"This so-called chemistry has to be developed much before actors come in front of the camera," says Kunal who can be credited for some crackling chemistry he brought alive between his actors in films like HUM TUM and FANAA, "It is also the function of the script because in order to get those lovey-dovey encounters come alive on screen, you first need to get them right on paper."

CHECK OUT: Neha Sharma is Shahid's love interest in TERI MERI KAHAANI!

Kunal worked on that by writing the characters of Shahid and Priyanka in such a manner that they turned out to be extremely endearing.

"The thing is that today's ever demanding audience wants something different from its actors all the time. They want Shahid to do different things and push the envelope. This was the demand of TERI MERI KAHAANI as well as we are indeed doing something altogether different in the film. That made me zero in on Shahid," divulges Kunal, "As for Priyanka then well, she hasn't done too many love stories; especially a film like TERI MERI KAHAANI which is an out and out romantic entertainer. I felt that it was about time we bring her and Shahid together in a quintessential music love story like this."

Also starring Neha Sharma and Prachi Desai in principal roles, TERI MERI KAHAANI with music by Sajid-Wajid releases all over on 22nd June.

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Shahid-Priyanka chemistry had to be developed

LINCOLN Ryker Fyfe and Sam Foltz know each other pretty well.

The two former Grand Island Senior High athletes played football together for four years. Now, theyre heading as walk-ons to play for Nebraska this fall in Lincoln.

But before that, they have one more chance to hook up on a long pass or maybe a slant across the middle as teammates on the North team at the 2012 Shrine Bowl at 1:30 p.m. Saturday at Memorial Stadium in Lincoln.

Definitely the slant, Foltz said when asked about his favorite play Thursday at the Shrine Bowl Media Day at Nebraska Wesleyan University. Its hard to defend the slant.

Fyfe had a different favorite.

The deep ball is pretty nice, Fyfe said. I like that route. He can run fast. He can catch. Hes big and strong.

How about the slant?

The slant? Fyfe said. Our timing is good, so that works, too.

Just about everything worked for Fyfe and Foltz during their senior season last fall. The two were key players in the Islanders 9-2 season that ended in the second round of the state playoffs.

The 6-foot-5 Fyfe finished the year as one of the top passers in Class A, completing 120-of-204 passes for 1,921 yards and 20 touchdowns.

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Chemistry key for Fyfe, Foltz

Attrition, as John Beilein puts it, is normal.

While statistics show that the Michigan basketball coach is probably right, there's nothing ordinary about having to replace five bodies inside every corner of your program.

Five new faces at practice, five new voices in the locker room, five new plates at the dinner table -- and five new personalities that need to be meshed together in an incredibly short amount of time for a program with extremely lofty immediate expectations.

Is Beilein worried?

Not really. He's the opposite, actually.

"My early sense for the younger guys coming in, I've watched some of them for three years, some for three months," Beilein told reporters earlier this month. "But I sense that they're all really good teammates, and they'll enhance team chemistry the minute they walk out here.

"Because they really have a great spirit about them."

Beilein expected to lose departed senior co-captains Zack Novak and Stu Douglass, the team's backbone, but didn't think he'd have to replace three other bodies.

That's exactly what happened, though, when Evan Smotrycz, Colton Christian and Carlton Brundidge left the program shortly after the season closed.

Michigan coach John Beilein believes his five incoming freshmen will enhance team chemistry because "they really have a great spirit about them."

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Chemistry 101: John Beilein says 5 new elements will help Michigan basketball team's cohesion

Public release date: 31-May-2012 [ | E-mail | Share ]

Contact: Michael Bernstein m_bernstein@acs.org 202-872-6042 American Chemical Society

WASHINGTON, May 31, 2012 The latest episode in the American Chemical Society's (ACS') award-winning Global Challenges/Chemistry Solutions podcast series explains that meeting current biofuel production targets with existing technology would require devoting almost 80 percent of current farmland in the U.S. to raising corn for ethanol production or converting 60 percent of existing rangeland to biofuels.

Based on a report by W. Kolby Smith, Ph.D., and colleagues in ACS' journal Environmental Science & Technology, the new podcast is available without charge at iTunes and from http://www.acs.org/globalchallenges.

Smith and colleagues explain that the 2007 Energy Independence and Security Act (EISA) set a goal of increasing U.S. biofuel production from 40 to 136 billion gallons of ethanol per year by 2022. They point out, however, that gaps exist in the ability to establish realistic targets for biofuel production, which the law fills with assumptions about technological developments and the availability and productivity of farmland. In an effort to establish more accurate estimates, they used satellite data about climate, plant cover and usable land to determine how much biofuel the U.S. could produce.

The satellite analysis found that meeting the EISA goals with current technology would require farmers to plant biofuel crops on 80 percent of their farmed land or plant biofuel crops on 60 percent of the land currently used to raise livestock. Both options would significantly reduce the amount of food U.S. farmers produce. The changes also could lead to more polluted freshwater and accelerate global climate change, the report indicated.

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Global Challenges/Chemistry Solutions is a series of podcasts describing some of the 21st century's most daunting problems, and how cutting-edge research in chemistry matters in the quest for solutions. Global Challenges is the centerpiece in an alliance on sustainability between ACS and the Royal Society of Chemistry. Global Challenges is a sweeping panorama of global challenges that includes dilemmas such as providing a hungry, thirsty world with ample supplies of safe food and clean water; developing alternatives to petroleum to fuel society; preserving the environment and assuring a sustainable future for our children and improving human health.

For more entertaining, informative science videos and podcasts from the ACS Office of Public Affairs, view Prized Science, Spellbound, Science Elements and Global Challenges/Chemistry Solutions.

The American Chemical Society is a nonprofit organization chartered by the U.S. Congress. With more than 164,000 members, ACS is the world's largest scientific society and a global leader in providing access to chemistry-related research through its multiple databases, peer-reviewed journals and scientific conferences. Its main offices are in Washington, D.C., and Columbus, Ohio.

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Meeting biofuel production targets could change agricultural landscape

Source: ISNA

Chemistry Nobel Laureate Peter Agre, Professor and Director of the Johns Hopkins Malaria Research Institute and Dr. Norman Neureiter the Acting Director of Center for Science, Technology & Security Policy of American Association for the Advancement of Science and the first US scientific ambassador to Europe are to arrive in Tehran in coming days.

Dr, Norman Neureiter is scheduled to deliver a lecture on "International Cooperation on Science and Technology Diplomacy, Opportunities and Challenges in the 21 Century" in Iranian Shahid Beheshti University on June 11.

Also Professor Peter Agre will attend the ceremony.

Peter Agre born on January 30, 1949 is an American medical doctor, professor, and molecular biologist who was awarded the 2003 Nobel Prize in Chemistry (which he shared with Roderick MacKinnon for his discovery of aquaporins. Aquaporins are water-channel proteins that move water molecules through the cell membrane.

In February 2009, Peter Agre was inducted as the 163rd president of the American Association for the Advancement of Science (AAAS), the nation's largest scientific organization. He is currently a professor at Johns Hopkins University.

He received his B.A. from Augsburg College in Minneapolis and his M.D. in 1974 from the Johns Hopkins University School of Medicine in Baltimore, Maryland.

From 1975 to 1978 he completed his clinical training in Internal Medicine at Case Western Reserve University's Case Medical Center under Charles C.J. Carpenter.

He served as the Vice Chancellor for science and technology at Duke University Medical Center in Durham, North Carolina, where he guided the development of Duke's biomedical research.

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US Chemistry Nobel Laureate to arrive in Tehran

(credit: Al Bello/Getty Images)

By Rich Coutinho More Columns

Over the course of a long baseball season, there will be ups and downs, injuries curtailing winning streaks. But allsuccessful teams have one constant: leadership.

Chemistry in the clubhouse.

It can extend winning streaks and snap losing streaks. The Mets have great chemistry, and thats been been of the biggest reasons New York sits in second place in the competitive NL East.

They came into the season with all the experts saying they had too many holes, not enough depth and inferior starting pitching. The fans, for the most part, bought that snow job hook, line and sinker. Thats all they heard from the media. But make no mistake about it the Metsare serious playoff contenders 50 games into the season.

Thatsright Iused the P word.

You want leadership? There are no better in this sport than Johan Santana and David Wright, who lead the right way. They dont do it for the world to see by throwing over a table or scolding a teammate. They do it by example. The younger players see Wright and Santana are the first to arrive, embrace their responsibility to the media, and compete.

Terry Collins deserves a bunch of credit for motivating these players, and so does his coaching staff. Consider the job Tim Teufel has done with Daniel Murphy at second base. Murphy will never be confused with Bill Mazeroski around the bag, but he has been serviceable due in large part to the amount of work he and Teufel put in during the offseason. And that has kept his potent bat in the lineup.

The numbers dont lie. The Metsare 16-10 at Citi Field and 12-12 on the road, the formula for a winning season. Theyre also 15-8 against the National League East, which is why they are only one and half games from the top spot in the division. What they lack in talent they make up for in resiliency, and that speaks to team chemistry. I have never been around a team that pulls for each other like this team even when one player is in competition with another for playing time.

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Coutinho: Great Team Chemistry Has Fueled Mets’ Success

If you want to increase your cars gas mileage or build a more powerful handheld electronic device, dont bend steel or slice silicon chips. Manipulate nanomaterials and molecules instead.

Funded by the U.S. Department of Energy, two University researchers will pursue more efficient methods of energy transmission and storage that involve maneuvering microscopic particles. Tina Salguero and Gary Douberly, assistant professors of chemistry in the UGA Franklin College of Arts and Sciences, will each receive $750,000 for five years from the DOEs Office of Science Early Career Research Program for energy-related projects.

Gary Douberly

This is tremendous news that continues the very strong performance of the chemistry faculty in recent years, said UGA President Michael F. Adams. At a time when this country faces serious questions about the future of its energy supply, research focused on energy efficiency is a national priority. I am proud that Drs. Salguero and Douberly are being supported by the Department of Energy in their groundbreaking research.

Salguero will focus on increasing the energy capacity for compact electrical devices while Douberly looks to new technologies to improve fuel efficiency.

Tina Salguero

Our efforts will develop the first synthetic methods for creating these types of nanosheets, and the characterization studies will show whether they retain their important dielectric properties, she said.

Salguero plans to develop methodologies for preparing ceramics in nanosheet form and to gauge their properties. She will also test two ways to process the nanosheets-first via inkjet printing of liquid crystalline nanosheets and second by mechanically assembling alternating layers of conducting and non-conducting materials to build up dense, hybrid nanosheet structures capable of greater energy storage.

Devices using this technology would have an energy density far exceeding anything possible today, Salguero said. Ceramic nanosheets could enable technological wonders like handheld high-power lasers and mobile electromagnetic launchers.

Douberly will use his funding to capture short-lived molecules and free radicals-highly reactive molecules-that arise during engine ignition. He will use a method called helium nanodroplet isolation to hold molecule groups-or species-that form for brief moments during combustion. Douberly will capture the molecules inside drops of super-cooled liquid helium and subject them to infrared laser spectroscopy to determine their molecular structure and their unique combinations of electromagnetic radiation wavelengths, or spectroscopic signatures.

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UGA chemistry professors awarded $1.5 million to conduct energy-related research

Wayne State University's Department of Chemistry is among the top 100 in the world, according to the latest ranking by the Academic Ranking of World Universities (ARWU). More than 1,000 universities were ranked in 2011, and the best 500 are published at http://www.shanghairanking.com/.

The ARWU uses six indicators to determine rankings. WSU received high marks in three: highly cited researchers, papers in the Science Citation Index, and percentage of papers published in the top 20 percent of journals.

"The chemistry department is excited to learn that we have been ranked among the elite chemistry departments in the world.Our inclusion among the best in the world is a welcome recognition of our efforts over the last several years to make Wayne State chemistrytruly first-rate in both teaching and research.With the recent opening of the newly renovated A. Paul Schaap Chemistry Building, we are well-positioned to move to the next level of excellence," said Jim Rigby, chemistry department chair.

The only other Michigan university receiving top 100 honors in chemistry was the University of Michigan-Ann Arbor.

The ARWU uses six indicators to determine rankings. WSU received high marks in three: highly cited researchers, papers in the Science Citation Index, and percentage of papers published in the top 20 percent of journals.

"The chemistry department is excited to learn that we have been ranked among the elite chemistry departments in the world.Our inclusion among the best in the world is a welcome recognition of our efforts over the last several years to make Wayne State chemistrytruly first-rate in both teaching and research.With the recent opening of the newly renovated A. Paul Schaap Chemistry Building, we are well-positioned to move to the next level of excellence," said Jim Rigby, chemistry department chair.

The only other Michigan university receiving top 100 honors in chemistry was the University of Michigan-Ann Arbor.

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WAYNE COUNTY: Wayne State chemistry department among top 100 worldwide

Credit: Nathan Walker, CC BY 2.0

Dave Kepler, chief sustainability officer at Dow Chemical Co., believes that to meet the demands of a burgeoning population, we will need more sustainable products and infrastructure in short, a more sustainable economy.

Writing for GreenBiz, Kepler says sustainable chemistry will play a key role in meeting the increasing demands for material goods in an environment of tight resources and energy supply. He writes that more than 95 percent of manufactured goods rely on certain chemical building blocks somewhere in their value chains that is, basic chemicals from which other chemicals get made. For that reason, integrating sustainability and green chemistry concepts sustainable chemistry as a building block is a vitally important part of building a more sustainable economy.

Dows sustainability strategy includes a set of four pillars of sustainable chemistry:

Kepler says Dows green chemistry efforts have led to products such as roofing shingles with integrated photovoltaics that make harnessing the power of the sun affordable, advanced lithium-ion batteries for improved hybrid and electric vehicle efficiency, corn seed traits that increase crop productivity and a joint venture with Mitsui in Brazil to make plastics from sugar cane.

That last detail making plastics from sugar cane is intriguing, especially in light of a recent article, Status Report: Green Chemistry for Polymers, by Sally Humphreys of research firm Applied Market Information. The article discusses a wide variety of efforts in the plastics industry to employ biological substitutes for fossil fuels as feedstocks for producing polymers.

Humphreys also highlights efforts in Brazil to produce plastics from sugar cane:

The Brazilian sugar cane industry is the largest in the world. [Brazilian petrochemical firm] Braskem has used this sugar as a source of feedstock to make its green polyethylene and polypropylene with current capacities at 200 and 30 kilotonnes per year respectively. 86.5 tons of sugar cane gives 7,200 liters of ethanol and 3 tonnes of polyethylene. Brazil has vast areas of arable land that could be used to develop this industry and Braskem is studying all aspects including ways to increase yield.

Sugar cane field in Brazil. Credit: Maria Hsu, CC BY 2.0

As another example, Ford Motor Co. has been testing the use of a soy polyol-based polyurethane foam, a bio-thermoplastic urethane (TPU) developed from renewable sources.

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Green Chemistry Carving a Bigger Role in Sustainable Manufacturing

OTTAWA, May 28, 2012 /CNW/ - The Chemistry Industry Association of Canada supports the federal government's back-to-work legislation requiring the appointment of an arbitrator to resolve outstanding disputes between Canadian Pacific Railway and its 4,800 striking employees.

CIAC's member-companies rely on rail to ship more than 70 per cent of their products, and the CP strike has hindered their ability to get those products to market. If the strike were to continue, some CIAC plants could be forced to reduce their production by the end of this week.

CIAC estimates that the 2007 rail strike cost chemistry companies - and the Canadian economy - in the order of $200 million dollars. When a chemical plant cannot deliver its products to market, the effects can be felt throughout the economy in sectors such as energy, housing, automobiles, pulp and paper, and consumer products - all of which rely on inputs from the chemistry industry. There can be health and safety implications as well; the industry's chemicals are essential for many Canadian municipalities to treat their water.

On May 22, 2012, CIAC President Richard Paton sent a letter to Labour Minister Lisa Raitt (now posted on http://www.canadianchemistry.ca) urging a quick resolution to the CP strike. The government's back-to-work legislation is an appropriate response to the chemistry industry's calls for action; it will mitigate further economic loss, and prevent damage to Canada's reputation as a reliable link in global supply-chains.

Fiona Cook Director Business & Economics Chemistry Industry Association of Canada 613-297-0509

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Chemistry industry applauds federal government's action to end CP strike

Photo courtesy of Foster Photography Katie Hogan

EAST NAPLES When Katie Hogan took chemistry during her junior year at Lely High School, she was hooked.

"Everyone was complaining about how hard it was," Katie said as she sat in the library on her last day of school. "I said, 'It's not hard, it's easy.' I ended up helping other students. Science has always been easy for me."

So she asked her mother, Jackie, a pharmaceutical rep, what career was most like chemistry and began working toward that goal.

"Some jobs aren't needed anymore, but people always need medicine," the 18-year-old said. "Pharmacology, I feel like it will always be there."

Katie, who has a 3.869 gpa, is Lely's 2012 Graduate of Distinction. She juggled a full course load in addition to being an award-winning sports captain, volunteering and completing an online pre-calculus class for an extra math credit.

"It takes a lot of self-motivation," said Chris Black, the school's librarian and media specialist, who saw her working online every day. "Math is not an easy subject without someone to teach you."

Black, the school running coach and Katie's coach since seventh grade, called her "one of the best," a seventh-grader who excelled and continued getting better.

"No matter what she does, whether it's athletics or school work, she does whatever you ask her to and she does her best and always has a smile," he said. "She even runs with a smile."

Last week, Katie was awarded the Bright Futures Medallion, meaning 50 percent of her tuition is paid for at a state school. Katie, who lives with her mother; stepfather, Mark Urban; and brother, Danny, originally wanted to go to Florida State University in Tallahassee, but instead chose University of Central Florida in Orlando.

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Class of '12: Lely graduate had good chemistry with school studies

My son, Alexander, is completing his high school career by taking chemistry and physics.

Which makes him 50 percent smarter than I am.

Or maybe its 100 percent.

Im equally lost among the precepts of mathematics as I am fumbling around in convoluted formulas of chemistry and the insane concepts of physics.

This is why I labored through only chemistry in high school, achieving, by way of the dogged determination that is the clueless students only advantage, a flaccid C.

(I was pretty deft with a Bunsen burner, as well. And one time I tried to make nitroglycerine, a failed effort that seemed to amuse the teacher. Probably because I didnt hurt anyone.)

I have few distinct memories from chemistry class, but one retains that crystalline quality which our brains, in some cruel twist of human evolution, reserve for our most embarrassing episodes.

(Actually only part of the memory is still vivid; I have no recollection at all of the details of the problem we were supposed to solve.)

The occasion was a particularly rare one: An experiment that seemed to me, if not logical, at least understandable.

I volunteered to walk up to the blackboard (it was in fact green, but, as with the black kind, you wrote on it with chalk) and demonstrate the equation.

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Like father (not) like son: Showed up in chemistry class

Josh Brolin says he had a special chemistry with Will Smith when filming 'Men In Black 3'.

Josh Brolin says he had a special chemistry with Will Smith.

The 'No Country For Old Men' actor has revealed the natural chemistry and banter he shared with his 'Men In Black 3' comedy partner was one of a kind.

He said: ''When the camera rolls, something happens. It was very nice, I hadn't felt that with a lot of people. Usually you have to act at acting well. With Will Smith and I, something just happens when those cameras start rolling.

''And we're very different people, but I think we are both very mischievous in our own way (laughs), so we were having fun with this kind of back and forth, cat and mouse thing.

''But it's not a cat and mouse, it's something different. It was follying, it was a lot of fun! We created our own thing so it became less about how am I going to do Tommy Lee Jones, more in finding a rendition of Tommy, and then making it our own.''

Barry Sonnenfield's latest flick sees Josh play a young version of Tommy Lee Jones' character, Agent K, who teams up with Agent J (Will) when they go back in time to save the world.

The 44-year-old 'Goonies' star said that he knew from the very first ''make or break'' scene the pair shot together that the film was going to work.

Speaking about his favourite memory from filming, he added to Flicksandbits.com: ''The first scene me and Will shot was the first scene that's in the movie with us together. When I'm sitting there looking at J, who's looking around at all the 60s motif, and then he looks at me and he's telling me something and I say, 'How do you know my name?'

''That was the first scene we did in the movie, so that was an exciting moment for me because that's a make or break moment. All the talking and the rehearsing, all of the studying we did, it comes down to that moment. It was the moment of, 'Is this going to work or not?' That was a great moment.''

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Josh Brolin - Josh Brolin Shares Special Chemistry With Will Smith

Feb. 24, 1980April 27, 2012

A beloved chemistry teacher and varsity baseball coach who taught his students in Florida to rise above will be remembered Saturday at the Wales Center Community Baptist Church.

Justin M. Kunick was born in Naperville, Ill., and moved to Wales Center when he was four. He graduated from Iroquois High School in 1998 and then from Keuka College in 2002, where he played on the varsity baseball team, setting several team records.

From the time he was a newborn, Mr. Kunick struggled with heart problems but always overcame them with admirable determination. Ailments left him temporarily paralyzed on the right side of his body when he was a toddler. His family believes thats how he ended up a left-handed pitcher.

After working as a substitute teacher for a couple of years in Michigan, Mr. Kunick landed a full-time teaching job in Hudson, Fla.

Mr. Kunick had become the varsity coach at Fivay High School when, in January, he was diagnosed with colon cancer. Through his surgeries and chemotherapy, Kunick continued coaching from his hospital bed with the help of his father. Terry Kunick would call his son after each inning to report on how the team was doing.

Their final game, he coached from his hospice bed, Terry Kunick said.

Mr. Kunick died April 27 while in hospice in New Port Richey. He was 32.

He is survived by his father and mother, Marilyn Kunick; his wife, the former Anne Hastie; a brother, Joseph; and two sisters, Jeanette Wolff and Jody Smaszcz.

A memorial service will be held at 4 p.m. Saturday in the Wales Center Community Baptist Church, with friends and family gathering an hour beforehand.

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Justin M. Kunick, chemistry teacher, baseball coach

 It’s a stalwart of the undergraduate lab and can still be found introducing kids to the joys of science in even today’s modest chemistry sets. But potassium permanganate is good for much more than pretty colours and redox titrations… in fact, it could well save your life. Brian Clegg praises our purple pal in this week’s Chemistry in its element podcast.

                  

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Over at Sciencegeist they’ve throw down the gauntlet and asked bloggers to write about their favourite toxic chemical as part of a carnival of toxins that also play important roles in everyday life. It’s all part of the campaign by chemists and bloggers alike against ‘chemophobia’ – an irrational fear of the chemicals we find all around us in everyday life or even the very word ‘chemical’. Recently there seems to have been a spate of these articles in newspapers with chemical-free labels even popping up in labs where they ought to be choosing their words with a little more care!

Canaries provided a CO early warning system for miners

So I’m going to kick off Chemistry World’s contribution to the carnival with carbon monoxide: the silent killer. It’s now pretty much common knowledge that this diatomic molecule can kill, thanks to television images of people committing suicide by gassing themselves with car exhausts (this is much less likely today as catalytic converters mop up and transform much of the CO in exhaust fumes) and public health campaigns highlighting the dangers of the gas in the home. But John Scott Haldane, the father of noted geneticist J B S Haldane, was the first to realise that this colourless, odourless gas was responsible for the deaths of many miners. The CO that killed these miners was the result of incomplete combustion of carbon during coal dust explosions. J S Haldane, belonging to that intrepid class of chemists that is all but extinct now, used himself as a guinea pig to investigate the effects of CO. By exposed himself to potentially lethal doses of the chemical, he discovered the dangers it posed, which led to the introduction of canaries in mines as early warning signals of danger. Good for miners, bad for canaries! You can hear more about J S Haldane in Chemistry World’s podcast on carbon monoxide.

CO’s killing power comes from its affinity for the haemoglobin in red blood cells, binding to it preferentially over oxygen to form carboxyhaemoglobin. People exposed to CO are figuratively drowning in air – there’s plenty of oxygen all around them but their bodies just can’t absorb enough of it. And, in a grisly twist, carboxyhaemoglobin is bright red, giving victims of CO poisoning a hale and hearty rosy hue.

Unsurprisingly, this has led to boilers, and the deadly gas they can produce, becoming inextricably linked in people’s minds with danger – to be guarded against in the home and on holiday. In the US alone, it is estimated that 40,000 people seek medical attention for CO poisoning each year, so it’s clear it’s still a serious problem.

That’s the dark side of CO, but is there a lighter side? Oddly enough, it was discovered in the 1990s that this deadly gas has a memorable and vital physiological function. It acts as a neurotransmitter in certain parts of the brain involved in long-term memory and has functions in many other parts of the body that are only just being understood. CO joins hydrogen sulfide and nitric oxide as another small and toxic gaseous molecule, which is a vital poison that our bodies both produce and need to function properly. As a result, companies like Alfama are now developing drugs that release CO in minute amounts to treat diseases involving inflammation and a range of other conditions. This turnaround in the way CO is now viewed really gives wings to the old axiom ‘the dose makes the poison’.

Patrick Walter

                  

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Nickel tetracarbonyl - highly unpleasant, but extremely useful (Credit: Wikimedia commons/ Benjah-bmm27)

For my contribution to Sciencegeist’s toxic blog carnival, I decided to write about a decidedly enigmatic compound. Nickel tetracarbonyl is a transition metal complex but also a foul-smelling (and, given the context of this blog post, naturally highly toxic) gas. These are not generally two molecular properties that coincide. It also forms quite easily when nickel metal comes into contact with carbon monoxide.

Having not personally worked with it, I nevertheless respect and admire nickel tetracarbonyl from afar. However, this is a compound which can provoke intensely personal reactions from people who have had the opportunity to get a little more hands-on. I came across possibly one of the most vivid of these in our Chemistry in its element podcast series when Bernie Bulkin described his initiation into a lab working on metal carbonyl complexes:

‘One of the first things I was given to read when I started was the summary of the toxicological effects of nickel carbonyl.  I learned, with some concern, that at 30ppm it was certainly fatal, and even a significantly lower dose of 3ppm caused death in 50% of a group of test animals.

‘When you breathe it in, it decomposes, giving you a dose of carbon monoxide and depositing some nickel on your lungs. If you survive the first few hours, the nickel causes a form of pneumonia, coughing, breathlessness, extreme fatigue.  This lasts for several days, often resulting in cardiovascular or renal failure and death.  I was relieved to find that the safety precautions in the lab were extremely rigorous.’

The concept of receiving a bolus dose of carbon monoxide – deadly enough in its own right as described in Patrick’s blog yesterday – plus the added spice of nickel-plated lungs, was enough to imprint an instant respect for the compound in my mind.

So why on Earth might we want to make or use this compound, given its extreme potential to cause harm?

Nickel as a metal is industrially important – it is hard, shiny and reasonably resistant to corrosion (except by carbon monoxide of course…). Alloyed into steel or plated over the surface it endows the metal with these useful properties too, so much so that it was used to make coins (before being largely replaced by iron, which is cheaper and doesn’t cause the same kind of skin irritation that some people experience when handling nickel). Some coins, particularly the US five-cent pieces known as ‘nickels’, still contain nickel alloyed with copper or plated on the surface of a steel blank.

Nickel’s hardness and corrosion resistance also makes it ideal as the basis for superalloys used to make jet engine turbine blades. These are generally grown as single crystals of the metal for optimum performance at the high temperatures and force loadings of a working jet engine.

So where does nickel carbonyl fit in?

Nickel is rarely found in ores on its own – it is usually combined with its transition metal neighbours iron and cobalt. In fact, the name nickel comes from colloquial German for ‘devil’ (think of ‘Old Nick’ in English folklore) and cobalt derives from the word for a gremlin or hobgoblin, reflecting their role as annoying impurities in iron ores. So a method for separating the metals would not only deliver the desirable nickel, but improve processes for purifying iron and cobalt as well.

Having discovered nickel carbonyl by accident, Ludwig Mond – a German chemist – found that nickel reacts with carbon monoxide much more quickly than does either iron or cobalt. As a savvy businessman, he realised the potential of this observation and, in the late 19th century, developed it into the Mond process for extracting nickel from mixed ores. Reacting impure nickel with CO releases it as gaseous nickel carbonyl and leaves behind the impurities. The nickel can then be reclaimed by heating the complex until it decomposes. This process is still used when the purest nickel (greater than 99.99% pure) is required.

From a research chemistry point of view, nickel complexes form a variety of useful catalysts. Many of these are prepared from nickel carbonyl in some form, owing to the ease of displacing the carbonyl ligands. However, the chemist aspiring to prepare such catalysts would be well advised to seek out alternative sources of nickel in which someone else has already done the carbonyl substitutions – nickel plated lungs and death by suffocation or pneumonia is certainly not to be recommended…

Phillip Broadwith

                  

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The 1850 murder of Gustave Fougnies in Belgium is not famous because of the cleverness of his killers.Not at all. They his sister and brother-in-law practically set off signal flares announcing their parts in a suspicious death.

Its not famous because it was such a classic high society murder. The killers were the dashing, expensive, and deeply indebtedComte and Countessde Bocarm.The death occurred during a dangerouslyintimate dinner at their chateau, a 18th century mansion on an estate in southern Belgium.

Nor it is remembered because the Comte died by guillotine in 1851 so many did after all.

No, this is a famous murder because of its use of a notably lethal poison. And because the solving of this particular murder changed the history of toxicology, helped lay the foundation for modern forensic science. The poison, by the way, was the plant alkaloid nicotine. And it was chosen because at the time, no one absolutely no one knew how to detect a plant alkaloid in a dead body. During the unsuccessful prosecution of a morphine murder only a few years earlier, a French prosecutor actually started shouting about it in the courtroom: Henceforth, let us tell would-be poisonersuse plant poisons. Fear nothing; your crime will go unpunished. There is no corpus delecti (physical evidence) for it cannot be found.

And that was certainly the idea when the Comte and his wife decided to murder her young brother for his money. That they could kill him with this very special poison. And never be caught.

We probably know nicotine best today for its role in creating the highly addictive chemistry of tobacco, a reason that so many people find it difficult to quit smoking even though the habit is so conclusively linked to disorders ranging from heart disease to lung cancer. The compound has such a potent effect on the brain that some researchers have even suggested that it provides a gateway for drugs such as cocaine. Others have wondered whether that potency could somehow be harnessed to good effect, as a treatment for disorders ranging from Alzheimers to depression, although its addictive nature makes such approaches obviously complicated.

But back in the 19th century, of course, there was no way to peel apart its neurochemical effects. What people did know was that nicotine was one lethal compound. Tobacco, a plant native to the Americas, had caught the attention of the Europeans during the 16th century. One of its strongest advocates was Jean Nicot de Villemain, the French ambassador to Portugal, who acquired plants and seeds from the Portuguese colony in Brazil and promoted their use during the 1560s. The tobacco plant, Nicotiana tabacum, is named after him, as is the plants primary alkaloid.

Nicotine was first isolated from tobacco leaves in 1928 by two German chemists, Wilhelm Heinrich Posselt and Karl Ludwing Reinmann (its structure would be determined in 1893 and it would be first synthesized in 1904). Do you wonder what its made of? Three of the most common elements on Earth carbon, nitrogen and hydrogen and this represents one of the things I like best about chemistry, the way nature takes the planets ordinary ingredients and mixes them up to such varied effect. The formula for nicotine is a straightforward: C14H10N2. Of course, that underestimates its complexity. If you look at a 3D model of nicotine (frankly, these always remind me balloon art) youll see what a clustering twist of compound it really is:

Note: Carbon (black), hydrogen (white), nitrogen (blue)

And its that elegant arrangement that turns nicotine into such an effective poison, moving through the bloodstream with exceptional speed. When inhaled, nicotine travels from lung to brain in an estimated seven seconds. Toxicologists estimate that a fully smoked cigarette delivers about 1 mg of nicotine to the lungs; this compares to a lethal dose estimate of 30-60 mg. (For comparison, the lethal dose range for arsenic is 70-200 mg.) The International Programme on Chemical Safety (IPCS) notes that: Nicotine is one of the most toxic of all poisons and has a rapid onset of action. Apart from local caustic actions, the target organs are the peripheral and central nervous systems.

Read the rest here:
Nicotine and the Chemistry of Murder

The Midland Section of the American Chemistry Society selected Dave Karpovich as the regions Outstanding College Chemistry Teacher Award winner for 2012. The award is presented annually to an individual in Bay, Gratiot, Isabella, Midland or Saginaw counties who makes a substantial contribution to science learning through his or her own voluntary efforts.

Dr. Karpovich is an exemplary instructor, said Deborah Huntley, dean of SVSUs College of Science, Engineering and Technology. He is down to earth, yet professional, and very clear in the expectations he holds for his students. He holds a strong conviction that research is a key component of a strong undergraduate education, which is why he incorporates hands-on experience. Plus, he brings just enough humor to the classroom to sustain student attention, but without sacrificing the message or the importance of the topic.

Karpovich joined the SVSU faculty in 1998 and accepted an appointment as the H.H. Dow Endowed Chair in Chemistry in 2010. He teaches courses in general, analytical and environmental chemistry; he also leads a tutoring program where SVSU students volunteer in local high schools.

A resident of Gagetown, Karpovich has a long history of scholarly interest in the Saginaw Bay Watershed. One current research project which includes SVSU students and is a partnership with Delta College was cited as a premier example for similar partnerships throughout the Great Lakes states and nationwide during the National Center for Science and Civic Engagement Symposium and Capitol Hill Poster Session in Washington, D.C., in March. The project includes field, classroom, teaching, lab and community-based research components, and aims to assess methods to restore the Kawkawlin River in a way that can be replicated elsewhere in the Saginaw Bay Watershed.

Karpovich completed a Ph.D. at Michigan State University and a bachelors degree at SVSU. He received the award at the annual American Chemical Society recognition banquet Thursday, May 3, at the Great Hall Banquet and Convention Center in Midland.

With more than 154,000 members, the American Chemical Society is one of the worlds leading sources of authoritative scientific information. Chartered by Congress, the group comprises chemists, chemical engineers and other experts in related fields, and creates a professional organization for members around the globe. For more information on the Midland Section, visit its website at http://www.midlandacs.org

Copyright 2012 Midland Daily News. All rights reserved. This material may not be published, broadcast, rewritten or redistributed.

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Karpovich wins chemistry teacher award

A couple of weeks ago Chemistry World ran a story on a cracking paper from a team in Korea. The researchers took inspiration from the way Egyptian stone masons cracked large stone blocks (they inserted a wedge into a hole and then soaked it with water, causing it to expand and crack the stone) to create a technique to make nanoscale cracks in a controlled manner. They did this by etching a guide of notches and grooves into a silicon substrate and then depositing silicon nitride on top. The notches and grooves create a pathway for cracks to propagate along and this technique could be very useful for electronic and microfluidic devices.

© Nature

However, it now turns out that there’s an authorship dispute. The PhD student who said that she did much of the legwork didn’t get a note on the author list, according to this story in the Korea Herald (h/t @naturenano). The leader of the research group, Nam Koo-hyun at Ewha Womans University, Seoul, told the Herald that he made it clear from the start that the PhD student wouldn’t get a credit and that doing experimental work ‘does not qualify one for authorship’. I’m not sure how other PhD students would feel about this! Plenty of people have received a name check for far less than carrying out the experimental work. What do you think the cut off point should be for getting an author credit?

Patrick Walter

                  

Source:
http://prospect.rsc.org/blogs/cw/?feed=rss2