'+pages+''); $('.stream > div:odd').addClass('bgr_color'); updateHeight('#history'); }); window.activateTabArea = ensure(function(tab, areas){ var parsed = false; var parts = (areas || '').split('/'); window.fsonload = $.inArray('fs', parts) >= 0; if(fsonload){ parts.splice(parts.indexOf('fs'), 1); } var replayMode = false; if($.inArray('replay', parts)>=0){ replayMode = 'replay'; } var noSoundMode = false; if($.inArray('nosound', parts)>=0){ noSoundMode = 'nosound'; } if($.inArray('ns', parts)>=0){ noSoundMode = 'ns'; } var previewMode = null; if($.inArray('p', parts)>=0){ previewMode = 'p'; } if($.inArray('preview', parts)>=0){ previewMode = 'preview'; } if($.inArray('repeat', parts)>=0){ replayMode = 'repeat'; } if($.inArray('r', parts)>=0 || $.inArray('ro', parts)>=0){ replayMode = 'r'; } if(replayMode){ parts.splice(parts.indexOf(replayMode), 1); } if(noSoundMode){ parts.splice(parts.indexOf(noSoundMode), 1); } if(previewMode){ parts.splice(parts.indexOf(previewMode), 1); } if(previewMode){ if(!parts.length){ parts = ['1-14', '999:59']; } } var area = parts[0]; if(tab == 'history' && false){ var page = parseInt(area || '1') || 1; $.ajax({ url: 'https://login.wn.com/recent/json/?pp='+history_pp+'&skip='+history_pp*(page-1), dataType: 'jsonp', success: function(response){ $ensure(function(){ renderHistory(response, page); }); } }); return true; } if(tab == 'global_history' && false){ var page = parseInt(area || '1') || 1; globalHistory.fetchStream(page, '', function(){ updateHeight('#global_history'); }); return true; } if(tab == 'my_playlists' && false){ var page = parseInt(area || '1') || 1; myPlaylists.fetchStream(page, '', function(){ updateHeight('#my_playlists'); }); return true; } if(tab == 'my_videos' && false){ var page = parseInt(area || '1') || 1; myVideos.fetchStream(page, '', function(){ updateHeight('#my_videos'); }); return true; } if(tab == 'related_sites' && areas && matchPosition(areas)){ var seconds = parsePosition(areas); scrollRelated(seconds); return false; } if(matchPosition(area) || matchAction(area)){ parts.unshift('1'); area = parts[0]; } if(tab == 'expand' && area && area.match(/\d+/)) { var num = parseInt(area); if(num < 100){ //FIX ME. 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var par = el.closest('.playlist_scrollarea'); par.scrollTop(el.offset().top-par.height()/2); } var updateVolumeState = function(){ if(noSoundMode){ if(noSoundMode == 'turn-on'){ clog("Sound is on, vsid="+vp.vsid); vp.setVolumeUnMute(); noSoundMode = false; }else{ clog("Sound is off, vsid="+vp.vsid); vp.setVolumeMute(); noSoundMode = 'turn-on'; } } } var playQueueUpdate = function(){ var playPosition = playQueue[playQueuePosition]; vp.playFromPlaylist(playPosition.video); scrollToPlaylistPosition(vp); playShouldStart = playPosition.start; playShouldStop = playPosition.stop; }; var playQueueAdvancePosition = function(){ clog("Advancing play position..."); playQueuePosition ++; while(playQueuePosition < playQueue.length && !playQueue[playQueuePosition].video){ playQueuePosition ++; } if(playQueuePosition < playQueue.length){ playQueueUpdate(); }else if(vp.getReplayCurrent()){ playQueuePosition = 0; playQueueUpdate(); vp.seekTo(playShouldStart); vp.playVideo(); }else{ vp.pauseVideo(); playShouldStop = null; playShouldStart = null; } }; function loadMoreVideos(playerId, vp, start, finish, callback){ var playlistInfo = playlists[playerId-1]; if(playlistInfo.loading >= finish) return; playlistInfo.loading = finish; $.ajax({ url: '/api/upge/cheetah-photo-search/query_videos2', dataType: 'json', data: { query: playlistInfo.query, orderby: playlistInfo.orderby, start: start, count: finish-start }, success: function(response){ var pl = vp.getPlaylist().slice(0); pl.push.apply(pl, response); vp.setPlaylist(pl); callback(); } }); } if(parts.length == 1 && matchDash(parts[0])){ var pl = vp.getActualPlaylist(); var vids = parseDash(parts[0]); parts = []; for(var i = 0; i < vids.length; i++){ playQueue.push({ 'video': pl[vids[i]-1], 'start': 0, 'stop': null }) } if(vids.length){ if(vids[vids.length-1]-1>=pl.length){ loadMoreVideos(playerId, vp, pl.length, vids[vids.length-1], function(){ if(fsonload){ activateTabArea(tab, parts[0]+'/fs'); }else{ activateTabArea(tab, parts[0]); } var pls = vp.getPlaylist(); vp.playFromPlaylist(pls[pls.length-1]); vp.playVideo(); scrollToPlaylistPosition(vp); }); return true; } } if(playQueue){ playQueueUpdate(); vp.playVideo(); parsed = true; playShouldStart = 0; } } if(previewMode){ var vids = []; var dur = 0; var pl = vp.getActualPlaylist(); area = parts[0]; if(parts.length == 1 && matchPosition(parts[0])){ vids = parseDash('1-'+pl.length); dur = parsePosition(parts[0]); parts = []; }else if(parts.length == 1 && matchDash(parts[0])){ vids = parseDash(parts[0]); dur = parsePosition("999:59"); parts = []; } if(parts.length == 2 && matchDash(parts[0]) && matchPosition(parts[1])){ vids = parseDash(parts[0]); dur = parsePosition(parts[1]); parts = []; } for(var i = 0; i < vids.length; i++){ playQueue.push({ 'video': pl[vids[i]-1], 'start': 0, 'stop': dur }) } if(playQueue){ playQueueUpdate(); vp.playVideo(); parsed = true; } } if(parts.length>1){ for(var i = 0; i < parts.length; i++){ var sel = findMatchingVideo(vp, parts[i]); if(sel){ playQueue.push({ 'video': sel, 'start': 0, 'stop': null }) } } if(playQueue){ playQueueUpdate(); 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if(window.history && history.replaceState && document.location.hostname.match(/^(youtube\.)?(\w{2,3}\.)?wn\.com$/)){ if(path == main_tab || path == main_tab+'/' || path == '' || path == '/') { path = basepath; } else if( path.match('^'+main_tab+'/') ){ path = basepath + '/' + path.replace(main_tab+'/', '').replace('--','/'); } else { path = basepath + '/' + path.replace('--','/'); } if(document.location.search){ path += document.location.search; } if(window.lastHistory) { history.pushState(null, null, path); } else if(window.lastHistory != path){ history.replaceState(null, null, path); window.lastHistory = path; } } else{ path = path.replace('--','/'); if(path == main_tab || path == main_tab+'/' || path == '' || path == '/') { path = ''; } if(window.lastHistory != '/'+path){ window.location.hash = path? '/'+path : ''; window.lastHistory = '/'+path; } } }); $('.tabtrigger li a').live('click', ensure(function() { var tab = $(this).attr('id'); if(tab.substring(0,1) == '#'){ var name = tab.substring(1); if(name in menu_names){ name = menu_names[name][0]; } realTab = rev_names[name]; $('#'+realTab).show(); if(window.console && console.log) console.log("Triggering tab: "+name+(window.activeArea?" activeArea="+window.activeArea:'')); var path = name; if(window.activeArea){ path = path + '/' + window.activeArea; } if(tab.match(/#playlist\d+/) || tab.match(/#details\d+/)){ $('.multiple-playlists').show(); $('.related_playlist').show(); $('.longest_videos_playlist').show(); }else { $('.multiple-playlists').hide(); $('.related_playlist').hide(); $('.longest_videos_playlist').hide(); } // start the related script only when the tab is on screen showing if (tab.match(/related_sites/)) { if (mc) { mc.startCredits(); } } window.activeTab = realTab; addHistory(path); setTimeout(ensure(function(){ if(tab.match(/language--/)){ $('.tabtrigger').offscreentabs('activateTab', 'language'); } if(tab.match(/weather/)) { $('.tabtrigger').offscreentabs('activateTab', 'weather'); loadContinent(); } updateMenus(tab); updateHeight(); }), 10); } return false; })); }); -->

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  Thermal Energy

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  Thermal Energy

• Thermal energy

Thermal energy

In thermodynamics, thermal energy refers to the internal energy present in a system by virtue of its temperature. The average translational kinetic energy possessed by free particles in a system of free particles in thermodynamic equilibrium (as measured in the frame of reference of the center of mass of that system) may also be referred to as the thermal energy per particle.

Microscopically, the thermal energy may include both the kinetic energy and potential energy of a system's constituent particles, which may be atoms, molecules, electrons, or particles. It originates from the individually random, or disordered, motion of particles in a large ensemble. In ideal monatomic gases, thermal energy is entirely kinetic energy. In other substances, in cases where some of the thermal energy is stored in atomic vibration or by increased separation of particles having mutual forces of attraction, the thermal energy is equally partitioned between potential energy and kinetic energy. Thermal energy is thus equally partitioned between all available degrees of freedom of the particles. As noted, these degrees of freedom may include pure translational motion in gases, rotational motion, vibrational motion and associated potential energies. In general, due to quantum mechanical reasons, the availability of any such degrees of freedom is a function of the energy in the system, and therefore depends on the temperature (see heat capacity for discussion of this phenomenon).

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This page contains text from Wikipedia, the Free Encyclopedia - https://wn.com/Thermal_energy

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  Lighthouse Lab - Thermal Energy

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  Thermal Energy | Heat and Temperature

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4:55

Lighthouse Lab - Thermal Energy

• Order: Reorder
• Duration: 4:55
• Uploaded Date: 27 Jul 2022
• views: 72829

#lhl #lighthouselab #thermalenergy #heat Thermal energy is the energy that comes from the temperature of an object. The higher the temperature of an object, th...

#lhl #lighthouselab #thermalenergy #heat Thermal energy is the energy that comes from the temperature of an object. The higher the temperature of an object, the more thermal energy it has. Thermal energy can be used to do work, such as powering a machine, or it can be converted into other forms of energy, such as electricity, or heat. Welcome back to the Lighthouse Lab! Today, I want to talk to you about a type of energy called thermal energy and how it moves and how it affects the temperature of an object. You may recall that all matter is made up of tiny particles. Whether matter is in a solid, liquid or gas, these particles are always in motion. How much these particles move is called thermal energy and the more thermal energy an object has, higher its temperature. Check out these three beakers of water. There is iced-water in Beaker A, warm tap water in Beaker B and hot water from a kettle in Beaker C. We can use a thermometer to measure the temperature of the water in each beaker. The water in Beaker A is 4 degrees celsius. The water in Beaker B is 25 degrees celsius. It contains more thermal energy than the water in Beaker A. The water in Beaker C is 60 degrees celsius. It is the hottest and contains the most thermal energy. OK, so the more thermal energy an object has, the faster its particles are moving and the hotter it is. So when an object is heated, it gains thermal energy. In fact, the movement of thermal energy within an object is called heat and in matter heat always moves the same way. It moves from hot to cold. Let me show you an example. Here we've got a metal rod attached to a retort stand. I'm going to heat the metal rod on this end using a burner. To observe how heat moves, I'm going to attach 3 candles to the metal rod. Great! Before I start....make a prediction. Which candle will melt and fall away first? Which one will be the last to fall? OK....let's find out! I knew it! Thermal energy is moving from hot to cold. Its moving along the metal rod from here to here....and if that's the case then...yes! Just as I thought...and of course, there goes the last one. So there you have it...when an object is heated, it gains thermal energy and its temperature increases and thermal energy moves in the direction of hot to cold. Thanks for learning and I'll see you again soon in the Lighthouse Lab! This video lesson is produced by Blue Ring Media in association with NGScience.com – a world-class online learning resource for K-6 science. Our international curriculum covers a comprehensive range of topics and concepts to help enhance the teaching and learning of science in your classroom and at home. Create a free account today! https://ngscience.com https://www.facebook.com/ngscienceK6 https://www.pinterest.com.au/ngscienceK6/ https://www.youtube.com/c/NGScience The Lighthouse Lab is produced by Blue Ring Media on the Gold Coast, Australia. For media enquiries, please email us at [email protected]

https://wn.com/Lighthouse_Lab_Thermal_Energy

#lhl #lighthouselab #thermalenergy #heat Thermal energy is the energy that comes from the temperature of an object. The higher the temperature of an object, the more thermal energy it has. Thermal energy can be used to do work, such as powering a machine, or it can be converted into other forms of energy, such as electricity, or heat. Welcome back to the Lighthouse Lab! Today, I want to talk to you about a type of energy called thermal energy and how it moves and how it affects the temperature of an object. You may recall that all matter is made up of tiny particles. Whether matter is in a solid, liquid or gas, these particles are always in motion. How much these particles move is called thermal energy and the more thermal energy an object has, higher its temperature. Check out these three beakers of water. There is iced-water in Beaker A, warm tap water in Beaker B and hot water from a kettle in Beaker C. We can use a thermometer to measure the temperature of the water in each beaker. The water in Beaker A is 4 degrees celsius. The water in Beaker B is 25 degrees celsius. It contains more thermal energy than the water in Beaker A. The water in Beaker C is 60 degrees celsius. It is the hottest and contains the most thermal energy. OK, so the more thermal energy an object has, the faster its particles are moving and the hotter it is. So when an object is heated, it gains thermal energy. In fact, the movement of thermal energy within an object is called heat and in matter heat always moves the same way. It moves from hot to cold. Let me show you an example. Here we've got a metal rod attached to a retort stand. I'm going to heat the metal rod on this end using a burner. To observe how heat moves, I'm going to attach 3 candles to the metal rod. Great! Before I start....make a prediction. Which candle will melt and fall away first? Which one will be the last to fall? OK....let's find out! I knew it! Thermal energy is moving from hot to cold. Its moving along the metal rod from here to here....and if that's the case then...yes! Just as I thought...and of course, there goes the last one. So there you have it...when an object is heated, it gains thermal energy and its temperature increases and thermal energy moves in the direction of hot to cold. Thanks for learning and I'll see you again soon in the Lighthouse Lab! This video lesson is produced by Blue Ring Media in association with NGScience.com – a world-class online learning resource for K-6 science. Our international curriculum covers a comprehensive range of topics and concepts to help enhance the teaching and learning of science in your classroom and at home. Create a free account today! https://ngscience.com https://www.facebook.com/ngscienceK6 https://www.pinterest.com.au/ngscienceK6/ https://www.youtube.com/c/NGScience The Lighthouse Lab is produced by Blue Ring Media on the Gold Coast, Australia. For media enquiries, please email us at [email protected]

• published: 27 Jul 2022
• views: 72829

6:38

Thermal Energy vs Temperature

• Order: Reorder
• Duration: 6:38
• Uploaded Date: 25 Jul 2018
• views: 258513

Which has more energy – an ice berg or a cup of coffee? While this may seem to be a very simple question, the answer is surprise to most people.

Which has more energy – an ice berg or a cup of coffee? While this may seem to be a very simple question, the answer is surprise to most people.

https://wn.com/Thermal_Energy_Vs_Temperature

Which has more energy – an ice berg or a cup of coffee? While this may seem to be a very simple question, the answer is surprise to most people.

• published: 25 Jul 2018
• views: 258513

4:12

Thermal Energy

• Order: Reorder
• Duration: 4:12
• Uploaded Date: 01 May 2020
• views: 23936

Mount Everest is the tallest peak and has one of the harshest climates in the world, and the climbers trying to reach its summit must rely on thermal energy to ...

Mount Everest is the tallest peak and has one of the harshest climates in the world, and the climbers trying to reach its summit must rely on thermal energy to keep them alive. This grade 6-8 science story is produced by NBC Learn in partnership with Pearson.

https://wn.com/Thermal_Energy

Mount Everest is the tallest peak and has one of the harshest climates in the world, and the climbers trying to reach its summit must rely on thermal energy to keep them alive. This grade 6-8 science story is produced by NBC Learn in partnership with Pearson.

• published: 01 May 2020
• views: 23936

7:07

Thermal Energy | Heat and Temperature

• Order: Reorder
• Duration: 7:07
• Uploaded Date: 15 Jun 2020
• views: 195035

In this whiteboard animations tutorial, I will teach you thermal energy, heat and temperature. Q: What is thermal energy? Ans: The energy possessed by an obje...

In this whiteboard animations tutorial, I will teach you thermal energy, heat and temperature. Q: What is thermal energy? Ans: The energy possessed by an object due to the movement of particles within the system is called thermal energy. For example, consider a closed gas cylinder. The particles of the gas are in constant random motion; hence they possess thermal energy. Remember that thermal energy directly depends on the kinetic energy of particles. If the kinetic energy of the particles are high, thermal energy will also be high, and temperature of the system will increase. As a result, such a system or body will be hot. To learn more, watch this animated lecture till the end. #ThermalEnergy #Heat #Temperature #physics Subscribe my channel at:https://www.youtube.com/channel/UC_ltCdLVMRZ7r3IPzF2Toyg Youtube link: https://www.youtube.com/channel/UC_ltCdLVMRZ7r3IPzF2Toyg Facebook link: https://www.facebook.com/Najamacademy/

https://wn.com/Thermal_Energy_|_Heat_And_Temperature

In this whiteboard animations tutorial, I will teach you thermal energy, heat and temperature. Q: What is thermal energy? Ans: The energy possessed by an object due to the movement of particles within the system is called thermal energy. For example, consider a closed gas cylinder. The particles of the gas are in constant random motion; hence they possess thermal energy. Remember that thermal energy directly depends on the kinetic energy of particles. If the kinetic energy of the particles are high, thermal energy will also be high, and temperature of the system will increase. As a result, such a system or body will be hot. To learn more, watch this animated lecture till the end. #ThermalEnergy #Heat #Temperature #physics Subscribe my channel at:https://www.youtube.com/channel/UC_ltCdLVMRZ7r3IPzF2Toyg Youtube link: https://www.youtube.com/channel/UC_ltCdLVMRZ7r3IPzF2Toyg Facebook link: https://www.facebook.com/Najamacademy/

• published: 15 Jun 2020
• views: 195035

3:15

Heat Transfer – Conduction, Convection and Radiation

• Order: Reorder
• Duration: 3:15
• Uploaded Date: 04 Mar 2022
• views: 573141

#heat #energy #conduction #ngscience https://ngscience.com Observe and learn about the different ways in which heat moves. Get too ngscience.com for a range of ...

#heat #energy #conduction #ngscience https://ngscience.com Observe and learn about the different ways in which heat moves. Get too ngscience.com for a range of related learning and teaching resources for use in the classroom and at home. What Is Thermal Energy? All matter is made up of tiny particles. Whether matter is in a solid, liquid or gas, these particles are always in motion. How much these particles move is called thermal energy. The more thermal energy matter has, the higher its temperature. Temperature is how hot or cold matter is. It is a measure of the average kinetic energy of the particles in matter. The faster the particles mover, the greater the temperature. When matter gains thermal energy, the particles that make up the matter move faster. Its thermal energy increases and its temperature also increases. When matter loses thermal energy, the particles that make up the matter move slower. Its thermal energy decreases and its temperature decreases. So how does matter gain thermal energy? The movement of thermal energy is called heat. Heat occurs whenever there is difference in temperature. Let’s look at an example of the heat that occurs when a hot object comes in contact with a cold object. In both objects, the particles are moving – they have kinetic energy. When the objects are touching, their particles collide with each other. As they collide, the hot object passes energy to the cold object. The hot object gets cooler and the cold object gets warmer. Heat will continue to move in this way until the temperature of both objects is equal. When you place a cold metal spoon into a hot cup of tea, energy moves from the hot tea to the spoon. The tea loses thermal energy and gets cooler. The spoon gains thermal energy and gets hotter. The metal spoon will continue to gain thermal energy from the hot tea until the temperature of the tea and the spoon are equal. Just as heat moves from hot to cold between objects, it also moves in this way within objects. Let’s look at an example of placing a metal rod over a fire. The heat from the fire will cause the particles at the tip of the rod to gain thermal energy and its temperature increases. These particles then collide with the particles adjacent to them. In this way, heat in transferred from the hot region to the cold region of the metal rod. Thermal energy moves in three main ways – conduction, convection and radiation. Think again how heat moved in the metal rod placed on a fire. The thermal energy moved from the hot part of the rod to the cooler part of the rod. This movement of heat within an object is called conduction. Conduction also occurs when objects are touching. If you were to hold the cool end of the rod, before too long it would feel warm as thermal energy moves by conduction to your hand. Heat transfer from a hot cup to your hands and cooking a piece of fish in a pan are also examples of conduction. Liquids and gases are similar in that they have no fixed shape. They are fluids. Thermal energy can be transferred from one region of a fluid to another due to movements within the fluid. This movement of thermal energy, called convection, is caused by hot parts of the fluid rising and the cooler parts of the fluid sinking. Think about the water in a kettle as it is heated. The water touching the heating element is heated by conduction. The water becomes warm and rises. As it does so, the cooler water sinks and a current is created within the water. The current causes the thermal energy to spread through the water in the kettle. The heating of air in a hot air balloon is also an example of convection. For thermal energy to move by conduction and convection it must travel through matter. Between the Sun and the Earth is empty space. How does the heat from the Sun warm the Earth and other planets in the solar system? The answer is radiation. Radiation is the transfer of energy through electromagnetic waves. The warmth you feel when you place your hand near an electric heater or a campfire are examples of heat in the form of radiation.

https://wn.com/Heat_Transfer_–_Conduction,_Convection_And_Radiation

#heat #energy #conduction #ngscience https://ngscience.com Observe and learn about the different ways in which heat moves. Get too ngscience.com for a range of related learning and teaching resources for use in the classroom and at home. What Is Thermal Energy? All matter is made up of tiny particles. Whether matter is in a solid, liquid or gas, these particles are always in motion. How much these particles move is called thermal energy. The more thermal energy matter has, the higher its temperature. Temperature is how hot or cold matter is. It is a measure of the average kinetic energy of the particles in matter. The faster the particles mover, the greater the temperature. When matter gains thermal energy, the particles that make up the matter move faster. Its thermal energy increases and its temperature also increases. When matter loses thermal energy, the particles that make up the matter move slower. Its thermal energy decreases and its temperature decreases. So how does matter gain thermal energy? The movement of thermal energy is called heat. Heat occurs whenever there is difference in temperature. Let’s look at an example of the heat that occurs when a hot object comes in contact with a cold object. In both objects, the particles are moving – they have kinetic energy. When the objects are touching, their particles collide with each other. As they collide, the hot object passes energy to the cold object. The hot object gets cooler and the cold object gets warmer. Heat will continue to move in this way until the temperature of both objects is equal. When you place a cold metal spoon into a hot cup of tea, energy moves from the hot tea to the spoon. The tea loses thermal energy and gets cooler. The spoon gains thermal energy and gets hotter. The metal spoon will continue to gain thermal energy from the hot tea until the temperature of the tea and the spoon are equal. Just as heat moves from hot to cold between objects, it also moves in this way within objects. Let’s look at an example of placing a metal rod over a fire. The heat from the fire will cause the particles at the tip of the rod to gain thermal energy and its temperature increases. These particles then collide with the particles adjacent to them. In this way, heat in transferred from the hot region to the cold region of the metal rod. Thermal energy moves in three main ways – conduction, convection and radiation. Think again how heat moved in the metal rod placed on a fire. The thermal energy moved from the hot part of the rod to the cooler part of the rod. This movement of heat within an object is called conduction. Conduction also occurs when objects are touching. If you were to hold the cool end of the rod, before too long it would feel warm as thermal energy moves by conduction to your hand. Heat transfer from a hot cup to your hands and cooking a piece of fish in a pan are also examples of conduction. Liquids and gases are similar in that they have no fixed shape. They are fluids. Thermal energy can be transferred from one region of a fluid to another due to movements within the fluid. This movement of thermal energy, called convection, is caused by hot parts of the fluid rising and the cooler parts of the fluid sinking. Think about the water in a kettle as it is heated. The water touching the heating element is heated by conduction. The water becomes warm and rises. As it does so, the cooler water sinks and a current is created within the water. The current causes the thermal energy to spread through the water in the kettle. The heating of air in a hot air balloon is also an example of convection. For thermal energy to move by conduction and convection it must travel through matter. Between the Sun and the Earth is empty space. How does the heat from the Sun warm the Earth and other planets in the solar system? The answer is radiation. Radiation is the transfer of energy through electromagnetic waves. The warmth you feel when you place your hand near an electric heater or a campfire are examples of heat in the form of radiation.

• published: 04 Mar 2022
• views: 573141

5:45

GCSE Physics - Conduction, Convection and Radiation #5

• Order: Reorder
• Duration: 5:45
• Uploaded Date: 25 Jun 2019
• views: 1248150

In this video we cover: - The 3 ways heat energy can be transferred - How heat is conducted through solids - What thermal conductivity means - How convection...

In this video we cover: - The 3 ways heat energy can be transferred - How heat is conducted through solids - What thermal conductivity means - How convection cycles work - What radiation is General info: - Even if you don’t need to know the details for your course, it's worth watching to understand the concepts Exam board specific info: AQA - Everything is relevant to your course! IGCSE Edexcel - Everything is relevant to your course! Edexcel - You do not need to know conduction or convection in detail, so you can skip to 4:45 OCR 21st Century - You do not need to know conduction or convection in detail, so you can skip to 4:45 OCR Gateway - Everything is relevant to your course!

https://wn.com/Gcse_Physics_Conduction,_Convection_And_Radiation_5

In this video we cover: - The 3 ways heat energy can be transferred - How heat is conducted through solids - What thermal conductivity means - How convection cycles work - What radiation is General info: - Even if you don’t need to know the details for your course, it's worth watching to understand the concepts Exam board specific info: AQA - Everything is relevant to your course! IGCSE Edexcel - Everything is relevant to your course! Edexcel - You do not need to know conduction or convection in detail, so you can skip to 4:45 OCR 21st Century - You do not need to know conduction or convection in detail, so you can skip to 4:45 OCR Gateway - Everything is relevant to your course!

• published: 25 Jun 2019
• views: 1248150

3:51

How Heat Energy Shapes Our World

• Order: Reorder
• Duration: 3:51
• Uploaded Date: 31 May 2023
• views: 14323

#heatenergy #ngscience @NGScience Heat energy is one of the most crucial types of energy for life on Earth, and it's all around us. In this video, we'll take a...

#heatenergy #ngscience @NGScience Heat energy is one of the most crucial types of energy for life on Earth, and it's all around us. In this video, we'll take a look at where heat energy comes from and the variety of ways we use heat energy in our everyday lives. Let's begin with the Sun. That gigantic, shining ball of fiery gases in the sky, is the Earth's main source of heat energy. It's like a giant heating system for our planet. The Sun's heat travels millions of miles through space and reaches us here on Earth. It keeps us and all other living things warm. Without the Sun's heat, Earth would be a cold and lifeless planet. Every day, humans use heat energy in numerous ways. It's an essential part of our daily lives. Here are a few examples: Drying Clothes and Food: Have you ever hung a wet piece of clothing outside on a sunny day? The heat energy from the Sun helps to evaporate the water from your clothes, drying them out. Similarly, people dry fruits, vegetables, and other foods in the Sun. This is a method of preserving food so that we can eat it later. Cooking: We use heat energy every day for cooking food. When we turn on a stove or an oven, it generates heat. This heat cooks our food, making it safe and tasty to eat. Whether you're baking a cake, grilling a burger or roasting marshmallows on a campfire, you're using heat energy. Ironing Clothes: When your clothes are wrinkled, you can use an iron to make them smooth. The iron converts electrical energy into heat energy. The heat from the iron relaxes the fibers in your clothes, eliminating wrinkles and making them look and feel good too! Melting and Processing Metals: Heat is also used in industries, particularly in the processing of metals. For example, blacksmiths heat metal until it's so hot it becomes soft and malleable. They can then shape it into useful items like horseshoes, tools, and more. In factories, metals are heated to extreme temperatures to melt them down. They are then poured into molds to create all sorts of objects, from car parts to cutlery. Warmth in Our Homes: Lastly, but certainly not least, we use heat energy to make our homes warm and comfortable. On a frosty winter's day, we might turn on a heater, or kindle a fire in a fireplace. This heat radiates throughout our homes, creating a snug and cozy atmosphere. Beyond heating our living spaces, heat energy also plays a crucial role in warming our water. Ever wondered how your shower or bath water becomes so delightfully warm? This is achieved with the help of water heaters that use heat energy to raise the temperature of cold water. Once heated, this water can be used in multiple ways throughout our homes, from aiding in the cleanliness of our dishes and clothes to providing a relaxing soak in the tub. It's amazing how much we rely on heat energy in our daily lives. From the Sun's warmth that supports all life on Earth, to the many ways we use heat in our homes and industries, heat energy is indeed an integral part of our lives.

https://wn.com/How_Heat_Energy_Shapes_Our_World

#heatenergy #ngscience @NGScience Heat energy is one of the most crucial types of energy for life on Earth, and it's all around us. In this video, we'll take a look at where heat energy comes from and the variety of ways we use heat energy in our everyday lives. Let's begin with the Sun. That gigantic, shining ball of fiery gases in the sky, is the Earth's main source of heat energy. It's like a giant heating system for our planet. The Sun's heat travels millions of miles through space and reaches us here on Earth. It keeps us and all other living things warm. Without the Sun's heat, Earth would be a cold and lifeless planet. Every day, humans use heat energy in numerous ways. It's an essential part of our daily lives. Here are a few examples: Drying Clothes and Food: Have you ever hung a wet piece of clothing outside on a sunny day? The heat energy from the Sun helps to evaporate the water from your clothes, drying them out. Similarly, people dry fruits, vegetables, and other foods in the Sun. This is a method of preserving food so that we can eat it later. Cooking: We use heat energy every day for cooking food. When we turn on a stove or an oven, it generates heat. This heat cooks our food, making it safe and tasty to eat. Whether you're baking a cake, grilling a burger or roasting marshmallows on a campfire, you're using heat energy. Ironing Clothes: When your clothes are wrinkled, you can use an iron to make them smooth. The iron converts electrical energy into heat energy. The heat from the iron relaxes the fibers in your clothes, eliminating wrinkles and making them look and feel good too! Melting and Processing Metals: Heat is also used in industries, particularly in the processing of metals. For example, blacksmiths heat metal until it's so hot it becomes soft and malleable. They can then shape it into useful items like horseshoes, tools, and more. In factories, metals are heated to extreme temperatures to melt them down. They are then poured into molds to create all sorts of objects, from car parts to cutlery. Warmth in Our Homes: Lastly, but certainly not least, we use heat energy to make our homes warm and comfortable. On a frosty winter's day, we might turn on a heater, or kindle a fire in a fireplace. This heat radiates throughout our homes, creating a snug and cozy atmosphere. Beyond heating our living spaces, heat energy also plays a crucial role in warming our water. Ever wondered how your shower or bath water becomes so delightfully warm? This is achieved with the help of water heaters that use heat energy to raise the temperature of cold water. Once heated, this water can be used in multiple ways throughout our homes, from aiding in the cleanliness of our dishes and clothes to providing a relaxing soak in the tub. It's amazing how much we rely on heat energy in our daily lives. From the Sun's warmth that supports all life on Earth, to the many ways we use heat in our homes and industries, heat energy is indeed an integral part of our lives.

• published: 31 May 2023
• views: 14323

5:17

Heat Temperature and Thermal Energy

• Order: Reorder
• Duration: 5:17
• Uploaded Date: 11 Aug 2017
• views: 281211

Hi! Welcome to Likeable Science. As the name probably tells you, the purpose of this channel is to make science likeable! Using humor, visual learning, time-lap...

Hi! Welcome to Likeable Science. As the name probably tells you, the purpose of this channel is to make science likeable! Using humor, visual learning, time-lapse, raps, and songs, Likeable Science videos are based on a middle/high school curriculum, and help you to learn quickly in a fun and interesting way! If you like science, check out Likeable STEM (science, technology, engineering, math) at our website: https://www.likeableSTEM.com Likeable STEM includes this channel and others like Likeable Computing to teach all about computer science. Visit the Likeable STEM website for volunteering opportunities, chances to write in our blog, and for more learning opportunities! Dang! Is it hot in here, or is it just me? Today's topic is HEAT, and we're answering the question you've all probably asked at least once in your life: what IS heat? Tune in for a super LIT video about what heat is and how it can be transferred! Peace out! :)

https://wn.com/Heat_Temperature_And_Thermal_Energy

Hi! Welcome to Likeable Science. As the name probably tells you, the purpose of this channel is to make science likeable! Using humor, visual learning, time-lapse, raps, and songs, Likeable Science videos are based on a middle/high school curriculum, and help you to learn quickly in a fun and interesting way! If you like science, check out Likeable STEM (science, technology, engineering, math) at our website: https://www.likeableSTEM.com Likeable STEM includes this channel and others like Likeable Computing to teach all about computer science. Visit the Likeable STEM website for volunteering opportunities, chances to write in our blog, and for more learning opportunities! Dang! Is it hot in here, or is it just me? Today's topic is HEAT, and we're answering the question you've all probably asked at least once in your life: what IS heat? Tune in for a super LIT video about what heat is and how it can be transferred! Peace out! :)

• published: 11 Aug 2017
• views: 281211

28:43

Physics 2 - 5.1 Heat and Temperature

• Order: Reorder
• Duration: 28:43
• Uploaded Date: 05 Jan 2024
• views: 60

🔥 Embark on a lesson on thermodynamics with TraskClass! 🌡️ In this comprehensive physics tutorial, we'll delve into the fundamental concepts of heat, temperatur...

🔥 Embark on a lesson on thermodynamics with TraskClass! 🌡️ In this comprehensive physics tutorial, we'll delve into the fundamental concepts of heat, temperature, and heat transfer, deciphering their roles in understanding the dynamics of thermal energy. 📈🔍 🔍 Key Concepts Explored: Temperature Scales: Understand various temperature scales and their significance in measuring thermal states. Difference between Temperature, Thermal Energy, and Heat: Explore the distinctions among temperature, thermal energy, and heat, unraveling their interrelation in thermal systems. Heat Transfer Mechanisms: Dive into the mechanisms of heat transfer, encompassing conduction, convection, and radiation, and understand their distinct roles in transferring thermal energy. Specific Heat Capacity and Thermal Conductivity: Explore specific heat capacity as a property of materials and thermal conductivity's role in heat transfer efficiency. 🔬 Detailed Explanations & Practical Insights: Gain a comprehensive understanding through detailed explanations, and practical examples on the concepts of heat, temperature, and heat transfer mechanisms. 📊 Applications in Real Life: Discover how these concepts manifest in everyday scenarios, from household applications to industrial processes. 📝 Supplementary Materials Available: Access additional resources, quizzes, and exercises related to thermodynamics, heat, and temperature on traskclass.thinkific.com, enhancing your grasp of these fundamental concepts. 🗣️ Engage & Share Insights: Join the discussion! Share your thoughts, questions, or experiences related to thermodynamics and heat transfer in the comments section. Let's delve deeper into thermal energy dynamics! 💬🔥 🔔 Stay Informed: Hit the subscribe button and enable notifications to stay updated on our comprehensive tutorials unraveling the complexities of thermodynamics and heat dynamics! 🛎️ 📧 Connect with Us at [email protected]: Have inquiries or seeking further information? Reach out to us for discussions or inquiries about thermodynamics and related topics. 🚀 Explore the profound principles of thermodynamics, heat, temperature, and heat transfer, empowering you to decipher the fundamental laws governing thermal dynamics and energy transfer! 🌡️🔍

https://wn.com/Physics_2_5.1_Heat_And_Temperature

🔥 Embark on a lesson on thermodynamics with TraskClass! 🌡️ In this comprehensive physics tutorial, we'll delve into the fundamental concepts of heat, temperature, and heat transfer, deciphering their roles in understanding the dynamics of thermal energy. 📈🔍 🔍 Key Concepts Explored: Temperature Scales: Understand various temperature scales and their significance in measuring thermal states. Difference between Temperature, Thermal Energy, and Heat: Explore the distinctions among temperature, thermal energy, and heat, unraveling their interrelation in thermal systems. Heat Transfer Mechanisms: Dive into the mechanisms of heat transfer, encompassing conduction, convection, and radiation, and understand their distinct roles in transferring thermal energy. Specific Heat Capacity and Thermal Conductivity: Explore specific heat capacity as a property of materials and thermal conductivity's role in heat transfer efficiency. 🔬 Detailed Explanations & Practical Insights: Gain a comprehensive understanding through detailed explanations, and practical examples on the concepts of heat, temperature, and heat transfer mechanisms. 📊 Applications in Real Life: Discover how these concepts manifest in everyday scenarios, from household applications to industrial processes. 📝 Supplementary Materials Available: Access additional resources, quizzes, and exercises related to thermodynamics, heat, and temperature on traskclass.thinkific.com, enhancing your grasp of these fundamental concepts. 🗣️ Engage & Share Insights: Join the discussion! Share your thoughts, questions, or experiences related to thermodynamics and heat transfer in the comments section. Let's delve deeper into thermal energy dynamics! 💬🔥 🔔 Stay Informed: Hit the subscribe button and enable notifications to stay updated on our comprehensive tutorials unraveling the complexities of thermodynamics and heat dynamics! 🛎️ 📧 Connect with Us at [email protected]: Have inquiries or seeking further information? Reach out to us for discussions or inquiries about thermodynamics and related topics. 🚀 Explore the profound principles of thermodynamics, heat, temperature, and heat transfer, empowering you to decipher the fundamental laws governing thermal dynamics and energy transfer! 🌡️🔍

• published: 05 Jan 2024
• views: 60

7:03

How does a Thermal power plant work?

• Order: Reorder
• Duration: 7:03
• Uploaded Date: 26 Jan 2016
• views: 6946007

Help us to make future videos for you. Make LE's efforts sustainable. Please support us at Patreon.com ! https://www.patreon.com/LearnEngineering The operati...

Help us to make future videos for you. Make LE's efforts sustainable. Please support us at Patreon.com ! https://www.patreon.com/LearnEngineering The operation of a thermal power plant is explained in a logical manner with help of animation in this video. Starting from the very basic question a conceptual overview of Rankine cycle is provided here. Topics such a Generator, Steam turbine, condenser, feed water pump, boiler are illustrated initially. The basic Rankine cycle is modified and use of super hearing, reheating and feed water heating (deaerator) is explained there after. Like us on Facebook : https://www.facebook.com/LearnEngineering Voice-over artist :https://www.fiverr.com/mikepaine

https://wn.com/How_Does_A_Thermal_Power_Plant_Work

Help us to make future videos for you. Make LE's efforts sustainable. Please support us at Patreon.com ! https://www.patreon.com/LearnEngineering The operation of a thermal power plant is explained in a logical manner with help of animation in this video. Starting from the very basic question a conceptual overview of Rankine cycle is provided here. Topics such a Generator, Steam turbine, condenser, feed water pump, boiler are illustrated initially. The basic Rankine cycle is modified and use of super hearing, reheating and feed water heating (deaerator) is explained there after. Like us on Facebook : https://www.facebook.com/LearnEngineering Voice-over artist :https://www.fiverr.com/mikepaine

• published: 26 Jan 2016
• views: 6946007

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4:55

Lighthouse Lab - Thermal Energy

#lhl #lighthouselab #thermalenergy #heat Thermal energy is the energy that comes from the...

published: 27 Jul 2022

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Lighthouse Lab - Thermal Energy

Lighthouse Lab - Thermal Energy

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• published: 27 Jul 2022
• views: 72829

#lhl #lighthouselab #thermalenergy #heat Thermal energy is the energy that comes from the temperature of an object. The higher the temperature of an object, the more thermal energy it has. Thermal energy can be used to do work, such as powering a machine, or it can be converted into other forms of energy, such as electricity, or heat. Welcome back to the Lighthouse Lab! Today, I want to talk to you about a type of energy called thermal energy and how it moves and how it affects the temperature of an object. You may recall that all matter is made up of tiny particles. Whether matter is in a solid, liquid or gas, these particles are always in motion. How much these particles move is called thermal energy and the more thermal energy an object has, higher its temperature. Check out these three beakers of water. There is iced-water in Beaker A, warm tap water in Beaker B and hot water from a kettle in Beaker C. We can use a thermometer to measure the temperature of the water in each beaker. The water in Beaker A is 4 degrees celsius. The water in Beaker B is 25 degrees celsius. It contains more thermal energy than the water in Beaker A. The water in Beaker C is 60 degrees celsius. It is the hottest and contains the most thermal energy. OK, so the more thermal energy an object has, the faster its particles are moving and the hotter it is. So when an object is heated, it gains thermal energy. In fact, the movement of thermal energy within an object is called heat and in matter heat always moves the same way. It moves from hot to cold. Let me show you an example. Here we've got a metal rod attached to a retort stand. I'm going to heat the metal rod on this end using a burner. To observe how heat moves, I'm going to attach 3 candles to the metal rod. Great! Before I start....make a prediction. Which candle will melt and fall away first? Which one will be the last to fall? OK....let's find out! I knew it! Thermal energy is moving from hot to cold. Its moving along the metal rod from here to here....and if that's the case then...yes! Just as I thought...and of course, there goes the last one. So there you have it...when an object is heated, it gains thermal energy and its temperature increases and thermal energy moves in the direction of hot to cold. Thanks for learning and I'll see you again soon in the Lighthouse Lab! This video lesson is produced by Blue Ring Media in association with NGScience.com – a world-class online learning resource for K-6 science. Our international curriculum covers a comprehensive range of topics and concepts to help enhance the teaching and learning of science in your classroom and at home. Create a free account today! https://ngscience.com https://www.facebook.com/ngscienceK6 https://www.pinterest.com.au/ngscienceK6/ https://www.youtube.com/c/NGScience The Lighthouse Lab is produced by Blue Ring Media on the Gold Coast, Australia. For media enquiries, please email us at [email protected]

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6:38

Thermal Energy vs Temperature

Which has more energy – an ice berg or a cup of coffee? While this may seem to be a very ...

published: 25 Jul 2018

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Thermal Energy vs Temperature

Thermal Energy vs Temperature

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• published: 25 Jul 2018
• views: 258513

Which has more energy – an ice berg or a cup of coffee? While this may seem to be a very simple question, the answer is surprise to most people.

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4:12

Thermal Energy

Mount Everest is the tallest peak and has one of the harshest climates in the world, and t...

published: 01 May 2020

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Thermal Energy

Thermal Energy

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• published: 01 May 2020
• views: 23936

Mount Everest is the tallest peak and has one of the harshest climates in the world, and the climbers trying to reach its summit must rely on thermal energy to keep them alive. This grade 6-8 science story is produced by NBC Learn in partnership with Pearson.

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7:07

Thermal Energy | Heat and Temperature

In this whiteboard animations tutorial, I will teach you thermal energy, heat and temperat...

published: 15 Jun 2020

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Thermal Energy | Heat and Temperature

Thermal Energy | Heat and Temperature

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• published: 15 Jun 2020
• views: 195035

In this whiteboard animations tutorial, I will teach you thermal energy, heat and temperature. Q: What is thermal energy? Ans: The energy possessed by an object due to the movement of particles within the system is called thermal energy. For example, consider a closed gas cylinder. The particles of the gas are in constant random motion; hence they possess thermal energy. Remember that thermal energy directly depends on the kinetic energy of particles. If the kinetic energy of the particles are high, thermal energy will also be high, and temperature of the system will increase. As a result, such a system or body will be hot. To learn more, watch this animated lecture till the end. #ThermalEnergy #Heat #Temperature #physics Subscribe my channel at:https://www.youtube.com/channel/UC_ltCdLVMRZ7r3IPzF2Toyg Youtube link: https://www.youtube.com/channel/UC_ltCdLVMRZ7r3IPzF2Toyg Facebook link: https://www.facebook.com/Najamacademy/

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3:15

Heat Transfer – Conduction, Convection and Radiation

#heat #energy #conduction #ngscience https://ngscience.com Observe and learn about the dif...

published: 04 Mar 2022

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Heat Transfer – Conduction, Convection and Radiation

Heat Transfer – Conduction, Convection and Radiation

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• published: 04 Mar 2022
• views: 573141

#heat #energy #conduction #ngscience https://ngscience.com Observe and learn about the different ways in which heat moves. Get too ngscience.com for a range of related learning and teaching resources for use in the classroom and at home. What Is Thermal Energy? All matter is made up of tiny particles. Whether matter is in a solid, liquid or gas, these particles are always in motion. How much these particles move is called thermal energy. The more thermal energy matter has, the higher its temperature. Temperature is how hot or cold matter is. It is a measure of the average kinetic energy of the particles in matter. The faster the particles mover, the greater the temperature. When matter gains thermal energy, the particles that make up the matter move faster. Its thermal energy increases and its temperature also increases. When matter loses thermal energy, the particles that make up the matter move slower. Its thermal energy decreases and its temperature decreases. So how does matter gain thermal energy? The movement of thermal energy is called heat. Heat occurs whenever there is difference in temperature. Let’s look at an example of the heat that occurs when a hot object comes in contact with a cold object. In both objects, the particles are moving – they have kinetic energy. When the objects are touching, their particles collide with each other. As they collide, the hot object passes energy to the cold object. The hot object gets cooler and the cold object gets warmer. Heat will continue to move in this way until the temperature of both objects is equal. When you place a cold metal spoon into a hot cup of tea, energy moves from the hot tea to the spoon. The tea loses thermal energy and gets cooler. The spoon gains thermal energy and gets hotter. The metal spoon will continue to gain thermal energy from the hot tea until the temperature of the tea and the spoon are equal. Just as heat moves from hot to cold between objects, it also moves in this way within objects. Let’s look at an example of placing a metal rod over a fire. The heat from the fire will cause the particles at the tip of the rod to gain thermal energy and its temperature increases. These particles then collide with the particles adjacent to them. In this way, heat in transferred from the hot region to the cold region of the metal rod. Thermal energy moves in three main ways – conduction, convection and radiation. Think again how heat moved in the metal rod placed on a fire. The thermal energy moved from the hot part of the rod to the cooler part of the rod. This movement of heat within an object is called conduction. Conduction also occurs when objects are touching. If you were to hold the cool end of the rod, before too long it would feel warm as thermal energy moves by conduction to your hand. Heat transfer from a hot cup to your hands and cooking a piece of fish in a pan are also examples of conduction. Liquids and gases are similar in that they have no fixed shape. They are fluids. Thermal energy can be transferred from one region of a fluid to another due to movements within the fluid. This movement of thermal energy, called convection, is caused by hot parts of the fluid rising and the cooler parts of the fluid sinking. Think about the water in a kettle as it is heated. The water touching the heating element is heated by conduction. The water becomes warm and rises. As it does so, the cooler water sinks and a current is created within the water. The current causes the thermal energy to spread through the water in the kettle. The heating of air in a hot air balloon is also an example of convection. For thermal energy to move by conduction and convection it must travel through matter. Between the Sun and the Earth is empty space. How does the heat from the Sun warm the Earth and other planets in the solar system? The answer is radiation. Radiation is the transfer of energy through electromagnetic waves. The warmth you feel when you place your hand near an electric heater or a campfire are examples of heat in the form of radiation.

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5:45

GCSE Physics - Conduction, Convection and Radiation #5

In this video we cover: - The 3 ways heat energy can be transferred - How heat is conduct...

published: 25 Jun 2019

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GCSE Physics - Conduction, Convection and Radiation #5

GCSE Physics - Conduction, Convection and Radiation #5

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• published: 25 Jun 2019
• views: 1248150

In this video we cover: - The 3 ways heat energy can be transferred - How heat is conducted through solids - What thermal conductivity means - How convection cycles work - What radiation is General info: - Even if you don’t need to know the details for your course, it's worth watching to understand the concepts Exam board specific info: AQA - Everything is relevant to your course! IGCSE Edexcel - Everything is relevant to your course! Edexcel - You do not need to know conduction or convection in detail, so you can skip to 4:45 OCR 21st Century - You do not need to know conduction or convection in detail, so you can skip to 4:45 OCR Gateway - Everything is relevant to your course!

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3:51

How Heat Energy Shapes Our World

#heatenergy #ngscience @NGScience Heat energy is one of the most crucial types of energy ...

published: 31 May 2023

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How Heat Energy Shapes Our World

How Heat Energy Shapes Our World

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• published: 31 May 2023
• views: 14323

#heatenergy #ngscience @NGScience Heat energy is one of the most crucial types of energy for life on Earth, and it's all around us. In this video, we'll take a look at where heat energy comes from and the variety of ways we use heat energy in our everyday lives. Let's begin with the Sun. That gigantic, shining ball of fiery gases in the sky, is the Earth's main source of heat energy. It's like a giant heating system for our planet. The Sun's heat travels millions of miles through space and reaches us here on Earth. It keeps us and all other living things warm. Without the Sun's heat, Earth would be a cold and lifeless planet. Every day, humans use heat energy in numerous ways. It's an essential part of our daily lives. Here are a few examples: Drying Clothes and Food: Have you ever hung a wet piece of clothing outside on a sunny day? The heat energy from the Sun helps to evaporate the water from your clothes, drying them out. Similarly, people dry fruits, vegetables, and other foods in the Sun. This is a method of preserving food so that we can eat it later. Cooking: We use heat energy every day for cooking food. When we turn on a stove or an oven, it generates heat. This heat cooks our food, making it safe and tasty to eat. Whether you're baking a cake, grilling a burger or roasting marshmallows on a campfire, you're using heat energy. Ironing Clothes: When your clothes are wrinkled, you can use an iron to make them smooth. The iron converts electrical energy into heat energy. The heat from the iron relaxes the fibers in your clothes, eliminating wrinkles and making them look and feel good too! Melting and Processing Metals: Heat is also used in industries, particularly in the processing of metals. For example, blacksmiths heat metal until it's so hot it becomes soft and malleable. They can then shape it into useful items like horseshoes, tools, and more. In factories, metals are heated to extreme temperatures to melt them down. They are then poured into molds to create all sorts of objects, from car parts to cutlery. Warmth in Our Homes: Lastly, but certainly not least, we use heat energy to make our homes warm and comfortable. On a frosty winter's day, we might turn on a heater, or kindle a fire in a fireplace. This heat radiates throughout our homes, creating a snug and cozy atmosphere. Beyond heating our living spaces, heat energy also plays a crucial role in warming our water. Ever wondered how your shower or bath water becomes so delightfully warm? This is achieved with the help of water heaters that use heat energy to raise the temperature of cold water. Once heated, this water can be used in multiple ways throughout our homes, from aiding in the cleanliness of our dishes and clothes to providing a relaxing soak in the tub. It's amazing how much we rely on heat energy in our daily lives. From the Sun's warmth that supports all life on Earth, to the many ways we use heat in our homes and industries, heat energy is indeed an integral part of our lives.

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5:17

Heat Temperature and Thermal Energy

Hi! Welcome to Likeable Science. As the name probably tells you, the purpose of this chann...

published: 11 Aug 2017

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Heat Temperature and Thermal Energy

Heat Temperature and Thermal Energy

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• published: 11 Aug 2017
• views: 281211

Hi! Welcome to Likeable Science. As the name probably tells you, the purpose of this channel is to make science likeable! Using humor, visual learning, time-lapse, raps, and songs, Likeable Science videos are based on a middle/high school curriculum, and help you to learn quickly in a fun and interesting way! If you like science, check out Likeable STEM (science, technology, engineering, math) at our website: https://www.likeableSTEM.com Likeable STEM includes this channel and others like Likeable Computing to teach all about computer science. Visit the Likeable STEM website for volunteering opportunities, chances to write in our blog, and for more learning opportunities! Dang! Is it hot in here, or is it just me? Today's topic is HEAT, and we're answering the question you've all probably asked at least once in your life: what IS heat? Tune in for a super LIT video about what heat is and how it can be transferred! Peace out! :)

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28:43

Physics 2 - 5.1 Heat and Temperature

🔥 Embark on a lesson on thermodynamics with TraskClass! 🌡️ In this comprehensive physics t...

published: 05 Jan 2024

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Physics 2 - 5.1 Heat and Temperature

Physics 2 - 5.1 Heat and Temperature

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• published: 05 Jan 2024
• views: 60

🔥 Embark on a lesson on thermodynamics with TraskClass! 🌡️ In this comprehensive physics tutorial, we'll delve into the fundamental concepts of heat, temperature, and heat transfer, deciphering their roles in understanding the dynamics of thermal energy. 📈🔍 🔍 Key Concepts Explored: Temperature Scales: Understand various temperature scales and their significance in measuring thermal states. Difference between Temperature, Thermal Energy, and Heat: Explore the distinctions among temperature, thermal energy, and heat, unraveling their interrelation in thermal systems. Heat Transfer Mechanisms: Dive into the mechanisms of heat transfer, encompassing conduction, convection, and radiation, and understand their distinct roles in transferring thermal energy. Specific Heat Capacity and Thermal Conductivity: Explore specific heat capacity as a property of materials and thermal conductivity's role in heat transfer efficiency. 🔬 Detailed Explanations & Practical Insights: Gain a comprehensive understanding through detailed explanations, and practical examples on the concepts of heat, temperature, and heat transfer mechanisms. 📊 Applications in Real Life: Discover how these concepts manifest in everyday scenarios, from household applications to industrial processes. 📝 Supplementary Materials Available: Access additional resources, quizzes, and exercises related to thermodynamics, heat, and temperature on traskclass.thinkific.com, enhancing your grasp of these fundamental concepts. 🗣️ Engage & Share Insights: Join the discussion! Share your thoughts, questions, or experiences related to thermodynamics and heat transfer in the comments section. Let's delve deeper into thermal energy dynamics! 💬🔥 🔔 Stay Informed: Hit the subscribe button and enable notifications to stay updated on our comprehensive tutorials unraveling the complexities of thermodynamics and heat dynamics! 🛎️ 📧 Connect with Us at [email protected]: Have inquiries or seeking further information? Reach out to us for discussions or inquiries about thermodynamics and related topics. 🚀 Explore the profound principles of thermodynamics, heat, temperature, and heat transfer, empowering you to decipher the fundamental laws governing thermal dynamics and energy transfer! 🌡️🔍

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7:03

How does a Thermal power plant work?

Help us to make future videos for you. Make LE's efforts sustainable. Please support us at...

published: 26 Jan 2016

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How does a Thermal power plant work?

How does a Thermal power plant work?

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• published: 26 Jan 2016
• views: 6946007

Help us to make future videos for you. Make LE's efforts sustainable. Please support us at Patreon.com ! https://www.patreon.com/LearnEngineering The operation of a thermal power plant is explained in a logical manner with help of animation in this video. Starting from the very basic question a conceptual overview of Rankine cycle is provided here. Topics such a Generator, Steam turbine, condenser, feed water pump, boiler are illustrated initially. The basic Rankine cycle is modified and use of super hearing, reheating and feed water heating (deaerator) is explained there after. Like us on Facebook : https://www.facebook.com/LearnEngineering Voice-over artist :https://www.fiverr.com/mikepaine

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Thermal energy

In thermodynamics, thermal energy refers to the internal energy present in a system by virtue of its temperature. The average translational kinetic energy possessed by free particles in a system of free particles in thermodynamic equilibrium (as measured in the frame of reference of the center of mass of that system) may also be referred to as the thermal energy per particle.

Microscopically, the thermal energy may include both the kinetic energy and potential energy of a system's constituent particles, which may be atoms, molecules, electrons, or particles. It originates from the individually random, or disordered, motion of particles in a large ensemble. In ideal monatomic gases, thermal energy is entirely kinetic energy. In other substances, in cases where some of the thermal energy is stored in atomic vibration or by increased separation of particles having mutual forces of attraction, the thermal energy is equally partitioned between potential energy and kinetic energy. Thermal energy is thus equally partitioned between all available degrees of freedom of the particles. As noted, these degrees of freedom may include pure translational motion in gases, rotational motion, vibrational motion and associated potential energies. In general, due to quantum mechanical reasons, the availability of any such degrees of freedom is a function of the energy in the system, and therefore depends on the temperature (see heat capacity for discussion of this phenomenon).

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This page contains text from Wikipedia, the Free Encyclopedia - https://wn.com/Thermal_energy

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