration of EDTA-4Na. The concentration of EDTA-4Na was 5 mM (fig. S7C). Figure 5B shows that photoluminescence (PL) intensity at 510 nm (Al3+ residue in BP/Al3+/BDT) decreases as incubation time increases in the presence of EDTA-4Na. The relationship between ln (Ct/C0) and time (t) reveals a linear correlation [ln (Ct/C0) = 0.139t + 0.063, R2 = 0.995] (Fig. 5C), where C0 and Ct refer to the loading concentration of Al3+ in BP/Al3+/BDT at an immersion time of 0 and t, respectively. The above analysis indicates that EDTA-4Na is a suitable chelator for the removal of Al3+ from the BP/Al3+/BDT surface. Al3+ ions on the BP/Al3+/BDT surface can also be removed by other chelating agents, such as sodium citrate (SC) and glutathione (GSH) (fig. S7, D to F), thus indicating its great potential for the application in biomedical-related fields.

(A) Schematic illustration of Al3+ ion and BDT removal by EDTA-4Na. (B) Photoluminescence (PL) emission spectra of Al3+ residue on BP/Al3+/BDT after EDTA-4Na treatment. (C) Plot of ln (Ct/C0) as a function of EDTA-4Na treatment time. (D and E) HR-XPS spectra of P 2p, Al 2p, and S 2p for BP, BP/Al3+/BDT, and deprotected BP/Al3+/BDT. (F) Plots of water contact angles and zeta potentials of BP as measured at each protective-deprotective cycle. (G) Polarizing microscope images of bulk BP (0 and 7 days) and bulk deprotected BP/Al3+/BDT (0 and 7 days). (H) Variation of PO43 concentration in solutions of BP and deprotected BP/Al3+/BDT with varying ambient exposure durations. (I) Stability of deprotected BP/Al3+/BDT with a varying residual amount of Al3+ ion on the BP surface. (J) TEM images of BP, BP/Al3+/BDT, and deprotected BP/Al3+/BDT after HAuCl4 (aqueous solution) treatment.

The hydrophobic molecules (BDT) were also removed together with Al3+. The deprotected BP/Al3+/BDT produces a hydrophilic surface with a negative zeta potential (fig. S7G), which is similar to the original BP. The P 2p binding energy of deprotected BP/Al3+/BDT (129.7 and 130.8 eV) is same as that of the original BP (129.6 and 130.7 eV) (Fig. 5D), indicating a resumed electron density on the BP surface. Furthermore, no Al and S signals were found in Al 2p and S 2p. XPS spectra of deprotected BP/Al3+/BDT (Fig. 5E) show the complete removal of Al3+ and BDT from BP/Al3+/BDT. The deprotective process does not affect the BP lattice structure (fig. S7H), Raman spectra (fig. S7I), conductivity (fig. S7J), and inherent photothermal conversion efficiency (fig. S7K).

Our protective-deprotective process achieves the reversible regulation of the BP reactivity. Figure 5F illustrates the plots of water contact angles and zeta potentials of BP measured at each interval of the protective-deprotective process cycles. In the five-cycled protective-deprotective process, the surface properties of BP fluctuate between hydrophilicity and hydrophobicity, and the corresponding zeta potentials of BP exhibit excellent reversibility.

The recovery of surface electron density and surface properties of deprotected BP/Al3+/BDT is supposed to have the same reactivity (such as degradation upon ambient exposure) as the as-prepared BP. As expected, the deprotected BP/Al3+/BDT displays the same degradation behavior as the original BP (Fig. 5G), which completely converts to PO43 after 7 days (Fig. 5H). In addition, the residue amount of Al3+ ions on deprotected BP/Al3+/BDT surface can be rationally tuned via different immersing times of BP/Al3+/BDT in EDTA-4Na aqueous solution. The reactivity of deprotected BP/Al3+/BDT highly depends on the residue amount of surface Al3+ ions (Fig. 5I and fig. S8), demonstrating the efficient approach for regulating the reactivity of BP. Beyond the degradability, the deprotected BP can also be used for further functionalization. As shown in Fig. 5J, the deprotected BP can react with HAuCl4 aqueous solution, and Au nanoparticle-functionalized BP is achieved. We also prove that Al3+-based BP reactivity regulation can be extended to other metal ions such as Fe3+, Zn2+, and lanthanide metal ions (fig. S9). Notably, some metal ions, typically Fe3+ with relatively high oxidizability, enable the oxidation of BP when the normal protective process is applied. For these cases, Fe3+ is linked to the BDT molecule to form the Fe3+-BDT complex before functionalization on the BP surface to yield BP/Fe3+/BDT (see note S4 for details). The slight modification for the protection process can reduce the induced oxidation by metal ions in high valance state, further extending the scope of the developed protective strategy.

To verify this concept, we used the established protective strategy for tuning the reactivity of BP in practical application (e.g., solar vapor generation). BP, BP/Al3+/BDT, and deprotected BP were deposited on hydrophilic poly(vinylidene fluoride) (PVDF) to fabricate BP/PVDF, BP/Al3+/BDT/PVDF, and the deprotected BP film, respectively (fig. S10, A and B; see also experimental details in the Supplementary Materials). BP/PVDF, BP/Al3+/BDT/PVDF, and deprotected BP show similar H2O evaporation rates (fig. S10, C and D), suggesting the same photothermal conversion property of these samples. However, after five cycles, the evaporation rates for the BP/PVDF film gradually decreased (fig. S10E). Further characterization revealed the significant degradation of the BP/PVDF film (fig. S10F), and the BP content in the BP/PVDF film dropped significantly (fig. S10G). In contrast, for the BP/Al3+/BDT/PVDF film, after five cycles, the evaporation rates did not change. No such degradation of BP/Al3+/BDT/PVDF film was observed (fig. S10F), and the BP content in the sample exhibited almost no changes (fig. S10G) after five cycles. The result demonstrates the low reactivity (to oxygen/water) of the protected BP during the solar vapor generation. For the deprotected BP film, its structure
(fig. S10F) and BP content changed significantly, and therefore, similar degradation behavior to that of BP/PVDF film was observed, as expected. Analyzed together, these results suggest the feasibility of using the developed protective strategy for efficient regulation of the reactivity of BP for practical application.

Acknowledgments: We are grateful for the technical support from H. Wang, R. Yu, Y. Yang, and L. Yang from the Department of Physics and College of Materials, Xiamen University. Funding: This study was financially supported by the National Natural Science Foundation of China (21771154), the Shenzhen Fundamental Research Programs (JCYJ20190809161013453), the Natural Science Foundation of Fujian Province of China (2018J01019 and 2018J05025), and the Fundamental Research Funds for the Central Universities (20720180019 and 20720180016). This research was also supported by the Singapore National Research Foundation Investigatorship (NRF-NRFI2018-03). Author contributions: J.X., J.W., and Y.Z. conceived the idea and supervised the project. X.L. performed the experiments and collected the data. L.X. performed the TEM and analyzed the results. W.L. performed the Raman measurements. X.L., J.X., J.W., and Y.Z. analyzed the data and cowrote the paper. C.Z. and Q.X. discussed the results and commented on the paper. Competing interests: The authors declare that they have no competing interests. Data and materials availability: All data needed to evaluate the conclusions in the paper are present in the paper and/or the Supplementary Materials. Additional data related to this paper may be requested from the authors.

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Regulating the reactivity of black phosphorus via protective chemistry - Science Advances

Darren Thompson is a sought-after mentor and chemist who inspires students by opening a new world to them. Hes also an inventor, author of 41 published research papers and holds a Ph.D. in biochemistry.

But to get to this point, Thompson battled depression and had to overcome a dark side.

His brain damage and slurred speech serve as a reminder of a tragic time that Thompson overcame by renewing focus on science, embarking on a mission of saving others and embracing his Christian faith.

The only thing I regret in my life is my decision to try to end it, Thompson said.

Part of the reason Thompson is drawn to helping young people is because professors took a chance on him when he wasnt expecting it.

The other part is because Thompson got a second chance at life.

Back in the early 1990s, Thompson was studying at UC Santa Cruz, when Chemistry Professor Pradip Mascharak pulled him aside one day.

Thompson feared the worst.

I thought he was going to accuse me of cheating on the exam, Thompson said. But no, he said, the way you think, you should be a chemist. I took that to heart.

At the same time, Thompson was playing guitar and performing with the band Anomie.

Thompson was battling depression and probing his emotions through music.

He wrote a song called Not Blessed, which he recorded with the band Faded in 1996 after graduating UC Santa Cruz with highest honors.

I actually thought I was not blessed and could therefore not appreciate the intrinsic loveliness of the objects and people around me, Thompson said.

Smiling while I rage inside, goes one section of Not Blessed. No one sees me shed a tear.

By the time he was 24, Thompson had published 21 research papers and hewas performing and writing innovative, original music.

But he was raging inside.

On May 15, 1998, he attempted to end his life by ingesting cyanide.

Doctors were forced to place Thompson in a medically induced coma for three weeks. He woke up in a different hospital a few miles away and stayed for months.

Before he was finally discharged in October 1998, he spent his 25th birthday in the hospital. He weighed 130 pounds. A physical therapist held him upright.

He needed an electric wheelchair until December 2000.

UC Santa Cruz Professor Glenn Millhauser talked Thompson into going to grad school while Thompson was recovering.

Millhausers lab had fascinating equipment that inspired Thompson, like a mid-80s Bruker EPR spectrometer.

Way cool, Thompson said. Warp speed, Mr. Scott type of stuff.

Finding inspiration in his research, Thompson earned his Ph.D. in chemistry and biochemistry from UC Santa Cruz in 2009. He went on to be a post-doctoral research associate at Californias renown Scripps Research Institute.

But the cyanide poisoning left Thompson with brain damage. He alternated between peaks and valleys. But he noticed a decline in his cognitive abilities when he was doing his post-doctoral research. His speech has been slurred for 23 years. His cerebellum does not send nerve information rapidly. But he gained back 20 pounds and mobility.

Thompson moved to Idaho in 2015 and within a year founded his company, Peptidaho, in the Sagle area. Peptidaho does management consulting and synthesizes two chemicals, one of which (TPG-FLAG) Thompson co-invented.

Thompson wanted to do more with aspiring chemists so when he heard there was a lab in Coeur dAlene he worked his way into the office of Ray Von Wandruszka, University of Idahos chemistry department chair.

They formalized the relationship with the University of Idaho for the unpaid position, which allows Thompson to work with students in the lab as an adjunct professor of chemistry. Its a summer gig, four days a week and about eight hours a day. He focuses on intense research projects and internships with a small number of students.

Most of his students are recommended by a teacher or know another student who studied with Thompson.

Darren (Thompson) is a great vehicle, said Charles Buck, associate vice president and executive officer for the University of Idaho Coeur dAlene. In my years of being around labs and lab rats almost 40 years now it is very unusual.

Tyler Siegford, John Sanchez and Kristen Nethercott are three students who brag about the ways Thompson mentored and inspired them.

For Siegford, it was the lab work and the fact Thompson took a chance on someone with so little chemistry experience.

As a freshman, I was doing real science, said Siegford, who graduated from the University of Idaho earlier this year. I was using expensive instruments and dangerous chemicals to complete a project that had the potential to impact the world.

The research he did with Thompson was one of Siegfords proudest accomplishments. He went on to present at research conferences here in Idaho and in Orlando, Fla.

The research students do in (Thompsons) lab is world-class Seigford said.

Sanchez overheard Siegford talking excitedly about their research, and Sanchez made a point to apply to work with Thompson in the summer of 2019.

I found myself lost on so many topics, Sanchez said. But (Thompson) was there for me. He was patient with me and made a lot of my confusion disappear.

Nethercott studied with Thompson in the lab when she was a high school student in Coeur dAlene in 2019. Now shes studying biochemistry on a full-ride scholarship at the University of Florida.

She credits Thompson with inspiring her interest in the STEM disciplines of science, technology, engineering and math.

I never really struggled in school, but this internship was definitely a struggle and made me work hard to understand the concepts we were working with, she said.

Today, Thompson is raising money for newer, higher-tech equipment for the University of Idahos lab in Coeur dAlene.Donations may madeto the University of Idaho online. Under the designator field scroll down to select UI Coeur dAlene gifts. In the next field marked in honor of type out Dr. Thompsons lab.

Reporter Clark Corbin has covered Idaho government and education for more than a decade. Hes followed every legislative session, gavel-to-gavel, since 2011. Clark is a co-host of the Extra Credit podcast with Kevin Richert published on Fridays. You can follow him on Twitter: @clarkcorbin. He can be reached by email at [emailprotected]

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Faith led professor back to chemistry and recovery - Idaho EdNews

Responding to the introduction of new anti-rape ordinance measures that include the legalization of chemical castration as a form of punishment for repeat offenders, Rimmel Mohydin, South Asia Campaigner at Amnesty International, said:

Forced chemical castrations would violate Pakistans international and constitutional obligations to prohibit torture and other cruel, inhuman or degrading treatment. Punishments like this will do nothing to fix a flawed criminal justice system. Instead of trying to deflect attention, the authorities should focus on the crucial work of reforms that will address the root causes of sexual violence and give survivors the justice they deserve and the protection they need.

Background

On Tuesday 15 December, Pakistans President Arif Alvi signed into law a new anti-rape ordinance that includes measures to speed up rape trials, create a national sex offender registry and allow the chemical castration of repeat offenders. Pakistans government has 120 days to take the measure to parliament and have it permanently passed into law, during which time the law will remain in force.

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Pakistan: Cruel and inhuman chemical castration punishment will not fix flawed system - Amnesty International

Theres a certain expectation to Michigans press conferences after a stunning loss.

Theres deflection and reflection, combined with a fair bit of coach-speak. Players and coaches alike take responsibility without ever divulging enough to pointedly criticize.

It is, by now, a routine well-drilled into Jim Harbaughs Wolverines. They repeat it every year at the start of bowl season a few weeks after losing to Ohio State and a few other times dispersed throughout each season. Such is the nature of Michigans position in college footballs hierarchy good enough for losses to be cataclysmic, not good enough to avoid them all together.

So when graduate student tight end Nick Eubanks diverged from the expectation Monday, it was eye-opening.

We got a lot of younger dudes and chemistry isnt there, Eubanks said on a Zoom call with local media.

Two weeks into the season, five weeks into padded practices and four months into team workouts, the chemistry isnt there. Thats notable.

And in Saturdays 27-24 loss to unranked Michigan State, it was clear from the start, even if it wasnt the defining feature of Michigans offensive performance.

More notable was junior quarterback Joe Miltons lack of comfort in the pocket, as well as his tendency to force passes into double coverage.

There were positives, though, too. Milton threw for 300 yards thanks to a slew of well-delivered passes into tight windows. And at times, he showed good chemistry with his pass-catchers, improvising to find receivers on broken plays.

But a week after a comfortable, commanding performance against Minnesota, Michigans lack of offensive cohesiveness shone through too often.

On this play, Miltons timing with sophomore receiver Mike Sainristil is a touch late. A curl route like this one is all timing. A moment early and Sainristil wont be ready to catch the ball. A moment late and the defensive backs will have adjusted to the route. Either outcome can lead to an interception.

Here, Milton is fortunate to sail his throw, preventing the slot corner from cutting off Sainristils route for a likely pick-six. Still, the lack of timing costs Michigan a six-yard first-down pickup, forcing one of far too many second-and-longs on the day.

Too many drives without getting any points from the drive, Harbaugh said Monday. 12 drives and not enough points per drive. And a lot of that was a lot of second-and-longs.

This first-down play late in the third quarter exhibits another case of Milton lacking chemistry. Sophomore tight end Erick All is lined up in the slot to the left, running a post route over the middle. All seems to recognize the strong-side linebacker dropping over the top of his route and runs a shallower route, cutting over the middle of the field. Milton, though, seemingly expects All to run a skinny post, leading him to throw the ball well behind All.

Milton and All being on different pages here cost Michigan a first down in field-goal range. Three plays later, the Wolverines punted in a game they would eventually lose by three points.

According to Eubanks, building chemistry between Milton and his receiving corps has been an emphasis for Michigan this week.

Just being able to watch film and being able to put in more work in practice, getting the timing right with Joe would be very good in terms of us moving the ball down the field, especially in the passing game, Eubanks said.

For the Wolverines, unlocking the deep passing game would be a critical step toward maximizing their offensive potential. Josh Gattiss offense is at its best when it can spread out opposing defenses, giving its fastest weapons space to make plays.

Through two weeks, though, Milton has struggled to connect with his receivers downfield a problem exacerbated by a lack of chemistry. And when safeties can crowd the box without fear of being beaten over the top, it makes everything else more challenging for both Gattis and Milton.

Original post:
'Chemistry isn't there': Michigan's passing offense aiming to increase cohesiveness - The Michigan Daily

Mars water is being skimmed off the top. NASAs MAVEN spacecraft found water lofted into Mars upper atmosphere, where its hydrogen and oxygen atoms are ripped apart, scientists report in the Nov. 13 Science.

This completely changes how we thought hydrogen, in particular, was being lost to space, says planetary chemist Shane Stone of the University of Arizona in Tucson.

Mars surface was shaped by flowing water, but today the planet is an arid desert (SN: 12/8/14). Previously, scientists thought that Mars water was lost in a slow and steady trickle, as sunlight split water in the lower atmosphere and hydrogen gradually diffused upward, Stone says.

But MAVEN, which has been orbiting Mars since 2014, scooped up water molecules in Mars ionosphere, at altitudes of about 150 kilometers. That was surprising previously the highest water had been seen was about 80 kilometers (SN: 1/22/18).

That high-up water varied in concentration as the seasons changed on Mars, with the peak in the southern summer, when seasonal dust storms are most frequent (SN: 7/14/20). During a global dust storm in 2018, water levels jumped even higher, suggesting dust storms lift water in a sudden splash, Stone says.

The top of Mars atmosphere is full of charged molecules that are primed for rapid chemical reactions, especially with water. So water up there is split apart quickly, on average lasting only four hours, leaving hydrogen atoms to float away (SN: 11/27/15). That process is 10 times faster than previously known ways for Mars to lose water, Stone and his colleagues calculated.

This process could account for Mars losing the equivalent of a 44-centimeter-deep global ocean in the past billion years, plus another 17-centimeter-deep ocean during each global dust storm, the team found. That cant explain all of Mars water loss, but its a start.

Read more:
Chemical reactions high in Mars atmosphere rip apart water molecules - Science News

Chevron Phillips Chemical Co. said it has successfully completed its first commercial-scale production of polyethylene using chemical recyclingand plans to produce 1 billion pounds of the material annually by 2030.

The Woodlands, Texas-based firm made the announcement Oct. 8and said the recycled material matches the performance and safety specifications of its virgin PE.

CPChem spokesman Ryan Draper said the company has a target to produce a total of 1 billion pounds of the recycled PE annually by 2030. He declined to disclose current production but said it was made in the company's Cedar Bayou facility in Baytown, Texas, where it makes virgin PE and other chemicals.

"We are exceptionally proud to be the first company to announce production of a circular polyethylene on this scale in the U.S.," Jim Becker, vice president of polymers and sustainability, saidin the statement. "The successful production run marks a huge step for CPChem on our path to being a world leader in producing circular polymers."

"This development is an important milestone for us as we further our commitment to proactively help the world find sustainable solutions, including the elimination of plastic waste in the environment," he said.

The company said it was a two-year development process, and it is now working on scaling up production.

It also said it is working with suppliers of pyrolysis oil from waste plastic as a feedstock and is seeking to have the material certified by the International Sustainability and Carbon Certification Plus program. It plans to market it under the trade name Marlex Anew Circular Polyethylene.

"This advanced recycling technology allows us to recover hydrocarbons from plastic waste that have previously been difficult, or even impossible to recycle, enabling us to upgrade them into clean, safe circular plastics," said Ron Abbott, CPChem's sustainability technical manager.

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CPChem touts PE chemical recycling success, targets billion pounds of production by 2030 - Plastics News

The 2020 Pittsburgh Steelers have something special going on. Yes, they are 5-0 as they head to Nashville to take on the only other remaining undefeated team in the AFC. But there is something else to the Steelers team, and the more Steelers fans understand it the more they need to appreciate the Steelers front offices willingness to protect it.

The Steelers locker room is really something special.

Sometimes fans get it and sometimes they just dont see this aspect of the game. When a team comes together in the locker room, theres so much more they can do on the field. Of course its easier to have a good locker room when a team is winning, but this started long before the Steelers took the field for the first time in 2020.

Going through the different training camp setting required this season, the Steelers had a different mentality. From the beginning head coach Mike Tomlin made the statement of Its one fail, all fail which speaks both to the teams mentality when it comes to Covid procedures as well as the season in general. By players and personnel needing to take the precautions needed to in order to make this season happen, it appears it has brought this team together even more. Add the fact not one single Steelers player opted out for the season already and it felt like something special was going on with this team from the very beginning.

As the season progresses, more evidence continues to emerge about the quality the Steelers locker room. Ben Roethlisberger cannot say enough about his young wide receivers. Remember, Roethlisberger is only seven games removed from having a team which included Antonio Brown. Seeing the Steelers Pro Bowl wide receiver JuJu Smith-Schuster smiling and happy after a win where he had a minimal contribution shows the difference in this wide receivers room which Roethlisberger hasnt seen for a long time.

For those who may not have seen Thursdays Minkah Fitzpatrick interview, T.J. Watt and Bud Dupree decided to drop in and take over for a while. It was quite comical for anyone watching as Fitzpatrick burst out into laughter at their responses. While many may put this into just people having fun, the fact that they can have fun and not feel like theyre stealing each other spotlight is something to be noted.

Another example of the Steelers locker room being different is Steelers tight end Eric Ebron. One of the biggest complaints about Ebron coming into 2020 was his presence in the locker room in his previous stops in the NFL. What has happened since hes come to the Steelers? There havent been any problems reported. Additionally, Ebron is jumping for joy on the sidelines at Steelers games.

So whats the big deal? Why even talk about the Steelers locker room chemistry? Whether its great or if its terrible, does it really matter if the team is winning?

Yes, it does.

The biggest thing the Steelers need to make sure they do this season is not screw it up. As the trade deadline approaches, many feel the Steelers could possibly make a move to bolster their roster. But as much as a player can bring to the field, the Steelers also need to be aware of what the player would bring to the locker room.

I understand that just because someone has a black and gold T-shirt and a smart phone it doesnt mean they speak for Steelers Nation. There are plenty of takes presented on social media, many of which are absolutely terrible. Im going to highlight one or two that Ive seen from multiple places and show how little they consider locker room chemistry.

The Steelers need to trade JuJu NOW! Theyre going to get nothing from him if they dont.

Why are the Steelers concerned about getting something in return for a player who may or may not leave via free agency following this season? The Steelers are 5-0. This year is what its all about. Not only that, why would the Steelers even consider taking their locker room leader in the wide receivers room and shipping him off somewhere else? What message does that send to the other young players on the team? What if JuJu Smith-Schuster is the glue that holds them all together?

Im not going to quote the next one exactly, but even some former Steelers has chimed in on the topic of the Steelers trading for Dwayne Haskins. I dont understand the point. First, what are they going to have to give up to get him? Next, how is he going to help the Steelers win in 2020? And finally, why would the Steelers disrupt a quarterback room which appears to be functioning quite well?

In case youre wondering why I make the statement about a well-functioning quarterback room, its based on the James Washington touchdown in Week 6 against the Cleveland Browns. The story about this play is it was presented to Ben Roethlisberger on the sidelines by third-string quarterback Josh Dobbs who saw something where he thought it would work.

The reason this is such a big deal is Ben Roethlisberger is trusting the other players in the quarterback room. Why would Ben Roethlisberger listen to Dobbs unless these guys have something going on? Roethlisberger has been doing this more than all the other guys in the room combined, but yet Roethlisberger listened to Dobbs, Steelers scored a touchdown, and Roethlisberger gave Dobbs the credit.

How much do fans really know about the Steelers locker room? We can look for evidence through various things, but its really difficult to find out the information with certainty. After the fact, we found out so much about Steelers superstars from several years ago and the issues going on. But from everything that is coming out in 2020, this is not the case with this team. This team is rolling on and off the field.

As a Steelers fan, remember the importance of locker room chemistry, specifically in season. Yes, it would be nice if the Steelers could go out and compile as much talent as possible before the trade deadline. But if theres any question as to whether or not its going to upset the balance in the locker room while this team is on a roll, then dont even bother picking up the phone.

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Locker room chemistry is a key component the Steelers success in 2020 - Behind the Steel Curtain

The sound when the cork pops out of the bottle is satisfying isnt it? But what disappointment if at that very first sip the look of pleasure and anticipation turns to disgust when the off flavors of a faulty wine hit your tongue thats if it even gets past your nose.

There are seven common faults that can be identified in wines, although a limited degree of some may be appreciated as pleasant by some consumers. These faults include oxidation (in excess), reduction, Brett (caused by Brettanomyces yeast), excess sulfur dioxide (SO2) (naturally produced during wine making and used to stabilize wines), volatile acidity, out of condition (over-age, bad storage) and last but by no means least 2,4,6-trichloroanisole (TCA), more commonly known as cork taint.

In the article we are going to focus on cork taint a fault not appreciated by anyone in the wine production, retail or consumer chain.

Cork is a natural product, stripped bark from the cork oak (Quercus suber). Consequently, as with any food or beverage product, good agricultural practice is necessary to minimize contamination by unwanted microbes during processing, transport and storage. Because of the nature of corks source, typical contaminants include soil-borne bacteria, yeasts and most commonly fungi. It is a subset of these fungi that are associated with cork taint. Species most frequently associated with cork taint include isolates from the genera Trichoderma and Fusarium, although other fungal species are also known to be involved.

To defend itself from fungal attackers, the tree produces phenolic compounds. In retaliation the fungi defend themselves by methylating the phenolic compounds which makes them less toxic, resulting in compounds such as anisole. When anisole then comes into contact with chlorine, which is frequently used as an antimicrobial during cork sterilization, it is converted to TCA et voila! If an affected cork is then used to stopper a bottle of wine, the compound is transferred into the wine as it comes into direct contact.

Cork taint is a harmless to health, naturally-occurring fault in bottles of wines closed by corks. It results in a very unattractive, moldy, wet cardboard smell that additionally reduces the fruit character of wine (it has nothing to do with pieces of cork breaking off and being seen in the bottle or glass). It can be detected by tasters at very low concentrations commented David Way, Wine Qualifications Developer at the Wine and Spirit Education Trust (WSET). Whilst the characteristics of cork taint have been described as a fault for decades, it wasnt until the 1980s that the compound responsible for taint was actually identified1, 2.

It has been estimated that 2-7% of wines suffer from cork taint3, 4; not only disappointing for the consumer but resulting in economic loss for producers and retailers. Thats aside from the sacrilege of potentially losing rare fine wines. However, these figures are reducing as the cork industry seek to address the issue.

A group of trained wine judges were put to the test and a geometric mean of the minimum detectable concentrations of TCA determined at 4.6 ng/L. Levels in the wines themselves below this should theoretically be undetectable to consumers and therefore offer a maximal threshold for acceptable limits of cork-to-wine transfer.

A host of laboratory-based analytical techniques can be applied to wines to determine if they contain TCA. Headspace solid phase microextraction (SPME) in combination with gas chromatography-mass spectrometry/ selective ion monitoring (GC/MS-SIM) has been shown to work well in detecting TCA in wines. SPME has also been used on wines and cork material to detect TCA at levels beyond olfactory detection. Headspace SPME and heart-cut multidimensional gas chromatography with tandem mass spectrometric detection has also proved effective. However, from a production point of view, every cork is an individual, so short of uncorking and testing every wine before it is sold, these techniques are not helpful in preventing cork taint in the first place.

In terms of whole, natural corks, the primary focus of efforts has been on identifying corks that contain TCA to prevent them reaching the bottling line.

A non-destructive technique called the dry-soak method was and is still used in some places to detect individual corks containing TCA. Here, every large format cork is held individually in a sealed glass jar containing 5-10 drops of de-mineralized water. Over 48 hours, the moist environment volatizes the TCA and then the corks are sniffed by a human expert panel. A study comparing this technique to chemical analysis by GC-MS found the dry-soak method effective in detecting tainted corks. However, this technique is labor intensive and due to sensory fatigue, only around 200 corks can be sniffed in one sitting, stopping for breaks every 50 corks. It may be effective, but this is therefore certainly not a method suited to a high throughput environment.

Given the sheer volume of corks used in the wine industry there is clearly a need for a quantitative, automated system for accurately detecting and rejecting affected corks.

A number of groups in both academia and industry, fostering collaboration between chemists and the cork industry, have successfully sought non-invasive, sensing device solutions that detect volatile organic compounds (VOCs), including TCA, on individual corks, rapidly.

A multi-center EU-funded project successfully developed an electronic nose, consisting of a sensor array, capable of detecting TCA down to 2 ng/L at a rate of 250 corks per hour. Whilst promising, the project has however not produced a solution available to producers. Whilst they can be useful technology, electronic noses lack the sensitivity required to detect TCA at the levels required and as such dont provide a solution for detecting affected corks currently commented Professor Ulrich Fischer, Head of the Institute for Viticulture and Oenology, Service Center for Rural Areas (DLR) Rheinpfalz, Germany.

A partnership was able to create a similar GC-based system with an analytical detection limit of a mere 0.5 ng/L, well below that detectable by a consumer. Each cork is checked individually with the cork sniffers currently able to test one cork every 16 seconds, each typically checking around 34,650 corks a week. But the goal is one every 10 seconds!

An alternative based on gas phase spectroscopy, also a result of industry-academia collaboration, analyzes corks one-by-one in an automated system and can be used on washed and unwashed corks. It too has a limit of detection of 0.5 ng/L and takes just 5 seconds to analyze each cork.

Seems like a huge waste of natural resources you may be thinking but fear not! Rejected corks can still find a useful life in applications such as flooring and gaskets.

An alternative approach is to prevent the formation of TCA in the first place by sterilizing and reconstituting the cork. The cork industry has responded with two main approaches cleaning cork with steam or creating closures with recomposed cork particles that have been cleaned and reconstituted with plastic. These responses are probably what has led to the reduction in corked bottles in recent years and give wine consumers the familiar ritual of opening a bottle with a corkscrew commented Way.

Corks fragments that have been sterilized with supercritical CO2 and glued back together have been a huge success in the wine industry. As the compounds used to reform them do not contain plasticizers they have been well received and accepted by many as a good and safe alternative to whole natural corks commented Fischer. He continued, Reconstitution also enables manufacturers to control the porosity of the corks to oxygen so they can be tailored to different types of wine. A red Bordeaux for example may benefit from a cork that enables greater oxygenation to develop its character, whilst a Riesling from Germany may benefit from less oxygenation to retai
n the floral aromatic character of the wine.

Recently, a Swiss group have developed a membrane that is able to filter TCA out of wines. Fischer continued, This is an exciting development for wine producers and suppliers. Whilst not economically viable for wines at the cheaper end of the market, it ensures rare and expensive wines are not lost and means suppliers are able to provide the vintages their customers want.

Plastic corks and screw cap closures have gained popularity in many parts of the world, particularly in New World wines. However, they are still fallible with compromised seals resulting in leakage and spoiled wines from excessive oxidation.

Synthetic closures avoid the hazards associated with TCA, but they lack the microporous properties of cork that allow minute quantities of oxygen into the bottle. Whilst excessive oxygenation is undesirable, small quantities of oxygen are a necessary part of the bottle ageing process that help to develop the tertiary characteristics of the wine think savory, meaty notes in a red, or honeyed, dried fruit in a white wine.

Therefore, whilst rubber corks and screw caps may be a good solution to protecting wines bottled for immediate consumption, they are not appropriate for premium wines that are designed to be bottle matured for a number of years.

Non-traditional corks are a very much contentious subject within the industry and the strength of opposition such that in some regions any closure except natural cork is banned under local wine production regulations.

The main approaches to dealing with cork taint have been either to use other types of closure, especially screw caps, or to ensure that corks do not contain TCA. Screw caps have been widely adopted in Australia and especially New Zealand (among many other countries) and have been accepted, especially for inexpensive and mid-priced wines in some markets, for example, the UK. There has been less take up by wine makers in Europe and less acceptance of alternative closures in some major market, such as France, Italy and the USA (although attitudes are changing in the last named) concluded Way.

Researchers have been developing new cork-free screw caps that incorporate a breathable liner, enabling micro dosing of oxygen into the bottle. It is still however early days and they have not been widely adopted so it is unlikely you will pick one up off the supermarket shelf anytime soon.

Aside from their physical and chemical properties, studies have shown that many consumers prefer natural corks and it impacts their perception of quality, an important consideration for wine producers and retailers wishing to get the best price for their wines.

Despite the potential shortcomings of natural cork. It is worth considering the green, biodegradable and renewable nature of cork over alternatives. Cork oaks grow for around 25 years before the first harvest, benefitting the environment and providing habitat. Once harvested a skillful job, the bark of the cork oak regrows too, and can be harvested every 8-14 years, offering long-term productivity.

References

1.Tanner H, Zanier C, Buser HR. 2,4,6-Trichloranisol: Eine dominierende komponente des korkgeschmacks, Schweiz. Z. Obst-Weinbau. 1981;117:97-103.

2.Buser H, Zanier C, Tanner H. Identification of 2,4,6-trichloroanisole as a potent compound causing cork taint, J. Agric. Food Chem. 1982;30:359-362.

3.Silva Pereira C, Figueiredo Marques JJ & San Romo MV. Cork taint in wine: Scientific knowledge and public perception A critical review. Critical Reviews in Microbiology. 2010;26(3):147-162. doi:10.1080/10408410008984174

4.Butzke CE, Evans TJ, Ebeler SE. Detection of cork taint in wine using automated solid-phase micro extraction in combination with GC/MS-SIM. Chemistry of Wine Flavor, 1998;15:208-216. doi:10.1021/bk-1998-0714.ch015

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Using Analytical Chemistry To Put an End to Corked Wine - Technology Networks

WASHINGTON Howard University chemical engineering associate professor and Director of Graduate Studies Preethi Chandran, Ph.D., has received a $500,000grant from the National Science Foundation through the Excellence in Research (EiR) program to study the biophysics of the shield of sugars, or glycans, that typically can shield pathogens.

One may think of the sugars found in glycan shields as gooey, sticky stuff that coats cells, Chandran says. Our goal is to find the order in the gooey-ness so we can predict where a pathogen like SARS-Cov-2, the virus that causes CoVID-19, would stick to itself or to mucus, or if it would just slip past the scouts of the immune system and therapeutics as well, explains Professor Chandran.

By deconstructing how the glycan shield protects pathogens, scientists can design strategies to breach the shield so that a broad spectrum of pathogens can be made vulnerable to detection, sanitizing, and treatment, Chandran says.

Chandran is the co-lead investigator on the research project with Sergei Nekhai, Ph.D. Howard University Center for Sickle Cell Disease deputy director and professor of biochemistry. The research will incorporate a team of undergraduate and graduate student researchers. An important objective is to discover holistic and economical approaches to combat the onset of infections. Ultimately, Chandran aims to develop new methods to study the interfacial dynamics of biomolecular surfaces and assemblies and to redirect naturally occurring biological interactions for a wide range of scientific applications.

Awards granted by the EiR program at NSF encourage and support potentially transformative research by outstanding scientists and researchers at HBCUs, says Interim Chair of the Department of Chemical Engineering Patrick Ymele-Leki, Ph.D. Our department is very fortunate to currently work on four separate projects supported by these highly competitive awards, and we are proud of the work done by Dr. Chandran and her colleagues to receive these grants.

About Howard University

Founded in 1867, Howard University is a private, research university that is comprised of 13 schools and colleges. Students pursue studies in more than 120 areas leading to undergraduate, graduate and professional degrees. The University operates with a commitment to Excellence in Truth and Service and has produced one Schwarzman Scholar, three Marshall Scholars, four Rhodes Scholars, 11 Truman Scholars, 25 Pickering Fellows and more than 165 Fulbright recipients. Howard also produces more on-campus African-American Ph.D. recipients than any other university in the United States. For more information on Howard University, visit http://www.howard.edu.

For media inquiries, please contact Sholnn Freeman, sholnn.freeman@howard.edu

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Howard University Chemical Engineering Professor Awarded $500K NSF Grant for Research on Biological Surfaces and Pathogens - Howard Newsroom

Thursday marks the restart of widespread testing for PFAS chemicals in New Hampshires public water supplies, after a year-long delay due to a lawsuit from PFAS-maker 3M.

PFAS are industrial chemicals, widely found in groundwater and linked to health problems including liver and kidney disease, high cholesterol and reproductive, developmental and immune issues, as well as potentially some cancers.

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The chemicals were common until at least the early 2000s in many household products, but aren't subject to binding federally regulations. New Hampshire is one of a small but growing number of states with its own PFAS limits.

The state Department of Environmental Services briefly enacted these new rules last year, before a judge granted an injunction that halted enforcement. This summer, the state legislature re-authorized the limits itself and put an end to the court case.

Starting Thursday, public water systems of all sizes, as well as schools, will have to test on a quarterly basis for four kinds of PFAS in their water supply.

If their average levels over four consecutive quarters exceed any the state's limits, which are some of the strictest in the country, they could have to invest millions of dollars in treatment technology or new water sources.

Brandon Kernan, the head of the DES Drinking Water Bureau, told NHPR that voluntary sampling from 2016 to 2019 showed close to 200,000 people affected by PFAS contamination.

It means contamination was present at one time in 7% of water systems, serving more than a quarter of public water users in the state. The state says this rate is comparable to a naturally occurring contaminant.

Kernan said in an email that many systems have since addressed the issue: in many cases the source of water has been taken offline, blended with another source to reduce PFAS levels or had treatment installed.

Several hundred systems also conducted tests at the end of 2019 to comply with the new limits before the court injunction took effect. Most were small housing developments and schools, along with some larger systems.

Kernan said data on those tests compiled in March showedexcessive PFAS levelsin about 5% of systems.

The state says it will offer water systems a waiver to use that fourth-quarter 2019 data as part of their average results over the next year.

Jason Randall is the superintendent of the Plymouth Village Water and Sewer District, one of the plaintiffs recruited by 3M to join the lawsuit that delayed the rules last year. He told NHPR in an interview that Plymouth did not test for PFAS at the end of 2019, but will begin doing so this quarter.

Randall is still concerned that the new PFAS limits and others planned in the next few years will create uncertainty for water ratepayers. He calls the cost of testing an expense up and coming for Plymouth, and says the cost of any potential treatment is still an unknown at this point.

The state is in the process of launching a new $50 million low-interest loan fund to help systems comply with the rules. Other sources, like federally-backed drinking water revolving loans and the state Drinking Water and Groundwater Trust Fund, could also be used.

New Hampshire is also part of a huge lawsuit against PFAS manufacturers like 3M and DuPont. Similar suits have netted hundreds of millions of dollars for contaminated areas in the past. New Hampshire will augment the new loan fund with any settlement it may eventually receive.

Support NHPR's award-winning local news reporting - become an NHPR member today.

Continued here:
Public Water Testing For N.H. State PFAS Chemical Limits To Begin After Year-Long Delay - New Hampshire Public Radio

Looking for a hands-on science project to do with your children this fall? The U.S. Crystal Growing Competition is back.

Held annually since 2014, the contest challenges K-12 students and teachers to grow the biggest, most beautiful crystals they can using aluminum potassium sulfate (alum), a nontoxic chemical used in water purification.

This year, the contest takes on new meaning, with many schools across the country operating under a remote or hybrid learning model, says founder Jason Benedict, a UB chemist with two school-aged kids.

Now, more than ever, with so many kids being at home, they need fun, hands-on scientific activities, says Benedict, associate professor of chemistry, College of Arts and Sciences. Growing crystals means they can take a break from their screens and do an exciting activity thats going to teach them something about crystals and crystal growth. You can do this as a family.

Crystals are really special objects where all of the ions or molecules are lined up in repeating patterns. People are exposed to crystals in a variety of ways in their daily lives. Snowflakes, for example, are all crystals. Salt and sugar are crystals. There are crystals inside of computers. Pharmaceuticals are crystalline. Well-tempered chocolate is an example: The snap of a well-tempered piece of chocolate is because the chocolate has a particular crystal form inside of it.

The contest is open to K-12 students and teachers, whether they are back in the classroom or learning at home. Participants can register for the competition by filling out the 2020 entry form and ordering bottles of crystal-growing material for $8. The deadline to order alum is Oct. 1.

Crystal-growing begins on Oct. 19, coinciding with National Chemistry Week, and goes on for five weeks. In addition to categories judging crystals by size and quality, the contest will again include a coolest crystal category that awards participants for cultivating crystals with a creative flourish, whether that means coloring crystals, trapping an object inside of them or implementing some other innovation.

Winners in various categories will be able to choose between cash prizes or hands-on magnetic science models that kids can manipulate to learn about crystal structures.

During the competition, teachers, students and families can share their excitement with the community of crystal-growers by posting updates on Twitter using the contests hashtag, #2020USCGC, Benedict says.

Submissions will be judged at UB.

The 2019 competition reached about 150 teams representing thousands of K-12 students and teachers, and homeschooling families in 33 states.

The experience of growing a sparkly, single crystal from scratch can be memorable for children.

Each team or participant starts with 100 grams of powdered alum. To grow a crystal, kids dissolve the material into water, then let the water evaporate. This causes the compound to emerge from the solution to form a crystal.

Its work that requires patience and finesse: If the water evaporates too quickly, too much of the alum will crystallize, causing imperfections such as occlusions or jagged edges (think rock candy). Go too slow, and youll get a miniscule crystal.

If the participants have half as much fun growing their crystals as we do receiving them, were going to have a lot of happy kids, parents and teachers, Benedict says.

Here are some how-to videos for growing large, single crystals:

The U.S. Crystal Growing Competition is sponsored by the American Crystallographic Association (which is based in Buffalo), the National Science Foundation, VWR and Wards Science, the UB Department of Chemistry, Georgetown University, the Texas A&M Department of Chemistry, the University of Central Florida Department of Chemistry, the University of Chicago Pritzker School of Molecular Engineering, the Western New York section of the American Chemical Society, Bruker, The Cambridge Crystallographic Data Centre, Krackeler Scientific and Rigaku, along with individuals who have made donations. To make a gift to support the contest, visit the competitions fundraising page.

Originally posted here:
Crystal competition offers socially distanced chemistry for kids - UB Now: News and views for UB faculty and staff - University at Buffalo Reporter