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how plastic affect oceans
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How is plastic damaging the environment?Positive/Negative/Neutral Objects - How are they different? Positive: has fewer electrons than protons Negative: Has more electrons than protons Neutral: has equal numbers of protons and electrons Laws of Electric Charges - What are they? How are they applied? Like charges repel, opposites charges attract, charged AND neutral objects attract Induced Charge Separation - Explain this process. A shift of the position of electrons when a charged object is brought near it. If the charged object is positive, the electrons will move toward it. If the charged object is negative, the electrons will move away from it. Charging by Friction (What is happening with the charges? - Know electrostatic series examples) Process in which objects made from different materials rub against each other, producing a net static charge on each object. When charged by friction, one material will have a stronger attraction to electrons and will pull the electrons off the other material Charging by Conduction (Be able to explain what the electrons are doing) Charging by contact with a charged object. An object that becomes charged by contact always gets the same type of charge that is on the object that charges it. Grounding (Be able to explain how it happens) A method of removing static charges from an object. Electrons from the ground move up to the charged object. If the object is negative, electrons leave the object. If the object is positive, electrons enter the object. The ground always remains neutral Conductors/Insulators/Semiconductors (Know examples for each and characteristics) Conductor: A material that allows electrons to flow through it easily. GOOD CONDUCTORS: Silver, copper, gold, aluminium, magnesium, iron, usually metals Insulator: A material that prevents electrons from flowing through it. Plastic, wood and glass are examples. To prevent electric shocks, conductive wires are wrapped in insulators. Semiconductors: Have special properties that make them fair conductors, they are the foundation of modern electronics, including radios, computers and telephones. Charging by Induction (How do we induce a PERMANENT charge?) You can permanently charge an object using induction by attaching a conducting wire to the neutral object that goes to the ground Electric Discharge - What causes it? Know everyday examples. How is lightning formed? When two objects that have a charge imbalance are brought close together or come in contact with each other, electrons are transferred rapidly. Electrons move from the object with a more negative charge to the object with the less negative charge. Lightning occurs through an imbalance of charge between clouds and the ground. Negative charge at the bottom of a cloud repels the electrons at the earth's surface which move away, causing the ground to become positively charged Current Electricity: Refers to the electrons that flow in a controlled way through a conductor Forms of Current Electricity - Alternating Current (AC) vs Direct Current (DC) - How do they differ? AC: Electrons move back and forth, alternating their direction. produced in generating stations and is then distributed over long distances ex. Something plugged into a wall outletThe film begins as a journey to film the largest animal on the planet, the blue whale. But during the journey the filmmakers (journalist Craig Leeson and environmental activist Tanya Streeter) make the shocking discovery of a huge, thick layer of plastic floating in the middle of the Indian Ocean. This prompts them to travel around the world to look at other areas that have been affected. In total, they visited 20 locations around the world during the four years it took them to make the film. The documentary premiered in 2016, and is now on streaming services such as Netflix.Itās very clear that a lot of research went into the film. There are beautiful shots of the seas and marine life. These are contrasted with scenes of polluted cities and dumps full of plastic rubbish. We see how marine species are being killed by all the plastic we are dumping in the ocean. The message about our use of plastic is painfully obvious. But the film doesnāt only present the negative side. In the second half, the filmmakers look at what we can do to reverse the tide of plastic flowing around the world. They present short-term and long-term solutions. These include avoiding plastic containers and āsingle-useā plastic products as much as possible. Reuse your plastic bags and recycle as much as you can. The filmmakers also stress the need for governments to work more on recycling programmers, and look at how technology is developing that can convert plastic into fuel We make a staggering amount of plastic. In terms of plastic bags alone, we use five hundred billion worldwide annually. Over 300 million tons of plastic are produced every year, and at least 8 million of those are dumped into the oceans. The results are disastrous, but it isnāt too late to change. Once youāve seen A Plastic Ocean, youāll realize the time is now and we all have a role to play. The price of electricity has risen (1) ______ over the last year. A) specially | B) obviously | C) significantly | D) remarkably The heavy rain led to floods, (2) ______ a lot of trouble for local farmers. A) causing | B) making | C) resulting | D) affecting I have never seen (3) ______ a beautiful sunset in my entire life! A) as | B) like | C) so | D) such It is very (4) ______ that some people still don't believe in climate change. A) doubtful | B) suspicious | C) worrying | D) uncertain My brother is learning how to (5) ______ a small business. A) adjust | B) run | C) manage | D) direct Can you (6) ______ the person who took your bag? A) inform | B) identify | C) tell | D) know On a daily (7) ______, we should try to use less plastic. A) basis | B) motive | C) cause | D) method Regular exercise and a healthy diet are very (8) ______ for your heart. A) rewarding | B) valuable | C) beneficial | D) productive She was (9) ______ to win the race, so she practiced every single day. A) fixed | B) decided | C) committed | D) determined An (10) ______ student spends about three hours on homework every evening. A) everyday | B) average | C) normal | D) regularMagnets Work! Did you know magnets are all around you? Magnets help you do amazing things! Keep reading! See if you think magnets have surprising uses. Magnets Pull. Look closely and you will see. Magnets can be found on a can opener. The magnet attracts, or pulls, the lid off of a soup can. A push or pull is called a force. There is also a magnet in a refrigerator. It pulls the metal in the door to make a tight seal. Do you know how? A magnet's force pulls objects made of metals called iron and steel. It will not pull other things. It will not pull a wooden pencil or a plastic toy. A magnet does not attract all items. Magnets Have Poles. You have proved, or shown, that magnets can pull some things to it. Why is this true? The two ends of a magnet are its poles. Every magnet has a north pole and a south pole. Have you ever played with trains that have magnets? Sometimes, you try to put two train cars together, but they repel. This means they push away from each other. Then you turn one of the cars around. The two cars snap together as quick as a wink. That's right! If you have played with these trains, you know it is true. When the train cars push away, two of the same poles are facing each other. However, if you put the north and south poles together, they will snap together like the train. Magnets Can Be Powerful. We know that magnets can move objects. But does the heaviness of an object matter? Can magnets move objects that have different weights? Yes, they can. Scientists are using magnets in new ways. People often wish they could travel at a faster speed than a train. There is a new train that uses powerful magnets to travel more quickly. Magnets lift the train above the track and push the train forward. The train appears to be moving as fast as lightning! Scientists have measured these train speeds. They are much faster than the trains we know. Can you imagine what magnets will help us do in the future? 10 Gever Tulley is a computer scientist from California. In 2005, he started a summer programme for children called Tinkering School. The idea was that children can learn important skills for life by building things together. Gever Tulley and his team help the children to think big and create plans for innovative things they want to build. Children have made fantastic things since the school started. They have built a rollercoaster. They have made a rope bridge from plastic shopping bags. They have made tree houses, wooden motorbikes and boats. At Tinkering School, children get all kinds of materials like wood, metal, plastic, nails and ropes. They get lots of real tools too, such as knives, hammers, screwdrivers and power drills. Some children have cut themselves when using a knife, or hurt their fingers when using a hammer. Tinkering School has been around for many years now, but nobody has ever suffered a serious injury in all those years. This is because there are strict health and safety regulations they must follow. The children always learn how to use the tools safely and they must wear the right clothing and protection at all times. Gever Tulley's ideas have worked very well. A lot of children have gone to his summer schools over the years. In 2011, Gever Tulley and a colleague decided to create a 'real' ! school, called Brightworks, in San Francisco. The school is very small-it only has 20 students aged 6 to 13. Brightworks is based on the same principles as Tinkering School. Since it started, Brightworks has been written about a lot. Most of those articles have been very positive. They have praised the quality of the school. They have found the children are more motivated than at many other schools. But since the beginning of the school there have also been critical voices. Some people have said that children are not learning enough at Brightworks. They feel that students and teachers are just 'playing around' all the time. The students at Brightworks seem to love their school. We spoke to 12-year-old Tina Cooper. She has been a student at the school since last October. 'Since I started here, I've never sat in a 'normal' class with a teacher,' she told us. 'But it's been a very exciting experience. I've worked hard at my new school for eight months now, and there hasn't been one single moment when I found it boring. Before, I was bored quite often.'Model Rockets Liftoff! Three... two... one... liftoff! A model rocket shoots into the sky. The rocket can fly up to 1,500 feet (457 m) high! Watching these small rockets fly can be fun and exciting. Model rockets aren't just for fun, though. They also teach us about science and space. The History of Rockets. People in China invented rockets about eight hundred years ago. They filled tubes with gunpowder and shot them at their enemies. Later, scientists built rockets that could go into space. Starting in the 1950s, people began building model rockets for fun. Parts of a Model Rocket. A model rocket kit comes with all the parts a rocket needs. A model rocket's body is a long tube made of cardboard or plastic. The nose cone fits into the top of the tube. The size and shape of a rocket's body and nose cone can change how it flies. Fins help the rocket fly straight. The engine burns fuel to push the rocket into the air. A parachute helps the rocket fall safely back to Earth. People like to make their rockets look great. Many people paint their rockets with different colors and designs. Every rocket is one of a kind! At the Launchpad. The only place to launch a rocket is in an open space. The launch area needs to be far away from people and buildings. A large field or a playground is a good spot. First, set up the launchpad. Place the rocket over the guide wire on the pad. The guide wire keeps the rocket pointing straight up. A girl connects the wire that will allow the controller to start the rocket engine. when it lifts off. Connect the launch controller to the rocket engine. Then step back and press the button on the controller to start the engine. Whoosh! The rocket flies up and away. Clubs and Competitions. People who fly model rockets often join model rocket clubs. Schools or hobby groups can have information about model rocket clubs. A science center or museum might have a model rocket club, too. Many people enter model rocket competitions. They set off rockets and see which one flies the highest and the fastest. Model rocket competitions are held all over the world. In the United States, students between twelve and eighteen can enter the Team America Rocketry Challenge. Every spring, one hundred teams compete to become the best in the country. The winners go on to compete against other teams from around the world. Model rockets are a fun way to learn about science. Who knows how high a model rocket can take your imagination?Inspire Manak Mathematics Project: Teacher: sarasa srinivasa kumar Student: Brundageethika, class 10 AP MODEL SCHOOL, Nandavaram, Marripadu Mandal, Nellore District *Title:* Enhanced Irrigation System for Efficient Water Use in Agriculture *Overview:* This project aims to develop an optimized irrigation system using mathematical principles to efficiently distribute water throughout a farm. By employing geometry, linear programming, and ratios, the system enables farmers to optimize water allocation, enhance crop yield, and reduce water consumption. *Issue Addressed:* Inefficient irrigation methods lead to excessive water consumption and reduced crop productivity. Conventional methods often result in inconsistent water distribution, wasting this precious resource. *Benefits:* - Guarantees efficient water usage, minimizing waste and preserving resources - Potential to reduce water consumption by up to 30% - Enhances crop productivity by ensuring each plant receives the ideal amount of water - Easy to implement and cost-effective for farmers in water-scarce areas - Promotes environmentally responsible agricultural practices - Scalable for various farm sizes and crop types *Required Tools:* 1. *Mathematical Tools:* - Graph paper or software (e.g., GeoGebra) - Calculator or software (e.g., Excel) for linear programming - Ruler and compass for manual layout design 2. *Materials for the Model:* - Cardboard or plywood board for farm layout model - Small containers (e.g., cups, bottles) for simulating water distribution - Plastic tubing or straws for irrigation channels - Clay or soil for crop fields 3. *Water Distribution System:* - Water pump or manual syringe for demonstrating water flow - Small-scale water reservoir (bowl or tank) - Valves or small taps to control water flow 4. *Visualization and Display:* - Markers, pens, and labels for marking crop sections and water flow paths - Charts or posters for showing mathematical calculations and results - Projector or laptop (optional) for digital models 5. *Miscellaneous:* - Adhesive (glue, tape) for assembling the model - Scissors or cutting tools for shaping materials - Measuring tape for accurate model scaling This project has the potential to make a significant impact on agricultural practices, and I'm excited to see how it develops!