Posts by Jai Ganesh

Jai Ganesh · Science HQ

Jaundice

Gist

Jaundice is the yellowing of the skin and eyes caused by excess bilirubin in the blood, signaling underlying liver dysfunction, bile duct obstruction, or accelerated red blood cell destruction. Common causes include hepatitis, cirrhosis, gallstones, and, in newborns, immature liver function.

Jaundice is primarily caused by a buildup of bilirubin in the blood, resulting from liver dysfunction, bile duct obstruction, or rapid red blood cell breakdown. Common underlying factors include hepatitis, liver cirrhosis, gallstones, alcohol-related liver disease, and pancreatic cancer, which prevent proper processing or excretion of bilirubin.

Summary

Jaundice, also known as icterus, is a yellowish or, less frequently, greenish pigmentation of the skin and sclera due to high bilirubin levels. Jaundice in adults typically indicates the presence of underlying diseases involving abnormal heme metabolism, liver dysfunction, or biliary-tract obstruction. The prevalence of jaundice in adults is rare, while jaundice in babies is common, with an estimated 80% affected during their first week of life. The most commonly associated symptoms of jaundice are itchiness,[2] pale feces, and dark urine.

Normal levels of bilirubin in blood are below 1.0 mg/dl (17 μmol/L), while levels over 2–3 mg/dl (34–51 μmol/L) typically result in jaundice. High blood bilirubin is divided into two types: unconjugated and conjugated bilirubin.

Causes of jaundice vary from relatively benign to potentially fatal. High unconjugated bilirubin may be due to excess red blood cell breakdown, large bruises, genetic conditions such as Gilbert's syndrome, not eating for a prolonged period of time, newborn jaundice, or thyroid problems. High conjugated bilirubin may be due to liver diseases such as cirrhosis or hepatitis, infections, medications, or blockage of the bile duct, due to factors including gallstones, cancer, or pancreatitis. Other conditions can also cause yellowish skin, but are not jaundice, including carotenemia, which can develop from eating large amounts of foods containing carotene—or medications such as rifampin.

Treatment of jaundice is typically determined by the underlying cause. If a bile duct blockage is present, surgery is typically required; otherwise, management is medical. Medical management may involve treating infectious causes and stopping medication that could be contributing to the jaundice. Jaundice in newborns may be treated with phototherapy or exchanged transfusion depending on age and prematurity when the bilirubin is greater than 4–21 mg/dl (68–365 μmol/L). The itchiness may be helped by draining the gallbladder, ursodeoxycholic acid, or opioid antagonists such as naltrexone. The word jaundice is from the French jaunisse, meaning 'yellow disease'.

Details

Jaundice is a condition where your skin, the whites of your eyes and mucous membranes (like the inside of your nose and mouth) turn yellow. Many medical conditions can cause jaundice, like hepatitis, gallstones and tumors. Jaundice usually clears up once your healthcare provider treats your main medical condition.

Overview:

What is jaundice?

Jaundice (hyperbilirubinemia) is when your skin, sclera (whites of your eyes) and mucous membranes turn yellow. Jaundice occurs when your liver is unable to process bilirubin (a yellow substance made when red blood cells break down) in your blood. This can either be caused by too much red blood cell breakdown or liver injury.

How jaundice develops:

* Red blood cell breakdown: Your body regularly breaks down old red blood cells and replaces them with new ones. This breakdown process makes bilirubin.
* Bilirubin processing: Normally, your liver processes bilirubin, making it a part of bile (a bitter, greenish-brown fluid that helps digest food). Your liver then releases the bile into your digestive system.
* Too much bilirubin: Jaundice happens when your liver can’t process all the bilirubin your body makes, or if your liver has a problem releasing bilirubin.
* Yellow color: When there’s too much bilirubin in your blood, it starts to leak into tissues around your blood vessels. This leaking bilirubin makes your skin and the whites of your eyes yellow. This yellow color is a common sign of jaundice.

Possible Causes:

What causes jaundice?

Jaundice can result from a problem in any of the three phases of bilirubin:

* Before your liver processes bilirubin (prehepatic jaundice). This type of jaundice happens before your body makes bilirubin. Too much red blood cell breakdown takes over your liver’s ability to filter out bilirubin from your blood.
* During the production of bilirubin (hepatic jaundice). This type happens when your liver can’t remove enough bilirubin from your blood. Hepatic jaundice can happen if you have liver failure.
* After production of bilirubin (posthepatic jaundice). Also called obstructive jaundice, this type happens when a blockage stops bilirubin from draining into your bile ducts.

Conditions that cause jaundice include:

Prehepatic jaundice causes

* Breaking down a large hematoma (bruise) and then reabsorbing it back into your bloodstream.
* Hemolytic anemias (when blood cells are destroyed and removed from the bloodstream before their normal lifespan is over).

Hepatic jaundice causes

* Viruses, including hepatitis A, chronic hepatitis B and C, and Epstein-Barr virus infection (infectious mononucleosis).
* Alcohol-induced hepatitis.
* Autoimmune disorders.
* Rare genetic metabolic defects.
* Medicines, including penicillin, oral contraceptives, chlorpromazine (Thorazine R), estrogenic or anabolic steroids and acetaminophen toxicity.

Posthepatic jaundice causes

* Gallstones.
* Inflammation (swelling) of your gallbladder.
* Gallbladder cancer.
* Pancreatic tumor.

How do you know if you have jaundice?

You may not notice the yellow skin and sclera associated with jaundice. Your provider may find the condition when looking for something else. How serious your symptoms are depends on what causes them and how quickly or slowly they develop.

Symptoms that can be associated with jaundice include:

* Yellowish tint to your skin and the whites of your eyes.
* Fever.
* Chills.
* Pain in your belly.
* Flu-like symptoms.
* Dark-colored pee.
* Pale-colored poop.
* Being tired or confused.
* Itchy skin.
* Weight loss.

Care and Treatment:

How can my provider tell I have jaundice?

Your provider can tell if you have jaundice by measuring the bilirubin levels in your blood and seeing whether it’s the type of bilirubin related to red blood cell breakdown (unconjugated) or liver injury (conjugated). They may also check for other signs of liver disease, including:

* Bruising.
* Spider angiomas (abnormal collection of blood vessels near the surface of your skin).
* Palmar erythema (red palms and fingertips).

Your healthcare provider will also examine you to decide your liver’s size and tenderness. They may use imaging (ultrasound and CT scanning) and liver biopsy (taking a tissue sample of your liver) to better understand what’s causing your liver injury.

How is jaundice treated?

There’s no specific treatment for jaundice. But your provider can treat the cause and the jaundice should improve. They can also treat complications the condition causes. For example, if itchy skin is a problem, your provider can prescribe medication.

What are the risks of not treating jaundice?

It depends on what’s causing your jaundice. If it’s a virus, the virus could spread or become chronic. But if you have jaundice because your liver is failing, complications from your liver disease can include coma and death.

Can you prevent jaundice?

Since there are many causes of jaundice, it’s hard to find ways to prevent it. Some general tips include:

* Avoiding hepatitis infection by getting vaccinated, having safe sex, using clean needles and practicing good personal hygiene like thorough hand-washing with soap and water.
* Staying within recommended alcohol limits.
* Maintaining a weight that’s healthy for you.
* Avoiding natural and herbal supplements.
* Managing your cholesterol.

When To Call the Doctor:

When should jaundice be treated by a doctor or healthcare provider?

A healthcare provider should evaluate jaundice. It’s a sign that something’s not right with your liver. If you notice signs of jaundice, call your healthcare provider.

Additional Common Questions:

Do children get jaundice?

Jaundice is common in newborn babies. Like with adults, a buildup of bilirubin in your baby’s blood can cause jaundice. Since your baby’s liver is still developing, it can’t remove (or break down) all the bilirubin. Jaundice usually goes away on its own or providers treat it with phototherapy.

Additional Information:

What Is Jaundice?

When red blood cells die, they leave behind bilirubin, a yellow-orange pigment in the blood. The liver filters bilirubin from the bloodstream to be removed in your stool. If too much is in your system or your liver is overloaded, it causes a buildup known as hyperbilirubinemia. This causes jaundice, where your skin and the whites of your eyes look yellow.

Newborn babies often get it. About 60% have jaundice, also known as icterus, within the first couple of days after birth. Adults can get it, too, although it's less common. See a doctor right away if you think you have jaundice. It could be a symptom of a liver, blood, or gallbladder problem.

Types of Jaundice

There are four main types of jaundice, which are grouped by where the bilirubin collects in your body. A blood test can determine which type you have.

Prehepatic

If bilirubin builds up before blood enters the liver, it's known as prehepatic jaundice. This means you're breaking down red blood cells and creating more bilirubin than your liver can process.

Hepatic

If your liver isn't able to process bilirubin well, it's called hepatic jaundice.

Posthepatic

Posthepatic jaundice is when bilirubin builds up after passing through the liver and your body can't clear it quickly enough.

Obstructive jaundice

This condition is when bile isn't able to drain into your intestines because of a blocked or narrow bile or pancreatic duct. This type of jaundice has a high death rate, so it's important to catch and treat it early.

Jaundice Symptoms

Jaundice may have no symptoms. Any signs you have may depend on how quickly the condition is getting worse. Well-known symptoms are yellowing of the skin and jaundice eyes (also called scleral icterus). But there are others to watch for, including:

* Fever
* Stomach pain
* Chills
* Dark urine
* Tar- or clay-colored stools
* Flu-like symptoms
* Itchy skin
* Weight loss
* Feeling unusually irritated
* Confusion
* Abnormal drowsiness
* Bruising or bleeding easily
* Bloody vomit

How long does jaundice last in adults?

How long jaundice lasts depends on what's causing it and the treatment you need. If a medication is causing it, jaundice will fade after you stop taking it. If hepatitis is causing it, medications can be taken to treat the condition. If there is a blocked bile duct or gallstones, surgery may be required.

Jaundice Causes

Jaundice in adults is rare, but you can get it for many reasons. These include:

* Hepatitis: Liver inflammation can be caused by a virus, autoimmune disorder, alcohol or drug use, or chemical exposure. It may be short-lived (acute) or chronic, which means it lasts for at least 6 months. Long-term inflammation can damage the liver, causing jaundice.
* Alcohol-related liver disease: If you drink heavily over a long period of time – typically 8 to 10 years – you could seriously damage your liver. Two diseases in particular, alcoholic hepatitis and alcoholic cirrhosis, harm the liver.
* Other liver disease: Cirrhosis can also be caused by autoimmune diseases, genetic conditions that are passed down in your family, and hepatitis. A severe condition known as nonalcoholic steatohepatitis can cause nonalcoholic fatty liver disease. With this kind of liver disease, fat builds up in your liver along with inflammation, which damages it over time.
* Blocked bile ducts: These are thin tubes that carry a fluid called bile from your liver and gallbladder to your small intestine. If the tubes are blocked by gallstones, cancer, inflammation, or rare liver diseases, you could get jaundice.
* Pancreatic cancer: This is the 10th most common cancer in men and the ninth in women. It can block the bile duct, causing jaundice.
* Certain medicines: Drugs like acetaminophen, penicillin, birth control pills, and steroids have been linked to liver disease.
* Blood clots: If your body reabsorbs a large blot clot (hematoma) under the skin, it can increase bilirubin levels.
* Hemolytic anemias: Destroyed blood cells are sometimes removed from the bloodstream too quickly, increasing bilirubin levels.

Diagnosing Jaundice

Your doctor will ask you about your symptoms and medical history. They'll then give you a physical exam to see if there's swelling in your liver.

To get more information, your doctor will likely order blood tests to measure bilirubin and cholesterol levels and get a complete blood count (CBC). If you have jaundice, your level of bilirubin will be high. Your doctor may order other tests to find the cause of your jaundice and how severe it is, including:

* A hepatitis panel, which is a blood test that shows if you have, or have had, hepatitis. It tests for hepatitis A, hepatitis B, and hepatitis C. If there are no hepatitis antibodies in your blood, it means you don't have the condition, or you had it in the past, but your body has cleared it.
* Tests to check enzyme levels in the liver to see how well it is functioning. If enzyme levels are higher or lower than normal, it can mean you have disease or damage to the liver or bile ducts.
* Imaging, like a CT scan, ultrasound, or magnetic resonance cholangiopancreatography, a type of MRI that checks for blocked ducts near the gallbladder
* A liver biopsy, to show if you have damage to, or disease in, your liver. During the test, a small piece of your liver is removed either with a needle inserted into the belly to the liver, through a vein in your neck, or through a cut in your belly.
* Prothrombin time, which measures how long it takes for blood plasma to clot. Your blood will be taken, and a laboratory will test it to see if it clots faster or slower than the normal range (which is between 10 and 13 seconds). If it clots too slowly, that may mean there are problems with your liver.

Jaundice Treatment

In adults, jaundice itself usually isn’t treated. But your doctor will treat the condition that’s causing it.

If you have acute viral hepatitis, jaundice will go away on its own as your liver heals. If a blocked bile duct is to blame, your doctor may suggest surgery to open it. If your skin is itching, your doctor can prescribe cholestyramine to be taken by mouth. This medication is used to remove bile acids from your body, which cause itching.

Phototherapy for jaundice

Phototherapy uses a fluorescent white or blue-spectrum light that breaks down bilirubin so it can be released from the body. This treatment is used for newborns, but phototherapy has not been shown to be effective for treating jaundice in adults.

Preventing Jaundice
You may have a higher risk for jaundice if you drink too much alcohol or have hepatitis. It is also more common in people during middle age.

You can reduce your risk of jaundice through lifestyle changes like:

* Avoid herbal supplements (which can be toxic to the liver) unless recommended by your doctor
* Stop smoking
* Reduce or cut out all alcohol (the CDC recommends no more than two alcoholic drinks per day for men and one daily for women)
* Don't use intravenous drugs (drugs that go into your vein)
* Don't take more prescription medication than you are prescribed
* Get all recommended vaccines before traveling overseas
* Use safe sex practices
* Maintain a healthy weight
* Keep your cholesterol in a healthy range

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Jai Ganesh · This is Cool

Gist

Iguazu Falls is the world's largest waterfall system, featuring 275 individual cascades stretching nearly 3 kilometers along the Argentina-Brazil border. As a UNESCO World Heritage site and one of the new seven natural wonders, it features the dramatic 80-meter-tall "Devil's Throat" (Garganta del Diablo).

Iguazu Falls exists within a protected UNESCO World Heritage site that's home to over 2,000 species of vascular plants and countless animal species, including jaguars, ocelots, and over 400 bird species.

Iguazu Falls is one of the new seven natural wonders of the world. At over 1.5 miles wide it is wider than Niagara Falls and is 60% taller than Niagara Falls.

Summary

“My poor Niagara …”

That is what Eleonor Roosevelt said when she saw Iguazu Falls.

Welcome to Iguazu Falls! One of the most important destinations in Argentina, Brazil and South America!

Every year, millions of people come to visit this beautiful natural attraction that Argentina and Brazil have to offer. During 2019, the park received 1,640,000 visitors, both local and foreign.

And everyone is amazed with this destination!

The Iguazu Falls consists of two national parks, one in Foz de Iguazu (Brazil) and the other one in Puerto Iguazu (Argentina). The curious thing is that although one only sees the falls as the main attraction, the park has a size of 252,982 hectares (67,720 on the Argentine side and 185,262 on the Brazilian side).

These falls in Argentina and Brazil managed to attract so much attention that almost at the same time they were declared National Parks (1934 in Argentina and 1939 in Brazil). And after some years and millions of visitors fascinated by the landscape and the sound of this natural attraction, UNESCO declared them as World Heritage Site in 1984, and reaffirmed as Exceptional Universal Value (their cultural and nature it’s so important that it’s conservation should be of worldwide interest) in 2013.

Why are they so famous? It is enough to just see photos and videos to be amazed by its beauty. But it is not only about tourism: the Iguazu National Park is home to many species of animals and flora that create an important natural ecosystem connected to all Latin America.

Each visitor who comes to the Iguazu Falls collaborates to continue the conservation work for the area.

And obviously, Iguazu Falls have allowed the development of local economies, making the city of Puerto Iguazu and Foz de Iguazu grow and improve the quality of life of its inhabitants.

Location of Iguazu Falls

Iguazu Falls are in the continent of South America, and as we mentioned, it is shared by two countries: Argentina and Brazil. Although Paraguay is nearby, it only shares the river that Iguazu Falls feeds, but it is quite far from the falls and cannot even be seen from there.

The city in Argentina where the Iguazu Falls are located is called Puerto Iguazu, and in Brazil it is called Foz de Iguazu. Both cities are very close to each other: only 16km from center to center.

Iguazu Falls on the Argentine side are located 18km from Puerto Iguazu and 29km from the center of Foz de Iguazu.

Iguazu Falls on the Brazilian side are 27km from Puerto Iguazu, and 29km from downtown Foz de Iguazu

Both cities are very close to each national park, that is why all the excursions that we offer on both sides of the falls can pick up from any hotel in both destinations (except in hotels far from the center such as Recanto Cataratas).

The destination is close to several major cities with direct flights. For example, going to Iguazu Falls from Buenos Aires only needs to take a plane to get there in about 2 hours. From Rio de Janeiro you can also get to Iguazu in two hours.

The Iguazu Falls on the Argentine side is at latitude -25.68352837588661 and longitude -54.4547103472097.

The Iguazu Falls on the Brazilian side is at latitude -25.61524025766296 and longitude -54.479225906855845.

Airports Near Iguazu Falls

As the Iguazu Falls are shared by Argentina and Brazil, you have two airports to choose from where to get there: Puerto Iguazu (airport code IGR) and Foz de Iguazu (airport code IGU).

Getting to one or the other airport depends on where you come from to visit the destination.

If you want to visit Iguazu from destinations in Argentina such as Buenos Aires, Cordoba, Salta or other, you should look for flights arriving in Puerto Iguazu (airport code IGR).

Now if you come from Rio de Janeiro, Sao Paulo, or even some international destination like Lima (Peru), then look for flights that arrive at Foz de Iguazu (airport code IGU).

Both airports are fairly close to Iguazu Falls, in fact it is quite normal to offer one-day tours that visit the park on flights that arrive and depart the same day – although it may seem rushed, it is an excellent option for passengers who come from cruise ships or who have very little time.

Iguazu Falls on the Argentine side are 9km (15-20 minutes by car). And the falls on the Brazilian side are 4 kilometers away (less than 10 minutes by car).

Details

Iguazú Falls or Iguaçu Falls are waterfalls of the Iguazu River on the border of the Argentine province of Misiones and the Brazilian state of Paraná. Together, they make up the largest waterfall system in the world. The falls divide the river into the upper and lower Iguazu. The Iguazu River rises near the heart of the city of Curitiba. For most of its course, the river flows through Brazil; however, most of the falls are on the Argentine side. Below its confluence with the San Antonio River, the Iguazu River forms the border between Argentina and Brazil.

The name Iguazú comes from the Guarani or Tupi words y, meaning 'water', and ûasú [waˈsu], meaning 'big'. Legend has it that a deity planned to marry a beautiful woman named Naipí, who fled with her mortal lover Tarobá in a canoe. In a rage, the deity sliced the river, creating the waterfalls and condemning the lovers to an eternal fall. The first European to record the existence of the falls was the Spanish Conquistador Álvar Núñez Cabeza de Vaca in 1541. It was inscribed into the UNESCO World Heritage List in 2013.

Geology and geography

The staircase character of the falls consists of a two-step waterfall formed by three layers of basalt. The steps are 35 and 40 metres (115 and 131 ft) in height. The columnar basalt rock sequences are part of the 1,000-metre-thick (3,300 ft) Serra Geral formation within the Paleozoic-Mesozoic Paraná Basin. The tops of these sequences are characterized by 8–10 m (26–33 ft) of highly resistant vesicular basalt and the contact between these layers controls the shape of the falls. Headwater erosion rates are estimated at 1.4–2.1 cm/year (0.55–0.83 in/year). Numerous islands along the 2.7-kilometre-long (1.7 mi) edge divide the falls into many separate waterfalls and cataracts, varying between 60 and 82 m (197 and 269 ft) high. The number of these smaller waterfalls fluctuates from 150 to 300, depending on the water level. About half of the river's flow falls into a long and narrow chasm called the Devil's Throat (Garganta del Diablo in Spanish or Garganta do Diabo in Portuguese).

The Devil's Throat canyon is 80–90 m (260–300 ft) wide and 70–80 m (230–260 ft) deep. Left of this canyon, another part of the river forms 160–200 individual falls, which merge into a single front during the flood stage. The largest falls are named San Martín, Adam and Eva, Penoni, and Bergano.

About 900 m (2,950 ft) of the 2.7 km (1.7 mi) length does not have water flowing over it. The water of the lower Iguazu collects in a canyon that drains into the Paraná River, a short distance downstream from the Itaipu Dam. The junction of the water flows marks the border between Brazil, Argentina, and Paraguay. Some points in the cities of Foz do Iguaçu, Brazil, Puerto Iguazú, Argentina, and Ciudad del Este, Paraguay, have access to the Iguazu River, where the borders of all three nations may be seen, a popular tourist attraction for visitors to the three cities.

The layout of Iguazu Falls resembles a reversed letter "J". The Argentina–Brazil border runs through the Devil's Throat. On the right bank is the Brazilian territory, which is home to more than 95% of the Iguazu River basin but has just over 20% of the jumps of these falls, and the left side jumps are Argentine, which make up almost 80% of the falls.

Access

The falls may be reached from two main towns, with one on either side of the falls: Foz do Iguaçu in Brazil and Puerto Iguazú in Argentina, as well as from Ciudad del Este, Paraguay, on the other side of the Paraná River from Foz do Iguaçu, each of those three cities having commercial airports. The falls are shared by the Iguazú National Park (Argentina) and Iguaçu National Park (Brazil). The two parks were designated UNESCO World Heritage Sites in 1984 and 1986, respectively.

The first proposal for a Brazilian national park aimed at providing a pristine environment to "future generations", just as "it had been created by God" and endowed with "all possible preservation, from the beautiful to the sublime, from the picturesque to the awesome" and "an unmatched flora" located in the "magnificent Iguaçu waterfalls". These were the words used by André Rebouças, an engineer, in his book Provinces of Paraná, Railways to Mato Grosso and Bolivia, which started up the campaign aimed at preserving the Iguaçu Falls in 1876. At this time, Yellowstone National Park in the US, the first national park in the world, was four years old.

On the Brazilian side, a walkway along the canyon has an extension to the lower base of Devil's Throat. Helicopter rides offering aerial views of the falls have been available from Brazil, but Argentina has prohibited such helicopter tours because of the adverse environmental impact on the flora and fauna of the falls.

Aerolíneas Argentinas has direct flights from Buenos Aires to Iguazu International Airport. Azul, GOL, and LATAM Brasil offer services from main Brazilian cities to Foz do Iguaçu. From Foz do Iguaçu airport, the park may be reached by taking a taxi or bus to the entrance of the park. Their park has an entrance fee on both sides. Once inside, free and frequent buses are provided to various points within the park. The town of Foz do Iguaçu is about 20 km (12 mi) away, and the airport is between the park and the town.

The Argentine access, across the forest, is by a Rainforest Ecological Train very similar to the one in Disney's Animal Kingdom. The train brings visitors to the entrance of Devil's Throat, as well as the upper and lower trails. The Paseo Garganta del Diablo is a 1 km-long (0.6 mi) trail that brings visitors directly over the falls of Devil's Throat, the highest and deepest of the falls. Other walkways allow access to the elongated stretch of falls across the forest on the Argentine side and to the boats that connect to San Martin Island. Also on the Argentine side, inflatable boat services take visitors very close to the falls.

The Brazilian transportation system aims at allowing an increase in the number of visitors, while reducing the adverse environmental impact, through an increase in the average number of passengers per vehicle inside the park. The new transportation system has a 72-passenger capacity and panoramic-view, double-deck buses.

Comparison with other notable falls

Upon seeing Iguazu, the United States First Lady Eleanor Roosevelt reportedly exclaimed, "Poor Niagara!" (which, at 50 m or 165 feet, are a third shorter). Often, Iguazu also is compared with Victoria Falls in Southern Africa, which separates Zambia and Zimbabwe. Iguazu is wider but is split into roughly 275 distinct falls and large islands, whereas Victoria has the largest curtain of water in the world, at more than 1,600 m (5,249 ft) wide and over 100 m (328 ft) in height (in low flow, Victoria is split into five by islands but in high flow, it may be uninterrupted). The only wider falls are extremely large rapid-like falls, such as the Boyoma Falls (Stanley Falls).

With the flooding of the Guaíra Falls in 1982, Iguazu currently has the sixth-greatest average annual flow of any waterfall in the world, following number five Niagara, with an average rate of 1,746 {m}^{3}/s (61,660 cu ft/s). Its maximum recorded flow was 45,700 {m}^{3}/s (1,614,000 cu ft/s) on 9 June 2014. By comparison, the average flow of Niagara Falls is 2,400 {m}^{3}/s (85,000 cu ft/s), with a maximum recorded flow of 8,300 {m}^{3}/s (293,000 cu ft/s). The average flow at Victoria Falls is 1,088 {m}^{3}/s (38,420 cu ft/s), with a maximum recorded flow of 7,100 {m}^{3}/s (250,000 cu ft/s).

Climate

The Iguazu Falls experience a humid subtropical climate (Cfa, according to the Köppen climate classification) with abundant precipitation and high temperatures year-round. During the summer of 2006, a severe drought caused the Iguazu River to become diminished, reducing the amount of water flowing over the falls to 300 cubic metres per second (11,000 cu ft/s) until early December. This was unusual, as dry periods normally last only a few weeks. The period with the greatest volume of water flowing over the falls is usually December to February, coinciding with one of the periods of greatest rainfall.

Additional Information

Iguazu Falls, Iguazú Falls, Iguassu Falls, or Iguaçu Falls (Spanish: Cataratas del Iguazú [kataˈɾatas ðel iɣwaˈsu]; Guarani: Chororo Yguasu [ɕoɾoɾo ɨɣʷasu]; Portuguese: Cataratas do Iguaçu [kataˈɾatɐʒ du iɡwaˈsu]) are waterfalls of the Iguazu River on the border of the Argentine province of Misiones and the Brazilian state of Paraná. They are the largest waterfalls system in the world. The falls divide the river into the upper and lower Iguazu. The Iguazu River rises near the city of Curitiba. For most of its course, the river flows through Brazil, however, most of the falls are on the Argentine side. Below its confluence with the San Antonio River, the Iguazu River forms the boundary between Argentina and Brazil.

The name “Iguazu” comes from the Guarani or Tupi words “y”, meaning “water”, and “ûasú “[waˈsu], meaning “big”. Legend has it that a deity planned to marry a beautiful woman named Naipí, who fled with her mortal lover Tarobá in a canoe. In a rage, the deity sliced the river, creating the waterfalls and condemning the lovers to an eternal fall. The first European to record the existence of the falls was the Spanish conquistador Álvar Núñez Cabeza de Vaca in 1541.

Iguaçu Falls is a series of cataracts on the Iguaçu River, 14 miles (23 km) above its confluence with the Alto (Upper) Paraná River, at the Argentina-Brazil border. The falls resemble an elongated horseshoe that extends for 1.7 miles (2.7 km)—nearly three times wider than Niagara Falls in North America and significantly greater than the width of Victoria Falls in Africa. Numerous rocky and wooded islands on the edge of the escarpment over which the Iguaçu River plunges divide the falls into some 275 separate waterfalls or cataracts, varying between 200 and 269 feet (60 and 82 metres) in height. The name of the falls, like that of the river, is derived from a Guaraní word meaning “great water.”

The rate of flow of the falls may rise to a maximum of 450,000 cubic feet (12,750 cubic metres) per second during the rainy season from November to March. Minimum flow occurs during the dry season from August to October. The mean annual rate of flow is about 62,000 cubic feet (1,756 cubic metres) per second.

The falls occur along a wide span where the Iguaçu River, flowing westward and then northward, tumbles over the edge of the Paraná Plateau before continuing its course in a canyon. Above the falls, islands and islets spread the river into numerous flows that feed the cataracts. A major portion of the river tumbles into a narrow, semicircular chasm called the Garganta do Diabo (Spanish: Garganta del Diablo [“Devil’s Throat”]); the effect has been described as that of “an ocean plunging into an abyss.” Excellent views of this section (also called Union Falls) can be obtained from both the Brazilian and Argentine sides. Many of the individual falls are broken midway by protruding ledges; the resultant deflection of the water, as well as the spray that arises, creates an array of rainbows. From the foot of the Garganta do Diabo, a curtain of mist rises some 500 feet (150 metres) into the air.

Among the many islands along the falls, the most notable is Isla Grande San Martín, which is situated downstream from the Garganta do Diabo (on the Argentine side). From this island, a fine view of many of the cataracts may be had. Individual falls to be seen from the forest paths and trails on the Argentine side include those known as Dos Hermanas (“Two Sisters”), Bozzetti, San Martín, Escondido (“Hidden”), and Rivadavia. From the Brazilian shore, an impressive panorama of falls can also be seen; among individual Brazilian falls are those known as Benjamin Constant, Deodoro, and Floriano.

The first Spanish explorer to visit the falls was Álvar Núñez Cabeza de Vaca in 1541. In 1897 Edmundo de Barros, a Brazilian army officer, envisaged the establishment of a national park at Iguaçu Falls. Following boundary rectifications between Brazil and Argentina, two separate national parks were established, one by each country—Iguaçu National Park (1939) in Brazil and Iguazú National Park (1934) in Argentina. Both parks were created to preserve the vegetation, wildlife, and scenic beauty associated with the falls. In 1984 the Argentine park was designated a UNESCO World Heritage site, and two years later the Brazilian park was also granted World Heritage status. The Iguaçu area is served by three airports, in Argentina, Brazil, and Paraguay.

The vegetation of the region is rich and varied, ranging from semi-deciduous to tropical, and has been a focus of botanical interest. Water plants include a family (Podostemaceae) that grows only in rushing water and is found on the ledges of the falls. Contrasts are also abundant, with orchids growing next to pines, bamboos next to palm trees, and mosses next to lianas and colourful begonias.

Animal life is equally varied and abundant but has been much less studied. Iguanas are a common sight. Among the mammals are several members of the cat family (ocelots and jaguars), deer, tapir, and innumerable smaller animals. Toucans and birds of many other varieties are also to be found. Fish include the dorado (golden salmon), mandi, and cascudo.

bg-new-demo-iguazu.jpg.webp

Jai Ganesh · This is Cool

2529) Vanadium Pentoxide

Gist

Vanadium pentoxide (V2O5) is a brownish-yellow solid inorganic compound, appearing as an orange powder when freshly precipitated. It is a crucial industrial catalyst, most notably used in the contact process to produce sulfuric acid. It serves as a strong oxidizing agent, a flux in ceramics, and a precursor to vanadium alloys and batteries.

Vanadium pentoxide (V2O5) is a crucial industrial compound primarily used as a catalyst in sulfuric acid production (contact process) and for manufacturing vanadium alloys/steel. It is also essential as a cathode material in lithium-ion and redox flow batteries, and as a coloring agent in ceramics and glass.

Summary:

Key Industrial and Technical Uses

1) Catalyst in Chemical Synthesis: V2O5 acts as a catalyst in the production of sulfuric acid, which is one of the world’s largest industrial chemicals. It is also used to produce maleic anhydride and as an oxidizer in organic chemical manufacturing.
2) Metallurgy and Alloying: Approximately 85% of total vanadium is used in special steel production, and V2O5 is the key precursor to producing vanadium aluminum master alloys for aerospace and high-stress structural applications.
3) Energy Storage (Batteries): It is a crucial component in vanadium redox flow batteries (VRFBs) for large-scale grid energy storage, as well as a cathode material in high-capacity lithium-ion batteries.
4) Ceramics and Glass Manufacturing: It is used as a pigment, yielding yellow, green, and blue colors in glazes for tiles and sanitary ware, and in specialized glass coating.
5) Other Applications: It is utilized in the manufacturing of photographic developers and as a sensing material in infrared detectors and gas sensors.

V2O5 is a highly stable metal-oxide semiconductor often used as a pigment or specialized catalytic agent in ceramic production. It is also utilized in research regarding chemical and battery applications, serving as a primary ingredient for creating higher-capacity anodes in, for instance, Sodium-Ion or Zinc-Ion battery systems.

Details

Vanadium(V) oxide (vanadia) is the inorganic compound with the formula V2O5. Commonly known as vanadium pentoxide, it is a dark yellow solid, although when freshly precipitated from aqueous solution, its colour is deep orange. Because of its high oxidation state, it is both an amphoteric oxide and an oxidizing agent. From the industrial perspective, it is the most important compound of vanadium, being the principal precursor to alloys of vanadium and is a widely used industrial catalyst.

The mineral form of this compound, shcherbinaite, is extremely rare, almost always found among fumaroles. A mineral trihydrate, V2O5·3H2O, is also known under the name of navajoite.

Preparation

Technical grade V2O5 is produced as a black powder used for the production of vanadium metal and ferrovanadium. A vanadium ore or vanadium-rich residue is treated with sodium carbonate and an ammonium salt to produce sodium metavanadate, NaVO3. This material is then acidified to pH 2–3 using H2SO4 to yield a precipitate of "red cake". The red cake is then melted at 690 °C to produce the crude V2O5.

Vanadium(V) oxide is produced when vanadium metal is heated with excess oxygen, but this product is contaminated with other, lower oxides. A more satisfactory laboratory preparation involves the decomposition of ammonium metavanadate at 500–550 °C:

2 NH4VO3 → V2O5 + 2 NH3 + H2O

Uses:

Ferrovanadium production

In terms of quantity, the dominant use for vanadium(V) oxide is in the production of ferrovanadium (see above). The oxide is heated with scrap iron and ferrosilicon, with lime added to form a calcium silicate slag. Aluminium may also be used, producing the iron-vanadium alloy along with alumina as a byproduct.

Sulfuric acid production

Another important use of vanadium(V) oxide is in the manufacture of sulfuric acid, an important industrial chemical with an annual worldwide production of 165 million tonnes in 2001, with an approximate value of US$8 billion. Vanadium(V) oxide serves the crucial purpose of catalysing the mildly exothermic oxidation of sulfur dioxide to sulfur trioxide by air in the contact process:

2 SO2 + O2 ⇌ 2 SO3

The discovery of this simple reaction, for which V2O5 is the most effective catalyst, allowed sulfuric acid to become the cheap commodity chemical it is today. The reaction is performed between 400 and 620 °C; below 400 °C the V2O5 is inactive as a catalyst, and above 620 °C it begins to break down. Since it is known that V2O5 can be reduced to VO2 by SO2, one likely catalytic cycle is as follows:

SO2 + V2O5 → SO3 + 2 VO2

followed by

2 VO2 + 1⁄2 O2 → V2O5

It is also used as catalyst in the selective catalytic reduction (SCR) of NOx emissions in some power plants and diesel engines. Due to its effectiveness in converting sulfur dioxide into sulfur trioxide, and thereby sulfuric acid, special care must be taken with the operating temperatures and placement of a power plant's SCR unit when firing sulfur-containing fuels.

Other applications

Due to its high coefficient of thermal resistance, vanadium(V) oxide finds use as a detector material in bolometers and microbolometer arrays for thermal imaging. It also finds application as an ethanol sensor in ppm levels (up to 0.1 ppm).

Vanadium redox batteries are a type of flow battery used for energy storage, including large power facilities such as wind farms. Vanadium oxide is also used as a cathode in lithium-ion batteries.

Vanadium pentoxide is often used as a component in glazes where it produces a wide range of colours from greens and yellows to blues and grays.

Additional Information

Vanadium pentoxide is used in different, industrial processes as catalyst: In the contact process it serves for the oxidation of SO2 to SO3 with oxygen at 440°C. Besides it is used in the oxidation of ethanol to ethanale and in the production of phthalic anydride, polyamide, oxalic acid and further products.

Vanadium pentoxide is a stable oxide of vanadium with an oxidation state of +5. It is extensively used as an n-type semiconductor, a cathode material in lithium batteries, and an industrial catalyst. It is also used in glass and ceramic glazes, as a steel additive, and in welding electrode coatings. Additionally, it is used as a catalyst in chemical reactions and in the manufacture of ceramics.

Jai Ganesh · Dark Discussions at Cafe Infinity

2466) Max Theiler

Gist:

Work

Yellow fever is a disease that used to be fairly common and claimed many lives in the tropics. The disease is caused by a virus and is transmitted to people by insects and also from one person to another. Max Theiler succeeded in transmitting the virus to mice, which paved the way for more in-depth research. When the virus was transmitted between mice, a weakened form of the virus was obtained that could make apes immune. In 1937 Theiler succeeded in obtaining an even weaker variant of the virus. This variant, 17D, came to be used as a human vaccine.

Summary

Max Theiler (born January 30, 1899, Pretoria, South Africa—died August 11, 1972, New Haven, Connecticut, U.S.) was a South African-born American microbiologist who won the 1951 Nobel Prize for Physiology or Medicine for his development of a vaccine against yellow fever.

Theiler received his medical training at St. Thomas’s Hospital, London, and the London School of Hygiene and Tropical Medicine, graduating in 1922. In that year he joined the department of tropical medicine at Harvard Medical School, Boston. There he carried out important studies of amebic dysentery and rat-bite fever and began work on yellow fever.

In 1930 Theiler joined the laboratories at the Rockefeller Foundation’s International Health Division in New York City, where he continued his research on infectious diseases, including yellow fever. With the discovery in 1928 that rhesus monkeys were susceptible to the virus responsible for yellow fever, researchers began to develop vaccines against the disease. Theiler discovered that the common mouse is also susceptible to the yellow fever virus, a finding that facilitated the vaccine research. In the late 1930s Theiler developed the first attenuated, or weakened, strain of the virus. Further studies led to the development of the improved 17D strain that became widely used for human immunization against yellow fever.

Theiler was director of the Rockefeller Foundation Virus Laboratories from 1951 to 1963. After retiring from the Rockefeller Foundation in 1964, he became professor of epidemiology and microbiology at Yale University, where he remained until 1967.

Details

Max Theiler (30 January 1899 – 11 August 1972) was a South African-American virologist and physician. He was awarded the Nobel Prize in Physiology or Medicine in 1951 for developing a vaccine against yellow fever in 1937, becoming the first African-born Nobel laureate.

Born in Pretoria, Theiler was educated in South Africa through completion of his degree in medical school. He went to London for postgraduate work at St Thomas's Hospital Medical School and at the London School of Hygiene and Tropical Medicine, earning a 1922 diploma in tropical medicine and hygiene. That year, he moved to the United States to do research at the Harvard University School of Tropical Medicine. He lived and worked in that nation the rest of his life. In 1930, he moved to the Rockefeller Foundation in New York, becoming director of the Virus Laboratory.

Early life and education

Theiler was born in Pretoria, the capital of the South African Republic (now South Africa); his father Arnold Theiler was a veterinary bacteriologist. He attended Pretoria Boys High School, Rhodes University College, and University of Cape Town Medical School, graduating in 1918. He left South Africa for London to study at St Thomas's Hospital Medical School, King's College London, and at the London School of Hygiene and Tropical Medicine. In 1922, he was awarded a diploma in tropical medicine and hygiene; he became a licentiate of the Royal College of Physicians of London and a member of the Royal College of Surgeons of England.

Career development

Theiler wanted to pursue a career in research, so in 1922, he took a position at the Harvard University School of Tropical Medicine in Cambridge, Massachusetts. He spent several years investigating amoebic dysentery and trying to develop a vaccine for rat-bite fever.

After becoming assistant to Andrew Sellards, he started working on yellow fever. In 1926, they disproved Hideyo Noguchi's hypothesis that yellow fever was caused by the bacterium Leptospira icteroides. In 1928, the year after the disease was identified conclusively as being caused by a virus, they showed that the African and South American viruses are immunologically identical. (This followed Adrian Stokes' inducing yellow fever in rhesus macaques from India). In the course of this research, Theiler contracted yellow fever, but survived and developed immunity.

In 1930, Theiler moved to the Rockefeller Foundation in New York, where he later became director of the Virus Laboratory. He was professor of epidemiology and public health at the Yale School of Medicine and the School of Public Health from 1964 to 1967.

Work on yellow fever

After passing the yellow fever virus through laboratory mice, Theiler found that the weakened virus conferred immunity on rhesus macaques. The stage was set for Theiler to develop a vaccine against the disease. Theiler first devised a test for the efficacy of experimental vaccines. In his test, sera from vaccinated human subjects were injected into mice to see if they protected the mice against yellow fever virus. This "mouse protection test" was used with variations as a measure of immunity until after World War II. Subculturing the particularly virulent Asibi strain from West Africa in chicken embryos, a technique pioneered by Ernest Goodpasture, the Rockefeller team sought to obtain an attenuated strain of the virus that would not kill mice when injected into their brains. It took until 1937, and more than 100 subcultures in chicken embryos, for Theiler and his colleague Hugh Smith to obtain an attenuated strain, which they named "17D". Animal tests showed the attenuated 17D mutant was safe and immunizing. Theiler's team rapidly completed the development of a 17D vaccine, and the Rockefeller Foundation began human trials in South America. Between 1940 and 1947, the Rockefeller Foundation produced more than 28 million doses of the vaccine and finally ended yellow fever as a major disease.

For this work, Theiler received the 1951 Nobel Prize in Physiology or Medicine. Theiler also was awarded the Royal Society of Tropical Medicine and Hygiene's Chalmers Medal in 1939, Harvard University's Flattery Medal in 1945, and the American Public Health Association's Lasker Award in 1949.

Theiler's murine encephalomyelitis virus

In 1937, Max Theiler discovered a filterable agent that was a known cause for paralysis in mice. He found the virus was not transmittable to rhesus macaques (rhesus monkey, a species of Old World Monkey) and that only some mice developed symptoms. The virus is now referred to as Theiler's murine encephalomyelitis virus. The virus has been well characterized, and now serves as a standard model for studying multiple sclerosis.

Private life

He married Lillian Graham (1895–1977) in 1928, and they had one daughter. He died on 11 August 1972 in New Haven, Connecticut.

Jai Ganesh · Jokes

Q: What did the apple say to the orange?
A: Nothing stupid, apples don't talk.
* * *
Q: Why do the Tennessee Volunteers have orange jerseys?
A: So they can play the game, direct traffic, and pick up trash without changing.
* * *
Q: Where do plastic oranges live?
A: Orange County.
* * *
Q: Why did the orange go to the doctor?
A: It wasn't peeling well.
* * *
Q: What kind of monkey doesn't eat bananas?
A: An orangutan.
* * *

Jai Ganesh · Dark Discussions at Cafe Infinity

Comfortable Quotes - II

1. I'll work with a director if I think I'm going to get into a comfortable situation, and if it's someone I respect and who respects me, even if they're not so well known. Movies are hard to make, and you have to work toward a common ethic and do your best. - Robert De Niro

2. War is a way of shattering to pieces... materials which might otherwise be used to make the masses too comfortable and... too intelligent. - George Orwell

3. There's nothing wrong with a woman being comfortable, confident. - Selena Gomez

4. I don't see myself going out in sweats, dropping Barron at school in sweats - it's just not my style - never was. I like to put myself together and go out. I do wear jeans and T-shirt though! I like them - why not? They're very comfortable, and when I'm home and playing with my child, I like to wear a white T-shirt and jeans. - Melania Trump

5. I never felt comfortable with myself, because I was never part of the majority. I always felt awkward and shy and on the outside of the momentum of my friends' lives. - Steven Spielberg

6. I know what I believe, I know what I want to do, and I'm just comfortable saying it, and laying it out there. - Joe Biden

7. Most actors don't like doing still photo shoots, but I love them. I'm very comfortable, and I enjoy the clothes, looking good, and freezing the moment. - Asin

8. I look at myself, and I see a Spanish person who's trying to be understood by an English-speaking audience and is putting a lot of energy into that, instead of into expressing himself freely and feeling comfortable. - Javier Bardem.

Jai Ganesh · This is Cool

Allotrope/Allotropy

Gist

Allotropes are different structural forms of the same element in the same physical state (solid, liquid, or gas). They possess distinct physical and chemical properties due to variations in how their atoms are bonded and arranged. Common examples include carbon (diamond, graphite, graphene) and oxygen (dioxygen, ozone).

Allotropes are different structural forms of the same element in the same physical state (solid, liquid, or gas). While they share identical chemical properties, they possess distinct physical properties (e.g., density, hardness, electrical conductivity) due to variations in how their atoms bond or arrange themselves, such as in diamond and graphite.

Summary

Allotropy or allotropism is the property of some chemical elements to exist in two or more different forms, in the same physical state, known as allotropes of the elements. Allotropes are different structural modifications of an element: the atoms of the element are bonded together in different manners. For example, the allotropes of carbon include diamond (the carbon atoms are bonded together to form a cubic lattice of tetrahedra), graphite (the carbon atoms are bonded together in sheets of a hexagonal lattice), graphene (single sheets of graphite), and fullerenes (the carbon atoms are bonded together in spherical, tubular, or ellipsoidal formations).

The term allotropy is used for elements only, not for compounds. The more general term, used for any compound, is polymorphism, although its use is usually restricted to solid materials such as crystals. Allotropy refers only to different forms of an element within the same physical phase (the state of matter, i.e. plasmas, gases, liquids, or solids). The differences between these states of matter would not alone constitute examples of allotropy. Allotropes of chemical elements are frequently referred to as polymorphs or as phases of the element.

For some elements, allotropes have different molecular formulae or different crystalline structures, as well as a difference in physical phase; for example, two allotropes of oxygen (dioxygen, O2, and ozone, O3) can both exist in the solid, liquid and gaseous states. Other elements do not maintain distinct allotropes in different physical phases; for example, phosphorus has numerous solid allotropes, which all revert to the same P4 form when melted to the liquid state.

Details

Have you ever wondered looking at a chameleon (if at all you could recognise one sitting on a branch of a tree or so) how quickly it can change its colour. Indeed this is intriguingly admirable how one single species can exist in multiple physical forms without changing its core properties or values!

Certain elements in our periodic table are known to exhibit such properties wherein a particular element in the same physical state can exhibit more than one physical form. Allotropy originated from the Greek word ‘allottropia’ meaning ‘changeable’.

In the year 1841, Swedish scientist Baron Jöns Jakob Berzelius first proposed the concept of Allotropy.

Let’s dig deeper into the vivid variations shown by allotropes!

Allotropes are different structural modifications of a chemical element existing mostly in the same physical state; wherein the atoms of the element are bonded together in a different manner.

What is Allotropy?

Allotropes are different structural modifications of the same element and can exhibit quite different physical properties and chemical behaviours. The change between allotropic forms is caused by physical forces like pressure, light, and temperature. Hence, the stability of a particular allotrope of an element depends on particular conditions and its structural composition.

Many elements (especially non-metals) from the p-block of the periodic table exhibit allotropy. For example, carbon, oxygen, phosphorus, sulphur, and selenium from the p-block exhibit allotropy. Allotropes of carbon include diamond, graphite, graphene, fullerenes, carbon nanotubes, etc. Phosphorus also has many solid state allotropes and also a gaseous phase allotrope.

Properties of Allotropes

At different temperatures, pressure conditions and atmospheric conditions, an element finds stability in different geometries where atoms are bonded in different ways. Hence, these elements show allotropy.

* Allotropes have different structural features belonging to the same element and therefore can exhibit different physical and chemical properties.
* The change between one allotropic form to another is caused by physical forces like pressure, light, and temperature.
* Stability of the different allotropes relies on specific conditions.
* For example, diamond and graphite (two allotropes of carbon) have different appearances, hardness values, melting points, boiling points, and reactivities.
* Allotropes of some elements have different molecular formulae or different crystalline structures, as well as they differ in physical phase. For example, two allotropes of oxygen (dioxygen, O2 and ozone, O3) can both exist in the solid, liquid and gaseous states.
* All elements showing allotropy do not maintain distinct allotropes in different physical phases. For example, phosphorus has numerous solid allotropes, which all revert to the same P4 form when melted to the liquid state.

Allotropes of Phosphorus

Allotropes of phosphorus are originally P4 and there are around 12 allotropes of phosphorus. The major ones are white phosphorus, red phosphorus, black phosphorus, diphosphorus (a gaseous allotrope), scarlet and violet phosphorus.

Phosphorus is a solid non-metallic compound at room temperature. The most common (and reactive) of all its allotropes is white (or yellow) phosphorus which looks like a waxy solid or plastic. The other common form of phosphorus is red phosphorus which is much less reactive and is one of the components of the matchstick head. Red phosphorus can be transformed into white phosphorus by careful heating.

Frequently Asked Questions - FAQs

Question 1. Why white phosphorus has the structure of P4 and sulphur can exist as S2?
Answer 1: White phosphorus has the structure of P4 as one phosphorus atom can form three bonds at a time. Thus, phosphorus forms a P4 white phosphorus tetrahedron (being sp3hybridised), while sulphur can only form two bonds. Hence, sulphur only forms rings and chains.

Question 2. Which allotrope of phosphorus is poisonous in nature?
Answer 2: The least stable, the most reactive, the most volatile, the least dense, and the most toxic of the allotropes is white phosphorus. It eventually changes to red phosphorus, a light and heat-accelerated transition.

Question 3. Which phosphorus allotrope is used in matchstick?
Answer 3: Red phosphorus. The striking surface of a matchbox is made up of red phosphorus and powdered glass, which on friction with the stick converts to white phosphorus and ignites a flame in the air.

Question 4. Why do some of the beaches show chemiluminescence?
Answer 4: White phosphorus present in the ocean helps in the production of microbes and tiny marine plants called phytoplankton. When white phosphorus is particularly abundant in the water, phytoplankton produce and store a form of phosphorus called polyphosphate to use later during times of phosphorus scarcity. This is why phytoplankton rich beaches produce chemiluminescence.

Additional Information

Allotropy is the existence of a chemical element in two or more forms, which may differ in the arrangement of atoms in crystalline solids or in the occurrence of molecules that contain different numbers of atoms. The existence of different crystalline forms of an element is the same phenomenon that in the case of compounds is called polymorphism. Allotropes may be monotropic, in which case one of the forms is the most stable under all conditions, or enantiotropic, in which case different forms are stable under different conditions and undergo reversible transitions from one to another at characteristic temperatures and pressures.

Elements exhibiting allotropy include tin, carbon, sulfur, phosphorus, and oxygen. Tin and sulfur are enantiotropic. The former exists in a gray form, stable below 13.2 °C, and a white form, stable at higher temperatures. Sulfur forms rhombic crystals, stable below 95.5 °C, and monoclinic crystals, stable between 95.5 °C and the melting point (119 °C). Carbon, phosphorus, and oxygen are monotropic. Graphite is more stable than diamond, red phosphorus is more stable than white, and diatomic oxygen, having the formula O2, is more stable than triatomic oxygen (ozone, O3) under all ordinary conditions.

Jai Ganesh · Jai Ganesh's Puzzles

Hi,

#10805. What does the term in Biology Isotonicity mean?

#10806. What does the term in Biology Jejunum mean?

Jai Ganesh · Jai Ganesh's Puzzles

Hi,

#6011. What does the noun limbo mean?

#6012. What does the noun limerick mean?

Jai Ganesh · Jai Ganesh's Puzzles

Hi,

#2602. What does the medical term Gastric glands mean?

Jai Ganesh · Jai Ganesh's Puzzles

Hi,

#9888.

Jai Ganesh · Jai Ganesh's Puzzles

Hi,

#6381.

Jai Ganesh · Exercises

Hi,

2742.

Jai Ganesh · Science HQ

Lungs

Gist

Lungs are the primary, spongy, pinkish-gray respiratory organs in the chest that enable breathing by exchanging oxygen for carbon dioxide, a process vital for life. They consist of lobes (three on the right, two on the left), fill with air via the trachea and bronchial tree during inhalation, and are protected by the rib cage and pleural membrane.

The lungs are the primary organs of the respiratory system, responsible for taking in oxygen from the air (inhalation) and expelling carbon dioxide (exhalation). They deliver oxygen to the bloodstream for cellular energy and remove metabolic waste, maintaining pH balance and supporting immune functions.

Summary

The lungs are the primary organs of the respiratory system in many animals, including humans. In mammals and most other tetrapods, two lungs are located near the backbone on either side of the heart. Their function in the respiratory system is to extract oxygen from the atmosphere and transfer it into the bloodstream, and to release carbon dioxide from the bloodstream into the atmosphere, in a process of gas exchange. Respiration is driven by different muscular systems in different species. Mammals, reptiles and birds use their musculoskeletal systems to support and foster breathing. In early tetrapods, air was driven into the lungs by the pharyngeal muscles via buccal pumping, a mechanism still seen in amphibians. In humans, the primary muscle that drives breathing is the diaphragm. The lungs also provide airflow that makes vocalisation including speech possible.

Humans have two lungs, a right lung and a left lung. They are situated within the thoracic cavity of the chest. The right lung is bigger than the left, and the left lung shares space in the chest with the heart. The lungs together weigh approximately 1.3 kilograms (2.9 lb), and the right is heavier. The lungs are part of the lower respiratory tract that begins at the trachea and branches into the bronchi and bronchioles, which receive air breathed in via the conducting zone. These divide until air reaches microscopic alveoli, where gas exchange takes place. Together, the lungs contain approximately 2,400 kilometers (1,500 mi) of airways and 300 to 500 million alveoli. Each lung is enclosed within a pleural sac of two pleurae which allows the inner and outer walls to slide over each other whilst breathing takes place, without much friction. The inner visceral pleura divides each lung as fissures into sections called lobes. The right lung has three lobes and the left has two. The lobes are further divided into bronchopulmonary segments and lobules. The lungs have a unique blood supply, receiving deoxygenated blood sent from the heart to receive oxygen (the pulmonary circulation) and a separate supply of oxygenated blood (the bronchial circulation).

The tissue of the lungs can be affected by several respiratory diseases including pneumonia and lung cancer. Chronic diseases such as chronic obstructive pulmonary disease and emphysema can be related to smoking or exposure to harmful substances. Diseases such as bronchitis can also affect the respiratory tract. Medical terms related to the lung often begin with pulmo-, from the Latin pulmonarius (of the lungs) as in pulmonology, or with pneumo- as in pneumonia.

In embryonic development, the lungs begin to develop as an outpouching of the foregut, a tube which goes on to form the upper part of the digestive system. When the lungs are formed the fetus is held in the fluid-filled amniotic sac and so they do not function to breathe. Blood is also diverted from the lungs through the ductus arteriosus. At birth however, air begins to pass through the lungs, and the diversionary duct closes so that the lungs can begin to respire.

Details:

What Are Lungs?

Your lungs are a pair of organs that are the main part of your respiratory system, a network of structures and tissues that allow you to breathe. They pull air into your body so your tissues can get oxygen.

You have two lungs, a right and a left. Many people think of them like balloons. But they’re actually made up of spongy tissue, airways (tubes that air travels through), air sacs (alveoli) and blood vessels. The blood vessels pick up oxygen from the air sacs and deliver it to the rest of your body.

Function:

What do lungs do?

Your lungs’ main function is to bring oxygen to your blood and remove carbon dioxide from your body. When you inhale through your nose or mouth, air travels down your pharynx (back of your throat), passes through your larynx (voice box) and into your trachea (windpipe). Then, it moves into your left and right bronchial tubes and into smaller and smaller passages (bronchioles).

Your airways end in tiny air sacs called alveoli. These are surrounded by blood vessels. Your alveoli hold the air, and the blood that flows by picks up oxygen. Your blood delivers the oxygen to your tissues to use for energy. At the same time, your blood also drops off carbon dioxide to your lungs, which you breathe out on your next exhale. This process happens 12 to 20 times per minute.

Anatomy:

Where are your lungs in your body?

Your lungs are located in your chest (thorax), inside your rib cage. Your thoracic cavity is the space that contains your lungs and other organs of your chest.

Lung structure

Your lungs are made up of spongy, pinkish-gray tissue (connective tissue). They’re thicker in your back and get thinner as they curve around to your chest. They’re shaped a bit like cones or upside-down elephant ears: They have a narrow top part that extends toward your shoulders and a wider bottom.

Your bronchial tubes enter your lungs and branch into smaller and smaller airways until they reach the alveoli. The alveoli look a bit like a bunch of tiny grapes. Your lungs are covered in thin layers of tissue called pleura. These layers reduce friction as your lungs get bigger when they fill and smaller when they empty. Many blood vessels bring blood into and out of your lungs.

You have two lungs, one on each side of your chest. Each lung is divided into sections (lobes). They’re separated by folds called fissures. Your lungs rest on your diaphragm, a muscle that contracts and relaxes to pull air into your lungs.

Right lung

The lung on your right side is divided into three lobes: the superior, the middle and the inferior. It’s shorter and wider than your left lung.

Left lung

Your left lung has two lobes: the superior and the inferior. The superior lobe has an indent (cardiac notch) to make space for your heart. The piece of the superior lobe that curls down around the left and bottom of your heart is called the lingula.

How big are your lungs?

A typical adult lung weighs about 2.2 pounds (1 kilogram) and is a little longer than 9 inches (about 24 centimeters) when you’re breathing normally. It’s about 10.5 inches (27 cm) when your lungs are completely expanded.

Conditions and Disorders:

What diseases affect your lungs?

Conditions that affect your lungs include:

* Asthma: Inflammation of your airways when you’re exposed to triggers
* Bronchiectasis: Widened airways that can develop pouches
* Bronchitis: Inflammation and mucus in your airways
* COPD (chronic obstructive pulmonary disease): Damage to your airways that blocks your breathing and gets worse over time
* Cystic fibrosis: An inherited condition that causes sticky mucus to build up in your lungs and other organs
* Infections: Flu, COVID-19, RSV, tuberculosis and other germs can infect your lungs and airways
* Interstitial lung disease: Damage and scarring in your lungs, like pulmonary fibrosis and asbestosis
* Lung cancer: Growths in your lungs that can spread to other organs
* Mesothelioma: A type of cancer in the lining of your lungs
* Pneumonia: Inflammation and fluid in your lungs caused by an infection
* Pulmonary nodules: “Spots” on your lungs

Signs and symptoms

Symptoms of lung disease can include:

* Cough
* Chest pain, tightness or discomfort
* Shortness of breath
* Tiredness

These symptoms are common, and many other conditions can cause them. Talk to a healthcare provider if you’re experiencing symptoms that affect your breathing.

Care:

How to care for your lungs

To keep your lungs healthy:

* Don’t smoke or vape. It’s never too late to quit.
* If you have to work with materials that create dust or fumes, wear a respirator mask and make sure the area is well-ventilated.
* Maintain a weight that’s healthy for you.
* Get regular physical activity. This helps your heart and lung muscles stay strong.
* Drink plenty of fluids.
* Take steps to avoid respiratory infections. This includes washing your hands frequently and wearing a mask when respiratory illnesses, like the flu and COVID-19, are spreading. Ask a provider which vaccines are recommended for you.

Additional Information:

Why Are Lungs Important?

Every cell in your body needs oxygen to live. The air we breathe contains oxygen and other gases. The respiratory system's main job is to move fresh air into your body while removing waste gases.

Once in the lungs, oxygen is moved into the bloodstream and carried through your body. At each cell in your body, oxygen is exchanged for a waste gas called carbon dioxide. Your bloodstream then carries this waste gas back to the lungs where it is removed from the bloodstream and then exhaled. Your lungs and respiratory system automatically perform this vital process, called gas exchange.

In addition to gas exchange, your respiratory system performs other roles important to breathing. These include:

* Bringing air to the proper body temperature and moisturizing it to the right humidity level.
* Protecting your body from harmful substances. This is done by coughing, sneezing, filtering or swallowing them.
* Supporting your sense of smell.

The Parts of the Respiratory System and How They Work:

Airways

* SINUSES are hollow spaces in the bones of your head above and below your eyes that are connected to your nose by small openings. Sinuses help regulate the temperature and humidity of inhaled air.
* The NOSE is the preferred entrance for outside air into the respiratory system. The hairs lining the nose's wall are part of the air-cleaning system.
* Air also enters through the MOUTH, especially for those who have a mouth-breathing habit, whose nasal passages may be temporarily blocked by a cold, or during heavy exercise.
* The THROAT collects incoming air from your nose and mouth then passes it down to the windpipe (trachea).
* The WINDPIPE (trachea) is the passage leading from your throat to your lungs.
* The windpipe divides into the two main BRONCHIAL TUBES, one for each lung, which divides again into each lobe of your lungs. These, in turn, split further into bronchioles.

Lungs and Blood Vessels

* Your right lung is divided into three LOBES, or sections. Each lobe is like a balloon filled with sponge-like tissue. Air moves in and out through one opening—a branch of the bronchial tube.
* Your left lung is divided into two LOBES.
* The PLEURA are the two membranes, actually, one continuous one folded on itself, that surround each lobe of the lungs and separate your lungs from your chest wall.
* Your bronchial tubes are lined with CILIA (like very small hairs) that move like waves. This motion carries MUCUS (sticky phlegm or liquid) upward and out into your throat, where it is either coughed up or swallowed. Mucus catches and holds much of the dust, germs, and other unwanted matter that has invaded your lungs. You get rid of this matter when you cough, sneeze, clear your throat or swallow.
* The smallest branches of the bronchial tubes are called BRONCHIOLES, at the end of which are the air sacs or alveoli.
* ALVEOLI are the very small air sacs where the exchange of oxygen and carbon dioxide takes place.
* CAPILLARIES are blood vessels in the walls of the alveoli. Blood passes through the capillaries, entering through your PULMONARY ARTERY and leaving via your PULMONARY VEIN. While in the capillaries, blood gives off carbon dioxide through the capillary wall into the alveoli and takes up oxygen from air in the alveoli.

Muscles and Bones

* Your DIAPHRAGM is the strong wall of muscle that separates your chest cavity from the abdominal cavity. By moving downward, it creates suction in the chest, drawing in air and expanding the lungs.
* RIBS are bones that support and protect your chest cavity. They move slightly to help your lungs expand and contract.

Keeping Lungs Healthy

Lung capacity declines as you age. Keep your lungs healthy by taking good care of yourself every day. Eat a balanced diet, exercise and reduce stress to breathe easier. Get more tips for healthy lungs.

1800x1200_respiratory_system_bigbead.jpg?resize=750px:*&output-quality=75

Jai Ganesh · This is Cool

2528) MASER

Gist

A maser (Microwave Amplification by Stimulated Emission of Radiation) is a device that produces coherent, highly focused electromagnetic waves in the microwave spectrum. Invented in the 1950s, it works by stimulating atoms to emit energy, often used for low-noise amplification in radio telescopes, atomic clocks, and satellite communications.

Masers (Microwave Amplification by Stimulated Emission of Radiation) produce coherent, low-noise microwave signals used for precise timekeeping in atomic clocks, deep-space communication, and high-sensitivity radio astronomy. They are essential for tracking spacecraft, studying interstellar molecular clouds, and providing stable frequency standards for radar.

Summary

A maser is a device that produces coherent electromagnetic waves (microwaves), through amplification by stimulated emission. The term is an acronym for microwave amplification by stimulated emission of radiation. Nikolay Basov, Alexander Prokhorov and Joseph Weber introduced the concept of the maser in 1952, and Charles H. Townes, James P. Gordon, and Herbert J. Zeiger built the first maser at Columbia University in 1953. Townes, Basov and Prokhorov won the 1964 Nobel Prize in Physics for theoretical work leading to the maser. Masers are used as timekeeping devices in atomic clocks, and as extremely low-noise microwave amplifiers in radio telescopes and deep-space spacecraft communication ground-stations.

Modern masers can be designed to generate electromagnetic waves at microwave frequencies and radio and infrared frequencies. For this reason, Townes suggested replacing "microwave" with "molecular" as the first word in the acronym "maser".

The laser works by the same principle as the maser, but produces higher-frequency coherent radiation at visible wavelengths. The maser was the precursor to the laser, inspiring theoretical work by Townes and Arthur Leonard Schawlow that led to the invention of the laser in 1960 by Theodore Maiman. When the coherent optical oscillator was first imagined in 1957, it was originally called the "optical maser". This was ultimately changed to laser, for "light amplification by stimulated emission of radiation". Gordon Gould is credited with creating this acronym in 1957.

Details

A maser is a device that produces and amplifies electromagnetic radiation in the microwave range of the spectrum. The first maser was built by the American physicist Charles H. Townes. Its name is an acronym for “microwave amplification by stimulated emission of radiation.” The wavelength produced by a maser is so constant and reproducible that it can be used to control a clock that will gain or lose no more than a second over hundreds of years. Masers have been used to amplify faint signals returned from radar and communications satellites, and have made it possible to measure faint radio waves emitted by Venus, giving an indication of the planet’s temperature. The maser was the principal precursor of the laser.

A maser oscillator requires a source of excited atoms or molecules and a resonator to store their radiation. The excitation must force more atoms or molecules into the upper energy level than in the lower, in order for amplification by stimulated emission to predominate over absorption. For wavelengths of a few millimetres or longer, the resonator can be a metal box whose dimensions are chosen so that only one of its modes of oscillation coincides with the frequency emitted by the atoms; that is, the box is resonant at the particular frequency, much as a kettle drum is resonant at some particular audio frequency. The losses of such a resonator can be made quite small, so that radiation can be stored long enough to stimulate emission from successive atoms as they are excited. Thus, all the atoms are forced to emit in such a way as to augment this stored wave. Output is obtained by allowing some radiation to escape through a small hole in the resonator.

The first maser used a beam of ammonia molecules that passed along the axis of a cylindrical cage of metal rods, with alternate rods having positive and negative electric charge. The nonuniform electric field from the rods sorted out the excited from the unexcited molecules, focusing the excited molecules through a small hole into the resonator. The output was less than one microwatt (10-6 watt) of power, but the wavelength, being determined primarily by the ammonia molecules, was so constant and reproducible that it could be used to control a clock that would gain or lose no more than a second in several hundred years. This maser can also be used as a microwave amplifier. Maser amplifiers have the advantage that they are much quieter than those that use vacuum tubes or transistors; that is, they add very little noise to the signal being amplified. Very weak signals can thus be utilized. The ammonia maser amplifies only a very narrow band of frequencies and is not tunable, however, so that it has largely been superseded by other kinds, such as solid-state ruby masers.

Solid-state and traveling-wave masers

Amplification of radio waves over a wide band of frequencies can be obtained in several kinds of solid-state masers, most commonly crystals such as ruby at low temperatures. Suitable materials contain ions (atoms with an electrical charge) whose energy levels can be shifted by a magnetic field so as to tune the substance to amplify the desired frequency. If the ions have three or more energy levels suitably spaced, they can be raised to one of the higher levels by absorbing radio waves of the proper frequency.

The amplifying crystal may be operated in a resonator that, as in the ammonia maser, stores the wave and so gives it more time to interact with the amplifying medium. A large amplifying bandwidth and easier tunability are obtained with traveling-wave masers. In these, a rod of a suitable crystal, such as ruby, is positioned inside a wave-guide structure that is designed to cause the wave to travel relatively slowly through the crystal.

Solid masers have been used to amplify the faint signals returned from such distant targets as satellites in radar and communications. Their sensitivity is especially important for such applications because signals coming from space are usually very weak. Moreover, there is little interfering background noise when a directional antenna is pointed at the sky, and the highest sensitivity can be used. In radio astronomy, masers made possible the measurement of the faint radio waves emitted by the planet Venus, giving the first indication of its temperature.

Gas masers

Generation of radio waves by stimulated emission of radiation has been achieved in several gases in addition to ammonia. Hydrogen cyanide molecules have been used to produce a wavelength of 3.34 mm. Like the ammonia maser, this maser uses electric fields to select the excited molecules.

One of the best fundamental standards of frequency or time is the atomic hydrogen maser introduced by American scientists N.F. Ramsey, H.M. Goldenberg, and D. Kleppner in 1960. Its output is a radio wave whose frequency of 1,420,405,751.786 hertz (cycles per second) is reproducible with an accuracy of one part in 30 × 1012. A clock controlled by such a maser would not get out of step more than one second in 100,000 years.

In the hydrogen maser, hydrogen atoms are produced in a discharge and, like the molecules of the ammonia maser, are formed into a beam from which those in excited states are selected and admitted to a resonator. To improve the accuracy, the resonance of each atom is examined over a relatively long time. This is done by using a very large resonator containing a storage bulb. The walls of the bulb are coated so that the atoms can bounce repeatedly against the walls with little disturbance of their frequency.

Another maser standard of frequency or time uses vapour of the element rubidium at a low pressure, contained in a transparent cell. When the rubidium is illuminated by suitably filtered light from a rubidium lamp, the atoms are excited to emit a frequency of 6.835 gigahertz (6.835 × 109 hertz). As the cell is enclosed in a cavity resonator with openings for the pumping light, emission of radio waves from these excited atoms is stimulated.

Additional Information

MASER stands for Microwave Amplification by Stimulation Emission of Radiation. A LASER is a MASER that works with higher frequency photons in the ultraviolet or visible light spectrum (photons are bundles of electromagnetic energy commonly thought of as "rays of light" which travel in oscillating waves of various wavelengths) .

The first papers about the MASER were published in 1954 as a result of investigations carried out simultaneously and independently by Charles Townes and co-workers at Columbia University in New York and by Dr. Basov and Dr. Prochorov at the Lebedev Institute in Moscow. All three of these gentlemen received the Nobel Prize in 1964 for their contributions to science.

[The following was paraphrased in part from Halliday & Resnick's "Fundamentals of Physics", second edition.]

The fundamental physical principle motivating the MASER is the concept of stimulated emission, first introduced by Einstein in 1917. Before defining it we look at two related but more familiar phenomena involving the interplay between matter and radiation, absorption and spontaneous emission.

* Absorption. According to quantum mechanics, absorption of photons by atoms occurs only if the wavelength of the photon is just the right size (say, of wavelength l). If it is, the atom will "absorb" it (the photon vanishes) and go to a higher energy state. In physics, this process is called "absorption."

* Spontaneous Emission. Atoms don't like to stay in high energy states (this is dictated by the laws of thermodynamics), so after absorbing a photon and going to a higher energy state, they will move of their own accord to a lower energy state, emitting a photon in the process. This is called "spontaneous emission" because no outside influence triggers the emission. Normally the average lifetime for spontaneous emissions by excited atoms is around 10-8 seconds (that is, the atom or molecule will usually take around 10-8 seconds before emitting the photon). Occasionally, however, there are states for which the lifetime is much longer, perhaps around 10-3 seconds. These states are called metastable. Metastable emission levels are essential for a working MASER and will be discussed further in a moment.

Now that we've discussed absorption and spontaneous emission, we can get to stimulated emission (a MASER beam is made up entirely of stimulated emission).

* Stimulated Emission. With stimulated emission, a photon of the absorption wavelength, l , is fired at an atom already in its high energy state from prior absorption. The atom absorbs this photon, and then quickly emits two photons to get back to its lower energy state. Thanks to quantum mechanics, both of these newly emitted photons are of wavelength l! The following figure displays this concept in detail:

* MASER. In each frame, a molecule in the upper level of the MASER transition (that is, in the high energy, excited state) is indicated by a large red circle, while one in the lower level (low energy state) is indicated by a small blue circle. (a) All of the molecules are in the upper state and a photon of wavelength l (shown in green) is incident from the left. (b) The photon l stimulates emission from the first molecule, so there are now two photons of wavelength l, in phase. (c) These photons stimulate emission from the next two molecules, resulting in four photons of wavelength l. (d) The process continues with another doubling of the number of photons.

Basically, a man-made MASER is a device that sets up a series of atoms or molecules and excites them to generate the chain reaction, or amplification, of photons. Metastable emission states make MASERs and LASERs possible. To get the proper wavelengths to generate the chain reaction, first electricity or another energy source is "pumped" into a chamber filled with particular atoms or molecules. Then this "pumping" radiation causes the transition of atoms from the ground state to a high energy excited state higher than that referred to in the above paragraphs. From this short-lived state the atoms come down through non-radiative transition to the long-lived metastable state. Once in the metastable state many atoms can be accumulated in one place and in the same state. The LASER or MASER beam, stimulated emission, arises when all these accumulated atoms simultaneously make a transition to the ground state, releasing their energy of wavelength l, creating a beam of microwave radiation (or visible light in the case of a LASER) which can be sent on to other atoms to cause the chain reaction described in the above figure. Since all the resulting photons are the same wavelength, MASER beams are extremely focussed and coherent. MASERs and their shorter-wavelength counterparts (LASERs), have many practical applications, especially in science and medicine.

Naturally occurring MASERs have been discovered in interstellar space. For more information about MASERs in space, check out this site for a discussion of astrophysical MASERs.

Jai Ganesh · Dark Discussions at Cafe Infinity

2465) Glenn Theodore Seaborg

Gist:

Work

The heaviest element existing in nature is uranium, which has an atomic number of 92. All of the heavier elements are radioactive and quickly decay. It has become apparent, however, that they can be created by bombarding atoms with particles and atomic nuclei. After initial contributions by Edwin McMillan, Glenn Seaborg succeeded in 1940 in creating an element with an atomic number of 94, which was named plutonium. This new substance became significant for both nuclear weapons and nuclear energy. Seaborg subsequently identified additional heavy elements and their isotopes.

Summary

Glenn Theodore Seaborg (April 19, 1912 – February 25, 1999) was an American chemist whose involvement in the synthesis, discovery and investigation of ten transuranium elements earned him a share of the 1951 Nobel Prize in Chemistry. His work in this area also led to his development of the actinide concept and the arrangement of the actinide series in the periodic table of the elements.

Seaborg spent most of his career as an educator and research scientist at the University of California, Berkeley, serving as a professor, and, between 1958 and 1961, as the university's second chancellor. He advised ten US presidents—from Harry S. Truman to Bill Clinton—on nuclear policy and was Chairman of the United States Atomic Energy Commission from 1961 to 1971, where he pushed for commercial nuclear energy and the peaceful applications of nuclear science. Throughout his career, Seaborg worked for arms control. He was a signatory to the Franck Report and contributed to the Limited Test Ban Treaty, the Nuclear Non-Proliferation Treaty and the Comprehensive Test Ban Treaty. He was a well-known advocate of science education and federal funding for pure research. Toward the end of the Eisenhower administration, he was the principal author of the Seaborg Report on academic science, and, as a member of President Ronald Reagan's National Commission on Excellence in Education, he was a key contributor to its 1983 report "A Nation at Risk".

Seaborg was the principal or co-discoverer of ten elements: plutonium, americium, curium, berkelium, californium, einsteinium, fermium, mendelevium, nobelium and element 106, then called unnilhexium, which while he was still living, was named seaborgium in his honor. He said about this naming, "This is the greatest honor ever bestowed upon me—even better, I think, than winning the Nobel Prize. Future students of chemistry, in learning about the periodic table, may have reason to ask why the element was named for me, and thereby learn more about my work." He also discovered more than 100 isotopes of transuranium elements and is credited with important contributions to the chemistry of plutonium, originally as part of the Manhattan Project where he developed the extraction process used to isolate the plutonium fuel for the implosion-type atomic bomb. Early in his career, he was a pioneer in nuclear medicine and discovered isotopes of elements with important applications in the diagnosis and treatment of diseases, including iodine-131, which is used in the treatment of thyroid disease. In addition to his theoretical work in the development of the actinide concept, which placed the actinide series beneath the lanthanide series on the periodic table, he postulated the existence of super-heavy elements in the transactinide and superactinide series.

After sharing the 1951 Nobel Prize in Chemistry with Edwin McMillan, he received approximately 50 honorary doctorates and numerous other awards and honors. The list of things named after Seaborg ranges from the chemical element seaborgium to the asteroid 4856 Seaborg. He was the author of numerous books and 500 journal articles, often in collaboration with others. He was once listed in the Guinness Book of World Records as the person with the longest entry in Who's Who in America.

Details

Glenn T. Seaborg (born April 19, 1912, Ishpeming, Michigan, U.S.—died February 25, 1999, Lafayette, California) was an American nuclear chemist best known for his work on isolating and identifying transuranium elements (those heavier than uranium). He shared the 1951 Nobel Prize for Chemistry with Edwin Mattison McMillan for their independent discoveries of transuranium elements. Seaborgium was named in his honor, making him the first person for whom a chemical element was named during his lifetime.

Seaborg learned Swedish from his immigrant mother before he learned English. When he was 10, his family moved to a suburb of Los Angeles. He received a bachelor’s degree (1934) from the University of California, Los Angeles, and a doctorate (1937) from the University of California, Berkeley. He stayed on at Berkeley as the personal laboratory assistant of Gilbert N. Lewis from 1937 to 1939. He also collaborated at Berkeley with physicist Jack Livingood to isolate a number of radioactive isotopes, including iodine-131, which later saved his mother’s life and is now used for the diagnosis and treatment of thyroid disorders. At Berkeley he was, successively, research associate, instructor, and assistant professor (1937–45), becoming professor of chemistry in 1946. He served as Berkeley’s chancellor from 1958 to 1961.

Seaborg, together with Arthur C. Wahl and Joseph W. Kennedy, produced and identified the second known transuranium element, plutonium (atomic number 94), on February 23, 1941, in Room 307 of Gilman Hall, which is now a National Historic Landmark. (McMillan had discovered the first transuranium element, neptunium [atomic number 93], the previous year at Berkeley.) In addition to plutonium, best known for its use as a fuel in certain types of nuclear reactors and as an ingredient in some nuclear weapons, Seaborg and his coworkers discovered nine more new elements (atomic numbers 95–102 and 106) between 1941 and 1955.

The early studies of plutonium were carried out on a tracer scale with amounts too small to be weighed. The first visible amount of plutonium (about a millionth of a gram of plutonium fluoride) was isolated by Seaborg, Burris B. Cunningham, and Louis B. Werner on August 20, 1942. During World War II, which Seaborg spent as a section chief at the University of Chicago Metallurgical Laboratory, the first industrial production of plutonium was undertaken in newly devised uranium reactors, and he had the primary responsibility for isolating plutonium from the reaction products and scaling up its extraction from ultramicroscopic laboratory amounts to a full-scale plant (the Hanford Engineering Works in Washington) by what he called “surely the greatest scale-up factor [10 billion] ever attempted.”

The other new elements discovered by Seaborg were americium (95), curium (96), berkelium (97), californium (98), einsteinium (99), fermium (100), mendelevium (101), nobelium (102), and seaborgium (106). By chance, Seaborg first announced the discovery of elements 95 and 96 in response to a question on a November 11, 1945, Quiz Kids radio program. The prediction of the chemical properties, method of isolation, and placement of these and many heavier elements in the periodic table of the elements was helped greatly by an important organizing principle enunciated by Seaborg in 1944 and known as the actinide concept. This was one of the most significant changes in the periodic table since Russian chemist Dmitry Mendeleyev’s original conception in 1869. Seaborg recognized that the 14 elements heavier than actinium (89) are closely related to it and belong to a separate group in the periodic table, the actinoid elements, analogous to the 14 elements heavier than lanthanum (57), the lanthanoids.

Seaborg returned to Berkeley in 1946, where he was involved in the discovery of berkelium and succeeding elements. He was the first scientist named chairman of the Atomic Energy Commission (1961–71), and the U.S. nuclear weapons and nuclear power industries developed rapidly during his tenure. Beginning in 1959, he was a leader in the movement to improve high-school and college chemistry curricula in the United States and abroad. He was a member of the National Commission on Excellence in Education that produced the 1983 report “A Nation at Risk: The Imperative for Educational Reform.”

A lifelong aficionado of athletics, Seaborg in 1958 helped establish the Athletic Association of Western Universities (now the Pacific-12 Conference). His activities and honors—governmental, academic, and educational—were so multifaceted and extensive that he was cited in the Guinness Book of World Records as having the longest entry in Who’s Who in America.

As an adviser to 10 U.S. presidents, from Franklin D. Roosevelt to George H.W. Bush, Seaborg visited more than 60 countries to promote international scientific cooperation and nuclear arms control treaties. Although he was actively involved in the development of the atomic bomb, he was one of the six signatories of the Franck Report (1945), which urged that the bomb be demonstrated to the Japanese instead of being used against a civilian population. He considered control of nuclear weapons the most crucial problem facing humanity, and he laid the groundwork for the 1968 Treaty on the Non-proliferation of Nuclear Weapons, which he considered “perhaps the most important step in arms limitation since the advent of the nuclear age.”

In 1971 Seaborg returned to the University of California, Berkeley, where he served as university professor, associate director-at-large of the Lawrence Berkeley Laboratory, and chairman of the Lawrence Hall of Science (1984–99). He died from complications of a stroke that he suffered in Boston in August 1998 at a national meeting of the American Chemical Society, the world’s largest organization devoted to a single science, in which he was very active, serving as president in 1976.

Seaborg was the author of The Transuranium Elements (1958), Man-Made Transuranium Elements (1963), Nuclear Milestones: A Collection of Speeches by Glenn T. Seaborg (1972), and A Chemist in the White House: From the Manhattan Project to the End of the Cold War (1998), which chronicles scientific and political issues through his decades of public service, including excerpts from journals and policy-making letters. Shortly after winning the Nobel Prize, Seaborg wrote a number of entries for the 14th edition of the Encyclopædia Britannica, among them the article on plutonium for the 1953 printing.

Jai Ganesh · Jokes

Q: Why do oranges wear suntan lotion?
A: Because they peel.
* * *
Q: Why did the Orange go out with a Prune?
A: Because he couldn't find a Date!
* * *
Q: What does an Orange sweat?
A: Orange Juice!
* * *
Q: Why did the girl stare at the carton of orange juice?
A: It said concentrate.
* * *
Q: Why did the orange stop rolling down the hill?
A: Because it ran out of juice!
* * *

Jai Ganesh · Dark Discussions at Cafe Infinity

Comfortable Quotes - I

1. You may not always have a comfortable life and you will not always be able to solve all of the world's problems at once but don't ever underestimate the importance you can have because history has shown us that courage can be contagious and hope can take on a life of its own. - Michelle Obama

2. Old age, believe me, is a good and pleasant thing. It is true you are gently shouldered off the stage, but then you are given such a comfortable front stall as spectator. - Confucius

3. There are risks and costs to action. But they are far less than the long range risks of comfortable inaction. - John F. Kennedy

4. A man cannot be comfortable without his own approval. - Mark Twain

5. It's always felt natural, because I'm generally very comfortable with people. - Bruce Springsteen

6. I'm more than comfortable just sitting back and scoring 21, 22 points or whatever and getting 10, 11 assists whatever the case might be. More than comfortable with that. It's just a matter of the pieces that you have around you and what you can do to elevate everybody else. - Kobe Bryant

7. Swimming is normal for me. I'm relaxed. I'm comfortable, and I know my surroundings. It's my home. - Michael Phelps

8. If you're not comfortable with public speaking - and nobody starts out comfortable; you have to learn how to be comfortable - practice. I cannot overstate the importance of practicing. Get some close friends or family members to help evaluate you, or somebody at work that you trust. - Hillary Clinton.

Jai Ganesh · Jai Ganesh's Puzzles

Hi,

#10803. What does the term in Biology Introduced species mean?

#10804. What does the term in Biology Invertebrate mean?

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