The Process of Coffee Decaffeination

So far, there is no method of decaffeination that can remove 100% of the caffeine from coffee. The U.S. standard – which is, by the way, a "standard" and not a law – says that a beverage may be labeled "decaffeinated" if 97% of the caffeine content has been removed. Europe generally follows a higher standard which is closer to 99%, but still not foolproof. And beyond the manufacturers’ control, brewing methods and steeping times (length of time a tea bag is left sitting in your hot water cup) drastically affect the level of caffeine that you end up consuming.

Percentages are where thinking about the actual caffeine content of different types of coffee beans, roasts and teas can be useful. For example, Arabica beans normally contain roughly one-half the caffeine of Robusta beans. So whereas a Robusta brew may have 100 mg of caffeine and its decaffeinated equivalent 3 mg, the equal serving of Arabica brew would contain about 50 mg of caffeine and 1.5 mg in the decaf version. Teas also have naturally lower caffeine content thancoffee – of any variety. Once you read about the industrial methods of extracting caffeine from a coffee bean, you may want to carefully consider the beverage products you choose.

The beverage industry is a major money making enterprise with many competing advertising messages aimed at the consumer on a daily basis. All beverages including coffees, teas, sodas and bottled water are marketed around a major ingredient – caffeine or no caffeine. In the non-caffeine market segment, consumers will notice many terms used to describe the beverages such "decaffeinated", "naturally decaffeinated", and "caffeine-free". As a general rule, beverages should only be considered "caffeine-free" if there was never any caffeine in the ingredients to begin with. This rules out all coffee beans and tea leaves because both contain caffeine in their unprocessed form. For coffee and tea lovers who do not want caffeine in their drink, they should pay attention to both natural variations in caffeine content of various teas andcoffee (some have more and some have less) as well as the physical decaffeination process used to manufacture a specific coffee or tea product.

There are currently four types of decaffeination processes: 1) solvent based; 2) charcoal or carbon filtered; 3) "supercritical" carbon dioxide; and 4) triglycerides, a process developed within the last 5 years. All of these processes are performed on greencoffee beans before they are roasted.

A point of clarification: you will read a lot about "water-based" processes, but every single method of decaffeination named above uses water in the process. One should therefore not assign any weight to the term "water processed" with one exception, which is the Swiss Water Process that is in fact a specific, patented carbon activated filter method.

Solvent based decaffeination is the earliest and most controversial way to remove caffeine from coffee or tea. Its inventor first used benzene as the separation agent. As benzene began to be recognized as a health hazard, it was replaced by TCE, another controversial industrial solvent. By the 1970’s and 1980’s, TCE was replaced by the chemical methylene chloride which has many advantages but is still suspected of having some carcinogenic risk. Today most processors use only ethyl acetate as a decaffeination solvent.

It is important to note that some producers claim ethyl acetate as "all natural" or "naturally decaffeinated" because the chemical compound does occur naturally in many fruits and vegetables. But the quantity of chemical required for industrial decaffeination means that almost 100% of the time, synthetically manufactured ethyl acetate is used. So far, there are no known health risks linked to the use of ethyl acetate in direct or indirect decaffeination methods.

Charcoal and carbon filtering processes were developed as a direct challenge to solvent-based methods. Using only water, coffee elements are extracted from the beans, filtered through carbon or charcoal to remove the caffeine, and then the extract is replaced back to the bean. The patented Swiss Water Process is touted as a superior method for preserving flavor, because it throws away the first batch of beans and uses the decaffeinatedcoffee extract to wash and filter the next batch of beans, and so forth. Basically the difference is they are not using pure water to filter the beans, they are using "flavor charged" water that is already saturated with flavor ingredients so only caffeine moves from the beans to the water. Thus there is no re-soaking or re-infusing removed flavor back into thecoffee bean, because the flavor has not been removed.

Supercritical carbon dioxide fluid has both gas-like and liquid-like physical properties. You many have also heard of superheated or liquefied gas. Supercritical fluid fills the container like a gas, but can dissolve substances like a liquid – making it an excellent agent for separating an element such as caffeine from acoffee bean. The highly pressurized carbon dioxide is forced through the beans and penetrates deeply, dissolving up to 99% of the caffeine. The carbon dioxide residue evaporates from thecoffee beans as they return to room temperature.

All of these decaffeination processes adulterate the natural coffee bean in some way because they are extracting elements from the essence of the bean or tea leaf. While some methods claim to be better or safer than others, the processes are similar, and it can be tough for the consumer to discern which actual method is being used. Decaf drinkers should read product packages carefully and possibly contact the manufacturer to ask about which method they use.

Another alternative is again, just choosing a beverage with low caffeine content to begin with. Modify your intake and brewing methods to preserve flavor while lowering your caffeine exposure. One promising development for the future is the discovery of the enzyme that produces caffeine in the coffee plant itself.

Any finally, the newest method of decaffeination uses triglycerides from spent coffee grounds to extract caffeine from raw coffee beans. The beans are soaked in a hot water solution to draw the caffeine to the surface of the beans. Then they are transferred to another container and immersed incoffee oils that were obtained from spent coffee grounds. The coffee oils contain triglycerides, which when heated for several hours at a high temperature, separate the caffeine – but supposedly not the flavor – from the beans. The beans are next separated from the oils and dried. The caffeine is removed from the oils, which are reused to decaffeinate another batch of beans. Scientists have discovered coffee varieties in Ethiopia containing a small fraction of the caffeine of traditional coffee. Further they are working on developing the enzyme into a commercial way to grow bioengineered, caffeine-free coffee. In the mean time, enjoy your coffee!