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| title | chunk | source | category | tags | date_saved | instance |
|---|---|---|---|---|---|---|
| Decaffeination | 2/2 | https://en.wikipedia.org/wiki/Decaffeination | reference | science, encyclopedia | 2026-05-05T10:47:06.751518+00:00 | kb-cron |
==== Supercritical CO2 ==== Food scientists have also turned to supercritical carbon dioxide (sCO2) as a means of decaffeination. Developed by Kurt Zosel, a scientist of the Max Planck Institute, it uses CO2 (carbon dioxide), heated and pressurised above its critical point, to extract caffeine. Green coffee beans are steamed and then added to a high pressure vessel. A mixture of water and CO2 is circulated through the vessel at 300 atm and 65 °C (149 °F). At this pressure and temperature CO2 is a supercritical fluid, with properties midway between a gas and a liquid. Caffeine dissolves into the CO2; but compounds contributing to the flavour of the brewed coffee are largely insoluble in CO2 and remain in the bean. In a separate vessel, caffeine is scrubbed from the CO2 with additional water. The CO2 is then recirculated to the pressure vessel.
=== Caffeine content of coffee ===
According to a 1979 analysis, coffee has the following caffeine content, depending on how it is prepared:
=== Caffeine content of decaffeinated coffee === To ensure product quality, manufacturers are required to test the newly decaffeinated coffee beans to make sure that caffeine concentration is relatively low. A caffeine content reduction of at least 97% is required under United States standards. There is less than 0.1% caffeine in decaffeinated coffee and less than 0.3% in decaffeinated instant coffee in Canada. Many coffee companies use high-performance liquid chromatography (HPLC) to measure how much caffeine remains in the coffee beans. However, since HPLC can be quite costly, some coffee companies are beginning to use other methods such as near-infrared (NIR) spectroscopy. Although HPLC is highly accurate, NIR spectroscopy is much faster, cheaper and overall easier to use. Lastly, another method typically used to measure the remaining caffeine includes ultraviolet–visible spectroscopy: useful for decaffeination processes that include supercritical CO2, as CO2 does not absorb in the UV-Vis range. A controlled study in 2006 at Florida State University consisting of ten samples of prepared decaffeinated coffee from coffee shops showed that some caffeine remained. Fourteen to twenty cups of such decaffeinated coffee would contain as much caffeine as one cup of regular coffee. The 473 ml (16 ounce) cups of coffee samples contained caffeine in the range of 8.6 mg to 13.9 mg. In another study of popular brands of decaf coffees, the caffeine content varied from 3 mg to 32 mg. In contrast, a 237 ml (8 ounce) cup of regular coffee contains 95–200 mg of caffeine, and a 355 ml (12 ounce) serving of Coca-Cola contains 36 mg.
== Decaffito == As of 2009, progress toward growing coffee beans that do not contain caffeine was still continuing. The term "Decaffito" has been coined to describe this type of coffee, and trademarked in Brazil. The prospect for Decaffito-type coffees was shown by the discovery of the naturally caffeine-free Coffea charrieriana variety, reported in 2004. It has a deficient caffeine synthase gene, leading it to accumulate theobromine instead of converting it to caffeine. Either this trait could be bred into other coffee plants by crossing them with C. charrieriana, or an equivalent effect could be achieved by knocking out the gene for caffeine synthase in normal coffee plants.
== Decaffeinated tea ==
Tea may also be decaffeinated, usually by using processes analogous to the direct method or the CO2 process, as described above. Oxidizing tea leaves to create black tea or oolong tea leaves from green leaves does not affect the amount of caffeine in the tea, though tea-plant subspecies (i.e. Camellia sinensis sinensis vs. Camellia sinensis assamica) may differ in natural caffeine content. Younger leaves and buds contain more caffeine by weight than older leaves and stems. Although the CO2 process is favorable because it is convenient, nonexplosive, and nontoxic, a comparison between regular and decaffeinated green teas using supercritical carbon dioxide showed that most volatile, nonpolar compounds (such as linalool and phenylacetaldehyde), green and floral flavor compounds (such as hexanal and (E)-2-hexenal), and some unknown compounds disappeared or decreased after decaffeination. In addition to CO2 process extraction, tea may be also decaffeinated using a hot water treatment. Optimal conditions are met by controlling water temperature, extraction time, and ratio of leaf to water. Temperatures of 100 °C or more, moderate extraction time of 3 minutes, and a 1:20 leaf to water weight per volume ratio removed 83% caffeine content and preserved 95% of total catechins. Catechins, a type of flavanol, contribute to the flavor of the tea and have been shown to increase the suppression of mutagens that may lead to cancer. Both coffee and tea have tannins, which are responsible for their astringent taste, but tea has around one third of the tannin content of coffee. Thus, decaffeination of tea requires more care to maintain tannin content than decaffeination of coffee in order to preserve this flavor. Preserving tannins is desirable not only because of their flavor, but also because they have been shown to have anticarcinogenic, antimutagenic, antioxidative, and antimicrobial properties. Specifically, tannins accelerate blood clotting, reduce blood pressure, decrease the serum lipid level, and modulate immunoresponses. Certain processes during normal production might help to decrease the caffeine content directly, or simply lower the rate at which it is released throughout each infusion. In China, this is evident in many cooked pu-erh teas, as well as more heavily fired Wuyi Mountain oolongs; commonly referred to as 'zhonghuo' (mid-fired) or 'zuhuo' (high-fired). A generally accepted statistic is that a cup of normal black (or red) tea contains 40–50 mg of caffeine, roughly half the content of a cup of coffee. Although a common technique of discarding a short (30 to 60 seconds) steep is believed to much reduce caffeine content of a subsequent brew at the cost of some loss of flavor, research suggests that a five-minute steep yields up to 70% of the caffeine, and a second steep has one-third the caffeine of the first (about 23% of the total caffeine in the leaves).
== See also ==
Caffeine-Free Coca-Cola Caffeine-Free Pepsi Coffee substitute Health effects of caffeine Health effects of coffee Health effects of tea Low caffeine coffee
== References ==