Learn How to Keep Skin Young Looking

Did you know some societies have known secrets about how to keep skin young looking for thousands of years?  Whether it was the use of seaweed masks, honey facials, palm oil, olive oil or parasols to protect their faces from the sun, many women had the right idea.  The latest research confirms that.

During the 1970s, 80s and even into the 90s, sunbathing and tanning was a common practice.  The idea of a “healthy” tan was promoted by companies that made tanning beds.  They even claimed that the UV emitted from their beds was safer than exposure to sunlight.  A lot of people fell for it.

Because of the sun-worshipping craze, there are a lot of people in the 40+ age group that have more wrinkles and age spots than they should.  Those things can be blamed on sun damage.

UV rays, whether they come from a bulb or the sun, stimulate the production of molecules called free radicals.  The body’s only defenses against free radicals are antioxidant molecules.  Supporting the skin’s antioxidant content is the first step in how to keep skin young looking.

Once we pass the age of 40, it is necessary to improve the skin’s antioxidant content.  Older skin cells contain more free radicals and produce fewer antioxidants.

We get antioxidants like the vitamins A, C and E from foods like fruits and vegetables.  The cells of the body produce more powerful antioxidants like coenzyme Q10, glutathione and superoxide dismutase.

Of course, the body must be well nourished in order to produce those antioxidants.  So, eating your fruits and veggies and taking your daily multi-vitamin is important.  But, if you are really serious about how to keep skin young looking, you will apply some of those antioxidants directly.

No, you can’t grind up your multi-vitamin and mix it water to create a paste.  The particles would be too large to penetrate the skin’s cells and layers, even if you used the strongest food processor available.  It takes nanotechnology to make the particles small enough to penetrate.

With nanotechnology, we can reduce the size of the particles to the point where they will pass through the tiny gaps in the skin’s brick and mortar construction.  Nano-emulsified coenzyme Q10 has been shown to penetrate through seven of the skin’s layers, soaking up free radicals and repairing damage done by the sun.

Scientists have been investigating how to keep skin young looking for many years.  Now, they understand the causes of an aged appearance and they understand how to address those causes with topically applied creams.

Free radical damage from the sun is one of the biggest causes of cellular aging.  Inflammation plays a role.  Decreased production of collagen and elastin fibers contributes to sagging.  And, low levels of hyaluronic acid make the skin look less smooth.

Now that you know this luckily, there are creams that address all of those issues.  If you want to learn how to keep skin young looking, you should learn more about those anti-aging creams.  It will be time well spent.

To learn more about unique ingredients for healthy skin, and other incredible substances you’ve probably never heard of, visit my website today.

Rechargeable Batteries ? Looking Forward

In 2007, assistant professor Yi Cui and colleagues at Stanford University’s Department of Materials Science and Engineering discovered that using silicon nanowires as the anode in rechargeable batteries increases the volumetric charge density of the anode by up to a factor of 10. This is significant because it offers an opportunity to use new types of active components for the batteries.

The active components in a secondary cell are the chemicals that make up the positive and negative active materials, and the electrolyte. The positive and negative are made up of different materials, with the positive exhibiting a reduction potential and the negative having an oxidation potential. The sum of these potentials is the standard cell potential or voltage.

In primary cells the positive and negative electrodes are known as the cathode and anode, respectively. In rechargeable cells the positive electrode is the cathode on discharge and the anode on charge, and vice versa for the negative electrode.

Already, several alternatives to rechargeable batteries exist or are under development. For transportation, uninterruptible power supply systems and laboratories, flywheel energy storage systems store energy in a spinning rotor for reconversion to electric power when needed; such systems may be used to provide large pulses of power that would otherwise be objectionable on a common electrical grid. For uses like portable radios and flashlights, rechargeable batteries may be replaced by clockwork mechanisms or dynamos which are cranked by the user to provide power.

A future development could be ultracapacitors for transportation, using a large capacitor to store energy instead of the rechargeable battery banks used in hybrid vehicles. One drawback to capacitors compared with batteries is that the terminal voltage drops rapidly; a capacitor that has 25% of its initial energy left in it will have one-half of its initial voltage. However, there are potential benefits in cycle efficiency, lifetime, and weight compared with the rechargeable batteries system.

Rechargeable Batteries – Looking Forward

In 2007, assistant professor Yi Cui and colleagues at Stanford University’s Department of Materials Science and Engineering discovered that using silicon nanowires as the anode in rechargeable batteries increases the volumetric charge density of the anode by up to a factor of 10. This is significant because it offers an opportunity to use new types of active components for the batteries.

The active components in a secondary cell are the chemicals that make up the positive and negative active materials, and the electrolyte. The positive and negative are made up of different materials, with the positive exhibiting a reduction potential and the negative having an oxidation potential. The sum of these potentials is the standard cell potential or voltage.

In primary cells the positive and negative electrodes are known as the cathode and anode, respectively. In rechargeable cells the positive electrode is the cathode on discharge and the anode on charge, and vice versa for the negative electrode.

Already, several alternatives to rechargeable batteries exist or are under development. For transportation, uninterruptible power supply systems and laboratories, flywheel energy storage systems store energy in a spinning rotor for reconversion to electric power when needed; such systems may be used to provide large pulses of power that would otherwise be objectionable on a common electrical grid. For uses like portable radios and flashlights, rechargeable batteries may be replaced by clockwork mechanisms or dynamos which are cranked by the user to provide power.

A future development could be ultracapacitors for transportation, using a large capacitor to store energy instead of the rechargeable battery banks used in hybrid vehicles. One drawback to capacitors compared with batteries is that the terminal voltage drops rapidly; a capacitor that has 25% of its initial energy left in it will have one-half of its initial voltage. However, there are potential benefits in cycle efficiency, lifetime, and weight compared with the rechargeable batteries system.

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