Elements of Our Everyday Life

     Of all the known elements in the universe, there is one in particular that is critical for life as we understand it—carbon. Having an atomic mass unit of 12.0107g/mol and seven isotopes₁—one of which, Carbon-12, being the basis for atomic weights—the sixth element, carbon, is the most chemically active element on the periodic table. Dr. Neil DeGrasse Tyson states, “You can make more molecules out of carbon than you can all other kinds of molecules combined₂.” Indeed, according to the U.S. Department of Energy’s NNSA (National Nuclear Security Administration, “There are close to ten million known carbon compounds; many thousands of which are vital to organic and life processes₃.” Complex organic chemistry—known as ‘the chemistry of life’—is based upon the properties, structures and reactions of carbon; it is ubiquitous. However, not only is carbon crucial for life, it has essentially become the cornerstone of modern human society through a specific set of molecules called hydrocarbons. In fact, the current global paradigm has been built around the continually accelerated usage of hydrocarbons which are, in terms of the human lifespan, relatively finite and tend to have a negative impact on the environment. So, what are hydrocarbons?

     Hydrocarbons are molecules that are composed of carbon and hydrogen, taking on the general chemical formula C_nH_2n+2. An example of a hydrocarbon is octane, C₈H₁₈, which is widely used in and a main component of gasoline. And, although various forms of these hydrocarbons comprise the edifice of our energy grid, the process by which we extract this energy—combustion—is environmentally deleterious as well as inefficient. Even with such a wide range of so-called “alternative” energy sources within our present capabilities, such as wind, wave, tidal, solar and geothermal, we seem to be intentionally ignoring these other sources for the sake of what can be called an addiction to oil. In detached ways, and this is due to a plethora of inherent inefficiencies in a fiat monetary/market system, we have inched our way toward transitioning into new methods of energy extraction; but, nothing close to the rate which is necessary to reverse the ecological degradation caused by humankind over the past century and a half. It would take an overhaul of our entire global, socioeconomic system to accomplish such a feat.

     We see $1,000,000+ windmills being constructed, just to view the entire process within the context of monetary gain and cost efficiency. Cost efficiency is simply a measure of industrial inefficiency; for, if products were designed with preservation, efficiency and sustainability in mind, massive profits simply could not be generated. This is why silicon-based solar panels, which have been around since 1954, have only recently reached an efficiency level of about 15-20%₄. However, in October 2012, researchers at Stanford University successfully built the world’s first all-carbon solar cell₅. The most promising aspect of these thin film cells is that they can be coated from solution. And, as the field of nanotechnology continues to expand exponentially, an increase in both efficiency and applications is almost inevitable.

     In terms of creating ecological imbalance, there is no greater purveyor than that of carbon. From the hydrocarbons themselves, to the greenhouse gases CO₂ and CO—produced through combustion of such hydrocarbons—carbon seems to be omnipresent. After all, it is the fourth most abundant element in the universe by mass₆. Ironically, in terms of potential for creating and maintaining ecological balance, there is no greater purveyor than that of carbon. With the introduction of this new carbon solar cell, it is only a short matter of time before we see the efficiency climb significantly from the current ‘less than 1%’.

     Another element of great significance on a cosmic scale is hydrogen. Hydrogen is the first element on the periodic table and has an atomic mass of 1.00794g/mol. Existing in nature as the gaseous diatomic molecule H₂—due to a stable electronic configuration which fills the 1s orbital and satisfies the Rule of 2 for both atoms—hydrogen is the most abundant element in the entire known universe and has been the basis of what can be termed “another form of life” for billions of years—stars.

     Stars are the nuclear furnaces of the universe, churning out all of the elements on the periodic table (aside from those created by humans in the laboratory) over millions to billions of years. The process of nuclear fusion that happens in the centers of stars is called the proton-proton chain and is responsible for the creation of different isotopes of hydrogen, helium and beryllium, depending upon the temperature₇. As stars form from giant dust clouds that are sometimes trillions of miles long, contamination or enrichment of newly formed stars from products of stars that have gone supernova leads to another process called the Carbon-Nitrogen-Oxygen (CNO) process which converts these elements into isotopes of one another₈. Fluorine is sometimes created in one of the stages of this process. But, where do the rest of the heavier elements come from?

     It turns out that the fusion of oxygen to oxygen can create elements up to sulfur-32. As the mass of stars increase, the elements eventually reach a limit to what can be fused in the center. That limit is iron. Essentially, a very high mass star will have an iron core surrounded by layers of other elements fusing₉. Eventually, these outer shells are blown off in violent supernovae and even higher elements are created through a process known as nucleosynthesis. Therefore, nearly every atom in each of our bodies was created inside, or through the death, of stars.

     Continuing that logic, every atom of carbon in hydrocarbons was created through the fusion of the other element present in hydrocarbons—hydrogen. This is why these two elements are so very important to all life processes; for, the Sun is the life-ground for all carbon-based life, and hydrogen is the life-ground of stars. It is quite astonishing how interconnected we all are to the rest of the universe. And, as we gaze out into the vastness of the cosmos, we can stand confident and fearless knowing that what is out there is already within us all; we are a part of that. Therefore, there is nothing to fear. As Carl Sagan famously put it, “We are star stuff harvesting star light₁₀.”