Final Experience

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When I first had to choose a science class to complete my requirements, I was not very excited about the idea of it. I do not consider myself as a person who enjoy science, however, this class proved me wrong. During the semester, I learn a lot about different topics and performed a different experiment in class which made the class very interested and easy to understand.

For our final experiment, we had to get into groups and design a science experiment that would relate and apply something we have to learn during the semester. Along with my group, we decided to perform a hydropower experiment which consisted of a waterwheel. Building the experiment was very interested and enjoyable. Applying different formulas we have learned in class exciting and building the experiment plus analyzing the data we got was also exciting. Although as in every experiment we did not have great success in every attempt some of them were better than others, we ended up having a good turnout at the end. During our final class meeting, we were able to share our project and experience with our classmates and see what others have done. In addition, we were allowed to display our experiment and show to other students how they could achieve the same experiment we designed for our class.

I found interesting and educational, to see what other students have done for their final experiments, and being able to do the experiments in class was also helpful to understand what they did and how they did it. As I said before, it is interesting to see the amount of trials and errors that can happen behind each experiment.

Now looking back in time, I am thankful I choose this as my science class because not only I learned but I got to do and built my own science experiment.

Oil – gas and fracking

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Why are oil and gas prices currently so low?

Currently, we have been having the lowest gas prices since 2009 with the gallon of gas just above $2; but why are the prices so low?

The oil prices started to drop halfway through 2015, and now the decline is shaper than before. There are a number of related factors leading to this drop, but one of the most common is that supply is exceeding demand. It is not a secret than the U.S has been stocking up its production of oil. According to the OPEC cartel which consist of 13 different countries report that Iran, one of the seven largest oil producers in the world, will be increasing its oil production despites of the low prices and demand.

Crude oil has dropped in value o around $32 a barrel on Wednesday according to the New York Times. The low cost of crude oil has driven down not only gasoline prices but the cost of “diesel, heating oil, and natural gas” as well, according to the Times.

What Fracking is?

 

“Fracking is shorthand for hydraulic fracturing; a type of drilling that has been used commercially for 65 years.”

Hydraulic Fracturing Gas Drilling

Hydraulic Fracturing Gas Drilling

Otherwise, known as hydraulic fracturing, has been in use since 1940’s. Fracking is a drilling technique used for extracting oil or natural gas from deep underground.  Today, the combination of advanced hydraulic fracturing and horizontal drilling, employing cutting-edge technologies, is mostly responsible for surging U.S oil and natural gas production.

How does this process work?

This process involves safely tapping shale and other tight-rock formations by drilling a mile or more below the surface before gradually turning horizontal and continuing several thousand feet more. Thus, a single surface site can accommodate a number of wells. Once the well is drilled, cased and cemented, small perforations are made in the horizontal portion of the good pipe, through which a typical mixture of water, sand and additives are pumped at high pressure to create micro-fractures in the rock that are held open by the grains of sand. Additives play a number of roles, including helping to reduce friction and prevent pipe corrosion, which is turn help, protect the environment and boost well efficiency.

Is it role in contributing to current oil and gas prices?

Hydraulic Fracturing has helped boost the rate at which oil and gas can be extracted from wells, specifically in the United States. Increasing the currently available supply is one way that fracking helps to lower the oil prices on a local scale. This is particularly true here in the U.S since oil does not have a strong local market in the U.S. Fracking lowers the cost of oil to the extent that it allows real supply to expand. However, there are limits on the extent to which fracking can be used to increase supply. Oil is scarce and hydraulic fracturing is more expensive and complicated than traditional oil extraction. Unfortunately, the success of fracking will eventually not be as beneficial unless technological changes make the technique less costly.

In a long time, fracking could potentially speed up the rate at which oil prices climb. When natural oil supplies approach depletion, the lack of supplies will require the prices to be higher. It is unlikely that the world will ever run out of oil but once the prices go high enough, substitutes for it will be absolutely necessary and its production won’t be lucrative.

 

References:

http://www.what-is-fracking.com/what-is-hydraulic-fracturing/

http://www.livescience.com/34464-what-is-fracking.html

http://www.investopedia.com/ask/answers/013015/how-does-fracking-affect-oil-prices.asp

http://www.thestreet.com/story/13394038/1/the-basics-on-why-oil-prices-are-so-low-and-what-it-means.html

Brainstorming Session #1

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Unfortunately, I was not able to be present in our first Brainstorming session as a group, however after class I talked to my groupmates and we discuss what they had come up during class for our final project. For the project we discussed the following three (3) ideas to be developed as out final experiment:

  1. Chemical Energy (Animal Waste)
  2. Thermal Energy ( Inflate Balloon with bottle in water)
  3. Hydro Energy (Waterwheel Electrically)

Along this blog, I will discuss in brief what each of these three (3) options consist off, and further along during the time in class, we will select one to develop in-depth as our final experiment.

  1. Chemical Energy ( Animal Waste)

What’s Biomass?

Biomass fuels come from things that once lived: wood products, dried vegetation, crop residues, aquatic plants and even garbage. It is known as “natural materials”. Plants used up a lot of the sun’s energy to make their own food (photosynthesis). They stored the food in the plants in the form of chemical energy. As the plants died, the energy is trapped in the residue. This trapped energy is usually released by burning and can be converted into biomass energy.

How is biomass converted into energy?

Energy from the sun is transferred and stored in plants. When the plants are cut or die, wood chips, straw, and another plant matter is delivered to the bunker

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-This is burned to heat water in a boiler to release heat energy (steam).

-The energy/power from the steam is directed to turbines with pipes

-The steam turns a number of blades in the turbine and generators, which are made of coils and magnets.

2. Thermal Energy ( Inflate Balloon with bottle in water)

The matter is made up of particles or molecules. These molecules move constantly. A rise of temperature of matter makes the particles vibrate faster. Thermal energy is what we call energy that comes from the temperature of matter. The hotter the substance, the more its molecules vibrate, and, therefore, the higher it’s thermal energy.

The picture below shows an example of this process “If we want to boil the water in these two beakers, we must increase their temperatures to 100°C. You will notice that will take longer to boil the water in the large beaker than the water in the small beaker. This is because the large beaker contains more water and needs more heat energy to reach 100°C.”

The matter is made up of particles or molecules. These molecules move constantly. A rise of temperature of matter makes the particles vibrate faster. Thermal energy is what we call energy that comes from the temperature of matter. The hotter the substance, the more its molecules vibrate, and, therefore, the higher it’s thermal energy.

The picture below shows an example of this process “If we want to boil the water in these two beakers, we must increase their temperatures to 100°C. You will notice that will take longer to boil the water in the large beaker than the water in the small beaker. This is because the large beaker contains more water and needs more heat energy to reach 100°C.

thermal-energy

3.Hydro Energy (Waterwheel Electrically)

 This process works by using water to power machinery or make electricity. Water constantly moves through a vast global cycle, evaporating from lakes and oceans, forming clouds, precipitating as rain or snow, and then flowing back down to the ocean. The energy of this water cycle, which is driven by the sun, can be tapped to produce electricity or for mechanical tasks like grinding grain

The picture below shows how this process works:

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From these three options, we will select one that would best work for our final experiment and then develop it.

 

President’s Climate Action Plan

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The president’s Climate Action Plan originally published in June 2013 with the function and “moral obligation to future generations to leave them a planet that is not polluted and damaged. “Over time, we have to encounter serious effects due to climate change. We have come to realized that climate change represents one of our greatest challenges of our times. It establishes a vision for the US government to work to prevent climate change domestically and internationally.

  1. Cut Carbon Pollution in America
  2. Prepare the United States for the Impacts of Climate Change
  3. Lead International Efforts to Combat Global Climate Change and Prepare for its Impacts

In this blog, we will discuss one of each initiative from each of the three key pillars proposed by the Action Plan.

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1 In regards of the first pillar (Cut Carbon Pollution in America), this plan includes deploying clean energy by cutting carbon pollution from power plants as power plants. “Are the largest concentrated source of emissions in the United States, together accounting for roughly one-third of all domestic greenhouse gas emissions.” Despite the plan being written and the progress at the state level, there were no federal standards in place to reduce carbon pollution from power plants, although some changes were being made at the state level. Carbon pollution standards for both new and existing power plants are being created by the Environmental Protection Agency.

With abundant clean energy solutions available, and buildings on the leadership of states and local governments, we can make continued progress in reducing power plant pollution to improve public health and the environment while supplying the reliable power needed for economic growth. In order to accomplish these goals, President Obama is issuing a Presidential Memorandum directing the Environmental Protection Agency to work expeditiously to complete carbon pollution standards for both new and existing power plantsFollowing with the second pillar (Prepare the United States for the Impacts of Climate Change), “ During the president’s first term, the United States more than doubled generation of electricity from the wind, solar, and geothermal sources.” To ensure America’s continued leadership position in clean energy, President Obama has set a goal to double renewable electricity generation once again in 2020. The plan includes protecting our economy and natural resources in many ways including protecting our economy and natural promoting resilience in the health sector, conserving land and water resources, and identifying vulnerabilities of key sectors to climate change. . “In order to meet this ambitious target, the Administration is announcing a number of new efforts in the following key areas:  Accelerating Clean Energy Permitting, Expanding and Modernizing the Electric Grid.” Promoting resilience in the health sector means providing guidance on affordable measures to ensure that our medical systems are resilient to climate impacts, collaboration with partner agencies to share best practices among federal health facilities, and training public health professionals and community leaders to prepare their communities for the health consequences of climate change.

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2.Following with the second pillar (Prepare the United States for the Impacts of Climate Change), “ During the president’s first term, the United States more than the double generation of electricity from the wind, solar, and geothermal sources.” To ensure America’s continued leadership position in clean energy, President Obama has set a goal to double renewable electricity generation once again in 2020. The plan includes protecting our economy and natural resources in many ways including protecting our economy and natural promoting resilience in the health sector, conserving land and water resources, and identifying vulnerabilities of key sectors to climate change. . “In order to meet this ambitious target, the Administration is announcing a number of new efforts in the following key areas: Accelerating Clean Energy Permitting, Expanding and Modernizing the Electric Grid.” Promoting resilience in the health sector means providing guidance on affordable measures to ensure that our medical systems are resilient to climate impacts, collaboration with partner agencies to share best practices among federal health facilities, and training public health professionals and community leaders to prepare their communities for the health consequences of climate change.

3. Continuing with the third pillar (Lead International Efforts to Combat Global Climate Change and Prepare for its Impacts) this plan main goal is to attempt to work with other countries to take action to address climate change. This is accomplished in many different ways such as:

-Enhancing multilateral Engagement with Major Economics

-Expanding Bilateral Cooperation with Major Emerging Economics

– Combatting Short-lived Climate Pollutants

– Reducing Emission from Deforestation and Forest Degradation

And also including Expanding clean energy use and cutting energy waste which can be sub-divided by:

-Financing and regulatory support for renewable and clean energy projects

– Actions to promote fuel switching from oil and coal to natural gas or renewables

–  Support for the safe and secure use of nuclear power

–  Cooperation on clean coal technologies

– Programs to improve and disseminate energy efficient technologies

References:

https://www.whitehouse.gov/energy/climate-change

https://www.whitehouse.gov/sites/default/files/image/president27sclimateactionplan.pdf

 

Museum of Sciene

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During our visit to the Museum of Science, we were asked to visit four (4) different exhibitions and perform the hands-on activities. We visit catching the wind, conserve @ home, energized! and investigate. All these exhibitions had activities to perform along the information which was helpful to see how the theory we learned in class relates to the practice.

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The first exhibition I visit was Energized; this exhibition focused on sunlight, moving water, and other self-replenishing sources that generate cleaner energy with fewer negative side effects. Along the exhibition, the viewer has the opportunity to perform hands- on activities and informative content that make us realized and think twice about the power we are using in our everyday. We use energy every day and for everything from powering our personal devices to even powering our buildings and unfortunately, our main source of energy is coming from sources that will eventually run out and are not good four our planet. Energized, makes you want to pay more attention toward this type of energy and rethink about the options and abilities that renewable energy has and the benefits this could bring us. It was nice, to see and have some hands-on activities to do since we have discussed this topic in class several times. Having this topic here again is a reinforcement of what we have learned and possibly seeing it from a different perspective other than the classroom.

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The next exhibition was Catching the Wind; this was just around the corner from energized which makes a great combination with the amount of information that both share. This display was an informational exhibition about wind turbines and how they are slowly but surely appearing more frequently in both the news and along our highways. Along this exhibition, the viewer learns how wind turbines generate electricity, in addition to it there is also an activity called “Wind Power Challenge” which consist of choosing a location and a turbine type, and then see if this can power your home, business or community. A great “game” to see and understand the process of a wind turbine and its advantages.

IMG_2689Continuing through the Museum of science moving on to the upper floors, we can encounter a variety of exhibits all very interesting and diverse great for anyone that would like to learn a few different topics; however, the next exhibition I visit was conserve @ home. This exhibit was all about teaching us how to save energy and its importance, and how this can also help us to save money on our daily basis by only doing some modification to our energy spending routine. Through the exhibition just as in the others there are some hands on actives, but there are some examples of how turning everyday things into more usable ones can help us recycle and repurpose the use of materials we daily encounter. One of the activities “turn your energy into light” (see picture above) I found to be very interesting because it has three different types of a lamp such as LED, Incandescent, and CFL which will lead up while you turn the wheel around giving it the power to turn on. The different activities offered at this exhibit will teach anyone who comes to it different ways to make the most out of energy consumption, time, and money.

The next exhibition I visited is called Investigate, this exhibit without a IMG_2686doubt was one of my favorites for it the particular way of displaying its information. This exhibit is set up in a unique way as it looks as you are entering a house, starting from the living room and learning the different scientific process.  Then we encounter the bathroom which shows two sinks that allow you to investigate if water always drains in the same direction in this hemisphere and then a toilet which was one of my favorite parts because it shows it in section (cut through half) allowing you to see how its process works when your flush it (this link will show a video I recorded during my visit Video). Something that we use every day and we do not really think about how it works. Moving on the “house” continues to develop into a kitchen kind of shape, a garage and a front yard each of these with different experiments, hands-on experiences and a broad amount of information that allow us to learn and appreciated many different aspects of science.

In conclusion, without a doubt the museum of science was a great experience to put in practice the theory we have learn through class, add some information and learn more while in a different set up rather than the classroom.

Pandora Promise

 

Pandora’s Promise is a documentary about the history and future of nuclear power. The film covers the discussion about this controversial topic. Through the documentary, a neutral concept and position about the nuclear power are “try” to be maintained by presenting the different sides of this issue and at the same time trying to answer the question we all ask “how do we continue to power modern civilization without destroying it?”. However; many said this is a pro-nuclear propaganda which I found to be an interesting attitude toward the topic provides a curious perspective on how environmentalist and supporters of nuclear power support stand on this issue.

Although a stronger “neutral” position will be preferable when talking about nuclear power; the documentary shows support towards nuclear power and even takes the time to expose the myths behind this topic. Most of these are concentrated the discussion over the danger that comes together with nuclear power and in discussion to the historic events that have been inevitable and, unfortunately, relevant because of this problem.

Through the documentary I was very impressed with the amount of support nuclear power got from different “environmentalist”; in my opinion, a person is either with or against something and this is the same with nuclear power you either love the environment or support and believed nuclear power is actually helpful for the environment and for our future and for the future generations.

Underexposing this extremely dangerous power, and hiding it under “pro-nuclear” words, mean supporting a developing of a process that with more power and support could end up affecting us all around the world. It’s been proved, and we have lived through many different nuclear disasters that have been underestimated in this film just to hide the causes of nuclear power. Underestimating the amount of death and horrible causes that a nuclear disaster brings with it is just not correct. Unluckily, It is extremely hard for me to agree with the statement established along this documentary, after researching about different causes of nuclear disasters and its horrible effects on the environment and humans life I find extremely hard to support a cause that it’s been originally known as bad, dangerous, and even in my opinion “lethal top our health” to be considered as “not as bad.” There are many things that can go “wrong” when dealing with such a delicate issue. It is not just to say that we will build safe nuclear power station when back in 2011 one of the worst nuclear disaster happened followed by a natural disaster even though the nuclear station was well built and put together and was consider as “safe” this end up causing a horrendous disaster to be remembered through history.

The way they showed facts and “proves” did not do a good job convincing me that nuclear power is “good” I strongly believed it’s not, even more after watching the documentary.  Exposing and “highlighting “other causes dangerous effects to hide the once produced by the nuclear power it’s not a right way to achieve or convey a concept.

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Nuclear Disasters

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“An event that has led to significant consequences to people, the environment or the facility.” IAEA

Fukushima Accident

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In 2011, one of the world worst accidents took place in Japan. An earthquake of magnitude 9.0 at 2:46pm on Friday March 2011 changed the live of a whole country leaving considerable damages which was followed by a 15-meter tsunami which resulted in outrageous amount of human death, over a million building  destroyed and a huge damage to costal ports and towns.

During the accident eleven (11) reactors at four nuclear power plants were operating in the region and immediately shut down with the earthquake. Even though the reactors proved robust seismically, they were vulnerable to the tsunami; the 15-meter tsunami flooded the entire site disabling the power supply and cooling of three Fukushima Daiichi reactors, causing a huge nuclear accident. This disabled 12 of 13 back- up generators on site and also heat exchanges for dumping reactor waste heat and decay heat to the sea. To add up to this tragedy a hardened emergency response center on site was unable to be used in grappling with the situation, due to radioactive contamination.

This accident was rated 7 on the INES scale, due to high radioactive releases over days 4 to 6, eventually a total of some 940 PBq (I-131 eq Although, there have been no deaths or cases of radiation sickness from the nuclear accident, however over 100,000 people were evacuated from their homes to ensure this. Government nervousness delays the return of many.

-The following picture color code different areas, the green areas show “Areas to which people may return but no stay overnight and there is not a required equipment to return” the orange area are restricted, pink area is named “difficult” meaning its accessible but only for public interest, red area represents fully evacuated and yellow represents planned evacuation area.

fukushima_evacuation_evolutionChernobyl Accident

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This accident took place the April of 1986 in Ukraine, The Chernobyl accident was the result of a flawed Soviet reactor designed that was operated with inadequately trained personnel. This was a direct consequence of Cold War isolation and the resulting lack of any safety culture.

This horrific accident ended up destroying the whole Chernobyl 4 reactor, killing more than 20 operators and firemen within three months later, acute radiation syndrome was diagnosed in more than 200 people on-site confirming 134 cases from which about 28 people died.

The Chernobyl disaster has been the only even in history of commercial nuclear power where radiation-related fatalities occurred; this led to major changes in safety culture and industry operation over time.

Safer Nuclear Technology

After the Fukushima accident the U.S has develop some safety proposal that should be consider in order to prevent a tragedy. While the probability of a nuclear power accident may be small, the human and environmental consequences of a radiation release can be catastrophic. Enforcing fire and earthquake regulations, addressing flood risk, and safer storage for nuclear waste are just a few of the ways we can help prevent nuclear accidents. Although nature is a big threat for nuclear facilities it’s not the only one. These facilities are key targets for sabotage and terrorist attack, and these could have horrible consequences if successfully performed. Nuclear Regulatory Commission (NRC) makes security rules that all plats must follow in order to maintain a safe status some of these are: security access zones, size and capability of security staffing, testing security systems and more; however these are not the only ways to prevent a nuclear technology, and there are many theories that agree that the NRC must do more to prevent and make nuclear technology safer.

Safely store waste

“Nuclear fuel remains dangerously radioactive for thousands of years after it’s no longer useful in a commercial reactor.”

  • Dry cask for short term solution

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Spent fuel pools at nuclear plants tend house nuclear waste only until it is cool enough to be transferred to permanent storage, have become dangerously overcrowded as the search for a permanent repository has stalled.  Experts recommend that instead of doing this it’s better to store it right away into dry casks to reduce safety hazard.

  • Repositories for long term solution

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  • Reprocessing

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 According to some research reprocessing is not a good solution, although many have been doing it over the past years this process separates nuclear waste into component materials, including plutonium, which can then be re-used as nuclear reactor fuel BUT it can also be used as the raw material for a nuclear weapon which can lead to terrorism attacks putting ourselves into a serious risk.

References

http://www.world-nuclear.org/information-library/safety-and-security/safety-of-plants/fukushima-accident.aspx#.UZn0laL2axo

http://www.world-nuclear.org/information-library/safety-and-security/safety-of-plants/chernobyl-accident.aspx#.UZn2DKL2axo

http://www.ucsusa.org/nuclear-power#.VuHaHPkrK9K.

http://www.ucsusa.org/nuclear-power/nuclear-waste#.VuHoCPkrK9I

 

 

Thermoelectric devices

Thermoelectric devices

Thermoelectric devices are made from thermoelectric modules. A thermoelectric module is an array of thermocouples connected electrically in series but thermally in parallel

 How do they work?

A thermoelectric device converts thermal energy into electrical energy by using an array of Thermocouples. This device is a reliable source of power for satellites, space probes, and even unmanned facilities. Satellites that fly toward planets that are far away from the sun cannot rely exclusively on solar panels to generate electricity. These satellites will have to use an alternative energy source, such as thermoelectric devices, to generate their power, as in NASA’s Pluto New Horizons spacecraft. Thermoelectric devices for deep-space missions use a radioactive material, like plutonium, to generate heat, and thermocouples to convert the heat to electricity. Since a thermoelectric device has no moving parts, it is reliable and can generate electricity for many years. Studies have been done on improving the efficiency of the thermoelectric generator by incorporating other technologies, like nanotechnology. By achieving a better efficiency, thermoelectric devices would need less radioactive material to produce the same amount of power, making the power generation system lighter. The Less radioactive material will also decrease the cost of spaceflight launches. Although these devices are used mostly in spacecraft technologies, they can be also applied to technologies on earth, which might further contribute to the advancement of technology. Some applications of this technology include automobiles, computers, household appliances, etc.

The image below shows a graph explaining how this system works 

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The following video is a detailed explanation showing how this process works:

What are the most common applications for it?

Thermoelectric effects can be used to make solid-state refrigeration devices, or to sense temperature differences, or to convert thermal energy directly into electricity. While the Peltier effect is used within thermoelectric cooling devices, the Seebeck effect is responsible for the conversion of temperature gradients to an electrical voltage.

  • Peltier effect: Thermoelectric cooling

Thermoelectric cooling uses the Peltier effect to create a heat flux between the junctions of two different types of materials. A Peltier cooler, heater, or thermoelectric heat pump is a solid-state active heat pump which transfers heat from one side of the device to the other, with consumption of electrical energy, depending on the direction of the current.

The image below shows a schematic of a Peltier cooler

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  • Seebeckeffect: Thermoelectric temperature sensing and power generation

This effect is the conversion of a temperature gradient across the junctions of two dissimilar metals to electrical voltage in the range of millivolts per Kelvin difference. The effect is non-linear with temperature and depends on absolute temperature, type and structure of materials.

The picture below is an example Seebeck voltage generator

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  • The Thomson effect

The Thomson effect,” or “Kelvin heat, describes the heat release in a material with a current through it. This heat release is directly measurable. That is unlike the Peltier and Seebeck effects, for which only the net effect of two different materials can be measured. Since the Peltier and Seebeck coefficients can be computed from the Thomson one, in principle the Thomson effect allows all three thermoelectric coefficients to be found without involving the second material.

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Example of thermoelectric devices:

The thermoelectric devices can enhance the energy production of hybrid automobiles by producing electricity using the waste heat of the engine.

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This image shows the inside of GMZ Energy’s TEG module. When waste heat enters the top of the module and moves through the semiconductor material (shown here as P and N) to the cooler side, the resulting temperature difference creates a voltage that’s extracted as electricity. Credit: Screenshot from a video by GMZ Energy

References

http://thermoelectrics.caltech.edu/thermoelectrics/engineering.html

http://www.spacegrant.hawaii.edu/reports/22_FA09-SP10/SLee_FA09.pdf

http://www.iue.tuwien.ac.at/phd/mwagner/node18.html

https://www.eng.fsu.edu/~dommelen/quantum/style_a/semicte.html

http://phys.org/news/2014-08-thermoelectric-devices-electricity-vehicles-machines.html

Iceland’s use of geothermal energy

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“Geothermal power facilities currently generate 25% of the country’s total electricity production.”

Over the past of a few years, Iceland has definitely made a change. Iceland went from what was known as one of Europe’s poorest countries to a country with high standard of living. Studies have shown that “In 2014, roughly 85% of primary energy use in Iceland came from indigenous renewable resources. Thereof 66% was from geothermal.”

Iceland as a country…

Iceland is relatively a young country geologically. It lies astride one of the earth’s major fault lines, the Mid-Atlantic ridge. This is the boundary between the North American and Eurasian tectonic plates. As a result of its location, Iceland is one of the most tectonically active places on earth, More than 200 volcanoes are located within the active volcanic zone stretching through the country from the southwest to the northeast, and at least 30 of them have erupted since the country was settled. In this volcanic zone, there are at least 20 high-temperature areas containing steam fields with underground temperatures reaching 250°C to 1,000 m depth.

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As a way to understand its “concept” in an easier way, the video below explains and shows how Iceland is based on geothermal energy and  describes how this benefits the country in many different ways by showing geothermal potential around the world:

Now that we have some background information about this country let’s talk a little bit about how they use geothermal resources…

The island itself its basically a blister of porous basalt at the crack in Earth’s crust where the North America. There are enormous underground reservoirs of water that are continually renewed by levels of annual precipitation that range as high as 177 inches over Iceland’s glaciers, and shallow patches of magma that heat the deepest reaches of these reservoirs to temperatures in excess of 750 degrees Fahrenheit.

The graphic below represents the use of geothermal energy during the year of 2013.

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The following image shows how electricity generation has developed since 1970-2013.

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It is clear to see, how the demand for geothermal energy has significantly increased over the years.

Iceland is known around the world as a leader in the use of geothermal district heating. Today, about 9 out of 10 households are heated with only geothermal energy.

Geothermal energy has been used for thousands of years in some countries for cooking and heating. It is simply power derived from the Earth’s internal heat. This thermal energy is contained in the rock and fluids beneath Earth’s crust. It can be found from shallow ground to several miles below the surface, and even farther down to the extremely hot molten rock called magma

There are three types of geothermal power plants: dry steam, flash, and binary. Dry steam, the oldest geothermal technology, takes the steam out of fractures in the ground and uses it to directly drive a turbine. Flash plants pull deep, high-pressure hot water into the cooler, low-pressure water. The steam that results from this process is used to drive the turbine. In binary plants, the hot water is passed by a secondary fluid with a much lower boiling point than water. This causes the secondary fluid to turn to vapor, which then drives a turbine. Most geothermal power plants in the future will be binary plants.


Generating Heat:

In  difference from the U.S there is not a national grid in Iceland- harnessing the energy comes via the remarkably simple method of sticking a drill in the ground near one of the country’s 600 hot spring areas, and using the steam that is released to turn the turbines and pump up water that is then piped to nearby settlements.

Geothermal water is used to heat around 90% of Iceland’s homes, and keeps pavements and car parks snow-free in the winter. Hot water from the springs is cooled and pumped from boreholes that vary between 200 and 2,000m straight into the taps of nearby homes, negating the need for hot water heating. It’s also purified and cooled to provide cold drinking water.

Generating electricity:

Once this heated water is forced to the surface, it is a relatively simple matter to capture that steam and use it to drive electric generators. Geothermal power plants drill their own holes into the rock to more effectively capture the steam.

There are three basic designs for geothermal power plants, all of which pull hot water and steam from the ground, use it, and then return it as warm water to prolong the life of the heat source. In the simplest design, known as dry steam, the steam goes directly through the turbine, then into a condenser where the steam is condensed into water. In a second approach, very hot water is depressurized or “flashed” into steam which can then be used to drive the turbine.

In the third approach, called a binary cycle system, the hot water is passed through a heat exchanger, where it heats a second liquid—such as isobutane—in a closed loop. Isobutane boils at a lower temperature than water, so it is more easily converted into steam to run the turbine.

These systems are best representing in the picture below

energy-renewable-geothermal-plant-designs-diagrams

References:

http://www.nea.is/geothermal/

http://www.scientificamerican.com/article/iceland-geothermal-power/

http://www.theguardian.com/environment/2008/apr/22/renewableenergy.alternativeenergy

http://ourworld.unu.edu/en/geothermal-energy

http://www.ucsusa.org/clean_energy/our-energy-choices/renewable-energy/how-geothermal-energy-works.html#.Vtkn-JwrKhc

 

New Solar Energy Efforts around the World

Innovations in Solar Energy 

Today, the world is advancing day by day and in many parts of it, we are facing wonderful creations that show solutions to many of problems for our planet earth. There are numerous of incredible ways utilize solar energy. Along this post, I will be discussing different inventions around the world that represent an incredible solution for our future.

Sahara Forest Project

“It is designed to utilize what we have enough of to produce what we need more of, using deserts, saltwater and CO2 to produce food, water, and clean energy.”

Sahara04

An ambitious Idea that started back in 2008 today is becoming a reality. The Sahara Forest Project would turn the desert into a source of food, water, and energy. This project combines concentrated Solar Power and Seawater greenhouses to provide renewable energy and sustainable agricultural solutions. The Sahara project has the purpose of providing us with key resources to live. According to Sahara project website, “In 2050 about 9.3 billion people will share our planet.” And as many of us know today in many places around the world looking for those key resources is a challenge. “The Sahara Forest Project is designed to utilize what we have enough of to produce what we need more have, using deserts, saltwater, and CO2 to produce food, water, and clean energy. This is done by combining already existing and proven environmental technologies, including saltwater-cooled greenhouses, concentrated solar power (CSP) and technologies for desert revegetation around a saltwater infrastructure. The synergies arising from integrating the technologies improve the performance and economics of the system compared to those of the individual components.”

The images below show what the project will look like when fully completed

Sahara05-537x309Sahara02

Netherlans- SolaRoad

solaroad

The world’s first solar road is an energy- harvesting bike path paved with glass-coated solar panels. What originally claim to be a great solution to generate solar power today it has shown to be even better than expected. This 70-meter test bike path generates 3,000 kWh this is enough to provide a single-person household with electricity for a whole year.

“If we translate this to an annual yield, we expect more than the 70kwh per square metre per year,” says Sten de Wit, spokesman for SolaRoad

How does it work?

The amazing creators behind this wonderful project spent five (5) years developing this technology.  “ The solar panels are sandwiched between glass, silicon rubber and concrete, and are strong enough to support 12- tonne fire tucks without any damaged. Each individual panel connects to smart metres, which optimize their output and feed their electricity straight into street lighting, or the grid.”

The images below show how the road looks from the top and side view

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Solar Billboards or “Eco-board”

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Neon sign that uses wind and sun energy to brighten streets

“ Small changes in awareness can turn into large-scale progress”

This spectacular innovation consists of billboard powered by 100% self-supplied electricity from wind turbines and solar panels on the billboard. This eco-board have been placed by Ricoh company in different part of the world. New York, London, Tokyo and Sydney are some of the cities that count with these boards.

This “eco-board” only illuminate when there is sufficient power generated from renewable power supplies. The eco-boards are the first of this kind in Europe to be fully powered by renewable energy “five wind turbines and 96 solar panels” Only one day of sun exposure, the billboard can light up to 210, 60-watt lightbulb for one hour.

The eco-boards also use 1/5 the energy of an LED billboard and ¼ energy of a fluorescent light billboard, which is why the Ricoh team believed this kind of eco-advertising could change the face of the industry.

“the effects of reducing energy consumption due to a single billboard might be small. But an eco-billboard that embodies an eco-friendly message may generate significant momentum for change if it succeeds in raising awareness of global environmental issues. We seek to proceed step-by-step with everyone towards the realization of a society that runs on sustainable resources.”Said  Ricoh

ricoh_solarbillboard

These are only a few of the amazing innovations we have been seeing around the world over the last years and without any doubt each of these are wonderful additions to our planet.


 

References:

http://saharaforestproject.com/concept/products.html

http://inhabitat.com/norway-and-jordan-sign-agreement-to-make-sahara-forest-project-oasis-a-reality/sahara04/

http://www.aljazeera.com/news/2015/05/150510092535171.html

http://www.sciencealert.com/solar-roads-in-the-netherlands-are-working-even-better-than-expected

https://www.ricoh.com/about/company/promotions/eco-billboards/newyork/

http://mashable.com/2012/01/04/innovative-solar-energy-tech/#0LgxxZw1Biqh