Month: March 2018

Optimum nutrition and energy from Marine Phytoplankton

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Marine Phytoplankton are single-celled plants that grow in the ocean. According to NASA scientists, Marine Phytoplankton are responsible for up to 90 percent of the planets oxygen, which is vital for maintaining life on both land and sea.

NASA scientists believe that around 3 1/2 billion years ago, the appearance of tiny plant-like organisms with the ability to convert sunlight,, water and minerals into protein, carbohydrates, vitamins and amino acids marked the beginning of life on planet Earth. Phytoplankton are the foundation for all other life forms and are the food utilized by the largest and longest living animals and fish. Blue whales, bowhead whales, baleen whales, gray whales, humpbacks, and right whales all eat plankton. These species live between 80 and 150 years old and maintain great strength and endurance throughout their lives.

Nearly all life in the ocean is dependent on plants. Only plants have the ability to manufacture food out of inorganic substances, such as energy from the sun. Thus all animals are dependent on plants, since animals cannot derive nutrition from inorganic substances. Being the original producers, plants form the first link in the food chain, a sequence of organisms in which each is food for the next member in the sequence.

In an article recently published in the Yale University Journal of Marine Research, the power stored chemically in the worlds phytoplankton equaled 63 billion kilowatts. Thus, marine phytoplankton is not only an incredible source of nutrition as the foundation of the food chain, but is a vitally important source of bio-energy as well. Benefits of Phytoplankton

The elements and electrolytes in plankton are almost tailor-made for the human body. It’s no coincidence that the composition of human plasma is quite similar in composition to seawater. Over reliance on land-based food sources often leads to deficiencies in micronutrients and trace elements. Our bodies need these elements to perform as nature intended.

Many people consuming Marine Phytoplankton report significantly increased levels of energy and vitality. The world renowned physicist, Dr. Fritz Popp, found that living things transmit small packets of light called photons. We are able to see the sparkling photon light produced by the phosphorescence in the ocean when the water is stirred at night. Since we are almost entire made up of water, we should only put into our bodies those foods and nutrients that have the highest quality, most positive frequency of energy.

Phytoplankton, the foundation of life in the ocean, the forerunner of life on land, and the sustainer of our atmosphere, has an extremely high energy frequency in addition to its nutritional content.

It is reassuring to know that a microscopic but highly powerful organism like marine phytoplankton contains the positive energy that we need to thrive, despite the hazards of environmental toxicity, stress and nutrient-depleted food. Our continued health may very well depend on our capacity to harness the nutritional and energy source from our oceans, and consuming properly harvested Marine Phytoplankton is an important step in the right direction.

Hydroelectric Energy

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Hydroelectric energyis within laymen’s terms what it really seems like,hydroelectric energycreated from waterparticularly moving water. Presently, hydroelectricity is undoubtedly typically the most popular type of alternative energy, and supplies between 15-20% from the world’s electricity. Generally,hydroelectric energyoriginates from the possibility energy of dammed water. The dammed water drives a water turbine and generator, which in turn converts the energy into electricity.

What is Hydroelectric Energy

Hydroelectricity Energy is most generally created by using dams,However particularly in places that you will find large flowing rivers and ponds to attract water from. Because of this, places like Canada, with large, intricate waterway systems make the most of this kind of energy. Furthermore they energy residential areas, however they may also actually energy energy-intensive industries like aluminum smelting along with other industrial activities.

Hydroelectricity Energy can also be fairly clean.Although fossil fuel is consumed in the making of the dam, there are virtually no carbon pollutants past the dam’s initial construction in non-tropical regions. Exactly the same isn’t true for tropical regions; however, as hydroelectric energy plants happen to be observed to create considerable amounts of methane and co2 when the surrounding forest isn’t removed.

This really is because of the truth that plant-existence decays within the flooded areas in an alarming rate, creating methane, in addition to more compact levels of co2. Out of the box also reiterated below, positioning is essential if this involves creating a hydroelectric dam.

Regrettably, hydroelectricity energy is certainly not without its problems. Planning hydroelectric energy projects frequently overlooks the harm to marine habitats and environments also to the nearby indigenous towns, and also requires relocating whenever a dam is made because of flooding within their towns.

This kind of callousness is exactly what rapidly becomes problematic with dams. Organizers need to be especially careful when directing river ways to be able to prevent any harsh long-term effects on individuals that rely on water, whether human or animal, also to conserve historic monuments along with other sites of cultural significance.

For example, while dams may be used to prevent flooding when water levels rise beyond normal levels, in the region around Burns Lake, Bc, Canada, a whole village was instructed to relocate because of flooding from the making of a dam.

Hydroelectric Energy doesn’t pollute water or even the air

However, hydroelectric energy facilities might have large environment impacts by altering the atmosphere and affecting land use, houses, and natural settings within the dam area.

Most hydroelectric energy plants possess a dam along with a reservoir

These structures may obstruct seafood migration and affect their populations. Operating ahydroelectric energyplant could also alter the temperature of water and also the river’s flow. These changes may harm native plants and creatures within the river as well as on land. Tanks may cover individual’s houses, important natural areas, farming land, and ancient sites. So building dams can require moving people. Methane, a powerful green house gas, could also form in certain tanks and become released towards the atmosphere.

Home Thermal Energy – 9 Steps To Detect And Fix Heat Loss Problems

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Whether you live in a warm or cold climate, heating and cooling account for over half of the average home energy costs. Making sure your house is adequately weatherized and insulated is your first line of defense to stopping unnecessary home thermal energy loss. It will not only save you money, but reduce pollution and slow the depletion of irreplaceable natural resources.

Some obvious signs that home thermal energy is being wasted are: general draftiness; constant frost on your windows; snow melting off your roof more quickly than other nearby homes; and high heating bills. Some not so obvious signs of home heat energy loss are: inadequate wall insulation; warm air escaping around chimneys; and heat loss through glass.

Here are 9 ways to find and correct Home Thermal Energy loss:

1. Measure insulation between the joists in your attic to determine if it meets the recommended R-value standards. To figure out the total current R-value, multiply the number of inches of loose insulation by 3.7; for fiberglass insulation, multiply by 3.1 per inch. If total amounts are substandard, you need to add more insulation to meet the standard. The recommended R-value for attics in a cold climate is R38; for a moderate climate, R26.

2. Measure the temperature in different areas of a room. A room is poorly sealed if you can detect differences in temperature of one or two degrees. Saving thermal energy in this case is as easy as upgrading the weatherstripping around doors and windows.

3. Check for drafts around windows and doors. An easy way to do this is on a windy day, hold a tissue next to the gaps where your doors and windows open and close. If the tissue flutters, your weatherstripping is inadequate, and it should be replaced or upgraded. Another heat saving idea to minimize home thermal energy loss is to look for light showing from the outside around door and window jambs.

4. Conduct a home energy audit with the assistance of your local utility company. Most power companies will provide a home energy audit kit. Some may even conduct the audit for you for a fee or in some cases, free of charge.

5. Frost buildup on windows is clear evidence of poor weatherstripping and an inadequate storm window. To inexpensively stop home thermal energy loss in this case, just upgrade the weatherstripping and add a layer of plastic sheeting on the exterior or interior side of the window.

6. Condensation or frost between windows happens when moisture builds up in the space between the window and the storm window. To save thermal energy for this problem and keep the warm, moist air on the inside, update the interior weatherstripping. Also, you need to check that there’s an outlet for moisture in the storm window. If there isn’t, you can make one by drilling one or two small holes in the lower rail of the storm window.

7. Inspect insulation and weatherstripping. What you want to check for here are signs of deterioration like crumbling foam or rubber; hardening of materials like felt or foam rubber that should be flexible; and damaged metal stripping. Replacing these materials as needed goes a long way in saving your home thermal energy and keeping your average home utility costs down.