ScienceIQ.com

Two Face? Absolutely!

During the Viking missions to Mars in the mid 1970s, the planet was imaged from orbit by the Viking 1 and 2 Orbiters. These spacecraft returned images of regions of the planet that, while similar to geological features on Earth, are vastly different. One of the areas viewed by the Viking 1 Orbiter as it searched for potential landing sites was a ...

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TwoFaceAbsolutely
Astronomy

It's a Supernova

Scientists have discovered that one of the brightest gamma ray bursts on record is also a supernova. It's the first direct evidence linking these two types of explosions, both triggered by the death ... Continue reading

ItsaSupernova
Biology

How Blood Clots

Scabby knees and bruised shins are as much a part of growing up as climbing trees. Minor injuries from paper cuts to skinned elbows are nothing to worry about for most people, because the blood's ... Continue reading

BloodClots
Biology

How Do Cacti Survive in That Environment?

Most plants require daily or weekly watering. Some people even give their plants extra nutrients with such products as 'Miracle Grow'. House plants may even come with directions as to how much ... Continue reading

CactiSurvive
Geology

Who Named The Cloud Types?

Clouds held a particular fascination for a young Englishman named Luke Howard (1773-1864). His father had sent him to grammar school at Burford, a village to the west of London. But Luke was more ... Continue reading

WhoNamedTheCloudTypes

Fission and Fusion

FissionandFusionIn the nuclear fission process, a heavy atomic nucleus spontaneously splits apart, releasing energy and an energetic particle, and forms two smaller atomic nuclei. While this is a normal, natural process, it is in actuality an extremely rare process. Vastly more common is the opposite process of 'fusion', in which two very light atomic nuclei fuse together to form a heavier atomic nucleus. Every star in the universe works on this principle.

In the nuclear fusion process, the product formed is a helium nucleus consisting of two protons and two neutrons. Ironically, this is the same particle emitted by many radioactive materials when they decay. To form the helium nucleus through fusion requires the joining of two deuterium nuclei. Deuterium is an isotopic form of hydrogen in which each nucleus contains both a proton and a neutron rather than just the one proton of the normal hydrogen nucleus. A single helium nucleus represents a large energy difference relative to two separate deuterium nuclei, and as one might expect, a large amount of energy is released when nuclear fusion occurs. But there is also a very large energy barrier to be overcome in order to bring the deuterium nuclei together and make them fuse. Think of it as a switch that you have to hit with a very heavy hammer in order to get the lights to come one. In this case, the 'hammer' is an atomic bomb!

To trigger the nuclear fusion reaction that is the heart of the 'hydrogen bomb' requires the deuterium mass to be impacted by an explosive force equivalent to that of a conventional atomic bomb based on nuclear fission. The result is catastrophic.