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]]>Me and my team did it to inspire and, more importantly, to create the tactics and details around how you, your organization, your startup can know more about start working on coffee business.
However this deck continues my tradition of training step-by-step guides that give you the exact information I’ve used to run my introduction to coffee class. That includes references like :
Coffee Origins . Biology of coffee plant . Coffee’s Growing Region . Coffee’s Journey . Current Coffee Industry . Coffee origin . How coffee is traded . Species . Varieties . cultivar . Harvesting . Processing . Processing Flavor Description . Quality Control . Roast Process . effect on taste . Roasting graph . Different roast style . storage . Coffee freshness . Humans Senses . Taste . SCA Flavor Wheel . Effect of geographical position on coffee flavor . Cupping . How to do coffee cupping . Brew methods . Brewing parameters . Filter material . Coffee extraction definition . Water Quality . What is Specialty Coffee / Organizations in Specialty Coffee / waves /.
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]]>general
Wet processing of coffee often includes a fermentation step, cocoa always does and tea processing has a step that is sometimes called ‘fermentation’. In food production there are many fermentations that confer nutritional, taste, stability or all of these benefits on raw materials. Sauerkraut, yoghurt, salami, tempe, uji, soya sauce, beer, and cheese are a few examples of scores of food fermentations known around the world.
Coffee fermentation, as we will see, is conducted for rather different reasons. The term ‘fermentation’ represents microbial growth as it occurs on any suitable substrate. In fact, in the early days of microbiology, the organisms that grew to spoil food were originally called ‘ferments’, rather than ‘microorganisms’, hence their growth was termed ‘fermentation’.
A second, narrower sense of ‘fermentation’ is often used in microbiology, which we will not use in this discussion: microbial activity in the absence, or near absence, of oxygen. However, it is worth remembering that vigorous microbial metabolism often depletes oxygen (and so augments CO2) thus oxygen limitation is usually an important aspect of food fermentations. It is an important factor in the selection of a fermentation community from the initial community of microorganisms. Bacteriologists also speak of fermentative organisms – microbes that do not require oxygen for respiration and oxidative species that do require oxygen for growth. In referring to organisms, we will use these bacteriological terms.
The so-called fermentation of tea raises an important aspect of some food fermentations. The changes wrought in tea by ‘cutting, tearing, curling’ (CTC), followed by aeration are produced by plant enzymes, not microbial activity. There is often a potential ambiguity in the roles of microbial and plant metabolism in processing systems since often both kinds of organisms are simultaneously active at some time during the process. Cocoa fermentation is required for flavour development although it also aids separation of seed from fruit tissue. Coffee fermentation, though it may have an impact on flavour development, is not required for flavour development and is conducted essentially to aid a similar separation of tissues.
Microorganisms occur naturally on and in the coffee fruit in increasingly large numbers as the fruit matures. The seeds themselves become active with maturity and a proportion of seeds will have undergone the early changes associated with germination by the stage of full ripeness. The fruit itself has no capacity to store, unlike apples and oranges, for example. Resident micro-organisms become active soon after harvest and signs of (unintended) fermentation can be measured soon after harvest. The object of our discussion here is principally the scheduled fermentation used to degrade the mucilaginous mesocarp tissue of the fruit.
Structure of the Coffee Fruit
The product of coffee are the seeds which are produced in small cherry-like fruits, normally in pairs. Of particular significance in understanding coffee processing are the three tissues of the fruit: the epidermis (or skin); the mesocarp (or mucilage) and the inner integument (or parch).
The epidermis is typical of plants, comprising a layer of small cells, including stomata, their cell walls impregnated with suberin, a water impermeable wax. Beneath this is the mesocarp which consists of many layers of parenchymatous cells – undifferentiated thin walled cells and which, in the ripe fruit, are large with large vacuoles. The inner integument, which is tightly adpressed to the seeds, is a very tough and relatively inelastic layer no more than two or three cells thick but comprising cells with considerable secondary thickening, i.e. it is essentially woody. Xylem tissue, presumably once connected to the funiculus (the tissue that connects the seed to its nutritional supply during development), can be easily seen in the integument by direct observation, running parallel to the surface of the tissue.
Before ripeness, the skin, mesocarp and parch form a tough and tightly adpressed covering to the seeds which are relatively soft at this stage. Attempts to remove the seeds at this point will invariably break the seeds. When ripeness is reached, the mesocarp becomes soft (hence the term mucilage), and the seeds relatively hard. If mechanical shear is applied now, the mesocarp splits to produce one fraction of skins with some mucilage and a second fraction of seeds tightly covered in their integument (parch), which is covered in a fairly thick layer of mucilage. this second fraction that is fermented to enable removal of the mucilage from the seeds.
It can be that the mesocarp of robusta fruit is thinner than that of arabica. It is, however, tougher and more difficult to remove from the parch. The mesocarp adhering to the parch is chemically quite different to that adhering to the skin. It lacks the characteristic anti-nutritional compounds such as tannins, free phenolics, caffeine and other alkaloids that make skins refractile even in composting. A tonne of ripe arabica cherry yields about 120kg of mucilage adhering to the beans. About half of the 17kg of the dry mass of this mucilage is sugars or some 8.5kg of sugars. This is the source of fermentable carbohydrate for the coffee fermentation. There are also minerals, particularly Ca, K and P, and amino acids present.
Pectic substances amount to about 35% of the dry mass of the bean-associated mucilage. They comprise essentially polygalacturonic acid chains (covalent bonds typical of all polysaccharides) that are cross-linked, via Ca+2 ions through the carboxylic groups of the uronic acids. As will be discussed below, the esther part of the carboxylic group and the glycosidic bonds of the chains are susceptible to attack from enzymes.
Wet Processing and Dry Processing:
Coffee must be dried in order to stabilise it and preserve quality. Wet processing refers to various methods where the seeds are mechanically separated from the skin of the fresh fruit (pulping) before drying and may or may not include a fermentation step. Dry processing refers to methods where the fruit is either dried directly or is disrupted, but the seeds not separated from the fruit tissues, then immediately dried. The decision as to which method to employ is based on economic considerations. Washed coffee commands a higher price, but is more expensive to produce.
A large proportion of arabica coffee is processed by the ‘wet method’ and a high proportion of this has a fermentation step in it. The market for washed robusta is limited, and the premium offered above dry processed robusta is small. Therefore, only a small proportion of robusta coffee is processed by the wet method, the bulk of this in India.
Capital costs for wet processing are high. Power, provided by mains electricity, petroleum powered generator or direct drive arrangements is required for even moderate sized operations. A good water source and fairly well-designed plumbing is also required. A facility to house equipment and various sealed channels and tanks are also necessary. The equipment comprises a pulper as a minimum, and typically includes a hopper, siphon tank, post pulping screen, washer or washing channels and skin-drying screens.
Operational costs are also higher for wet processing. Harvesting is particularly expensive because it requires the very labour-intensive selective harvesting system – only ripe cherries can be pulped. This is beginning to change due to new equipment that can accept (but not pulp) immature cherries. Further costs accrue because cherries affected by coffee berry disease, immature or over ripe cherries must be separated and sold as low grades, returning a low price.
There are generic differences in taste attributes between washed and natural coffees and both are required for different market segments: wet processed coffee yields a ‘softer’ cup with less body and higher acidity while the ‘arabica naturals’ excel in their body and bitterness while lacking acidity. Within the classification of washed coffees there are two commercial market segments: ‘Colombian milds’ and ‘other milds’, a distinction that is delimited by origin. Either may or may not be fermented and the ‘other milds’ characteristically have more body and less acidity than ‘Colombian milds’.
Coffee Fermentation:
Coffee is fermented, as mentioned above, to ease the removal of a layer of mucilage from the seed/inner integument to which it adheres. This is not to say there are no taste implications to this step. In contrast to coffee, the fermentation of cocoa is required to develop the flavour of the product though much of this is apparently accomplished by cocoa enzymes, rather than microbial activity. In coffee too, it has long been held that fermentation has a beneficial effect on flavour but lately, this has been disputed and many quality experts now accept the contention that mechanically washed coffee (with no fermentation) can be of comparable quality to the fermented product. What is beyond dispute is that badly conducted fermentation can result in disastrous losses in quality.
In general coffee fermentation is conducted as ‘dry fermentation’ where the mass of mucilage and parchments are not covered with water. The temperature of either of these processes is scarcely raised above ambient temperature reflecting the lack of oxygen diffusion to the heart of the mass. In contrast, fresh cherries held in woven sacks, an arrangement that has about 50% space, can heat to over 50OC within 36h. From a taste quality point of view, the fermentation step and operations either side of it (pulping and washing) are said to require conformance to certain criteria.
Firstly, the fermentation mass must comprise uniformly parchment coffee with a minimum of crushed or naked beans, skins and un-pulped coffee. Crushed and naked beans indicate beans with severe insect damage and/or a pulping machine being set too narrow. Presence of skins suggest the pulping machine is in need of maintenance and/or the water feed was too low. Un-pulped beans suggest that the pulper was set too wide and/or the removal of dried fruits has been ineffective.
Secondly, the fermentation must be concluded as soon as possible after sufficient mucilage degradation has been accomplished. This is ascertained by rubbing the parchment between your fingers to note whether the grittiness of the parchment surface can yet be felt.
Thirdly, after washing, mucilage must be completely removed from the parch before drying. Curiously, a product called descascado, produced with no attempt to remove mucilage, being pulped and immediately dried, can be a coffee of the highest quality.
The most important of these conditions is the temperature and the length of the fermentation. As mentioned above, coffee fermentation is not significantly self- heating so prevailing climatic conditions control temperature. The period of fermentation, in practice, can only be concluded when it is possible to take the coffee to the next two steps: washing and either soaking or drying. This normally occurs first thing in the morning since the afternoon and evening is reserved for pulping operations. Given that pulping always takes place in the late afternoon through the evening and requires everyone’s attention, fermentation periods will tend to be about 18h, 40h or 64h. Robusta usually requires at least one day more than arabica.
Microbiological aspects:
The outcome of a process like fermentation is a consequence of what goes in and what conditions are experienced during the fermentation. We have seen that there is about 8.5 kg of sugar in the pulp of 568kg of pulped coffee and another 6kg of pectic substances. The balance of the 17kg of dry matter is ash, amino acids, cellulose and so forth. Most of the organisms are provided by the mucilage community with some from the processing water and incidental skins, etc.
However, the conditions, as they develop, provide exceptionally powerful selective pressure toward fermentative organisms that can thrive at low pH. The fresh mucilage has a pH of about 6.5. This falls rapidly to a minimum of about 4.1 to 4.3. Although data is lacking, it is clear that oxygen tension falls with the fall in pH, both concomitant with growth. Typical of food fermentations, the ‘wild’ microbial flora of the raw material changes quickly and completely to species that were present, but rare, in the fruit-inhabiting community.
Studies of ‘wild’ fermentations are very arduous to conduct because of the sheer numbers of organisms and taxa and the difficulties in accurate enumeration and identification of them. The nomenclatural problems of synonymy and teloemorph/anamorph names make comparing different studies difficult. New methods based on DNA PCR amplification and gel electrophoresis which allows direct analysis of the fermentation liquor without an isolation step, may provide a means to solve these severe practical problems in future.
In general, the fermentation can be characterized as a mixed yeast/bacterial fermentation. Kloekera apiculata (=Hansenispore apiculata = Saccharomyces apiculatus) and Hansenispore uvarum are reported to dominate the yeast population with other yeasts such as Pichia kluyveri (=P. fermentans) and Kluyveromyces marxianus (=Candida kefir = C. bulgericus). The yeast species are fermentative and the dominant species share the characteristic of only assimilating and fermenting glucose amongst the usual sugars tested to identify yeasts.
The bacterial side of the fermentation is conducted by lactic acid bacteria, some Enterobacteriaceae and Bacillus. The most common bacteria to produce pectolytic enzymes are Pseudomonas (P. fluorescens, for example) and Erwinia (E. carotovora, for example). Of these only Erwinia is fermentative and, in fact, the presence of Pseudomonas is difficult to demonstrate in fermentation liquors. In general, the lactic acid bacteria have been reported to be more numerous than the Enterobacteriaceae.
Analysis of several fermentations under the project “Enhancement of Coffee Quality Through the Prevention of Mould Formation” has shown that the balance between yeasts and bacteria can vary widely, such that some are primarily bacterial and others dominated by yeast. It is not clear how the outcomes of these two types differ, or why it should differ.
The conditions of low oxygen tension and high water activity dictates that the oxidative, mesophilic species of Aspergillus capable of OTA production will not thrive during fermentation. In laboratory studies, large numbers of spores, introduced into the fermentation mass at the beginning of fermentation did not result in any OTA appearing in the beans and the organism (A. ochraceus) could not be recovered from the beans after drying.
this test is only valid for models where spores, let us say from the fruit skins or soil contamination, are the source of the OTA producer. In fact, a proportion of beans harbour these fungi, infected before harvest, and there is some evidence to suggest that fermentation can kill them in the beans. However it is clear that fermentation does not always do so. In other tests where pulping was delayed for up to six days after harvest, the protective effect of fermentation against OTA accumulation was not observed. This could be interpreted as there being some threshold biomass above which the mesophilic fungi can survive the fermentation well.
The presence of skins with the parchment is unlikely to affect the fermentation course with respect to OTA production. The presence of dry cherries, which go through the pulper due to their small size, present a different scenario. If we assume a greater development of OTA-producers could have occurred under the extended period of oxidative and mesohydric conditions of this material, the fermentation would not protect and significant OTA production could occur if not during the fermentation, then later during drying.
There are three classes of Pectolytic enzymes. Plants and fungi produce pectin esterases which remove methoxy groups of the uronic acids revealing carboxylic groups through which Ca+2 coordinates the chains. Certain fungi also can produce Pectin lyase, an enzyme that attacks the 1,4 glycosidic links of fully esterified (methoxylated) chains. Lastly, Polygalacturonase is produced by certain bacteria and it also attacks the glycosidic links but only of partially de-esterified chains or segments. The oxidative yeast Cryptococcus is common in the fruit and it is reported to be pectolytic but numerous isolates from coffee have been checked without a positive result. A few Candida species are also reported to liquefy Ca- pectate.
The role of microorganisms in taste defects of wet processed coffee is a matter of debate. Of the numerous defects often attributed to problems during fermentation, the three most serious are ‘fermented taste’, ‘sour’ and stinkers. But because fermentation can occur in the intact fruit, especially if harvested and not processed expeditiously, the same defects can arise in natural coffee and, by extension, in wet processed coffee where the fault was actually elsewhere than the fermentation step.
A fermented taste has fruity aldehyde tones; sour is likened to onion; stinker is a powerful foul taste, and a single stinker bean can effect several kilograms of product. Stinker beans have been attributed to the growth of Bacillus brevis or high levels of lactic acid bacteria and maybe fairly specifically associated with derivatives of methyl-butanoic acid, cyclohexanoic acid esters and S-containing organic compounds. Some compounds that can be traced to a defect also indicate the source where few organisms produce the compound. Earthy and mouldy odour can be attributed principally to 2-methyl-isoborneol and geosmin, respectively. These compounds are produced notably by species of Eurotium, a few other moulds and some actinomycetes.
Soaking:
In some processing chains, whether or not fermentation has been conducted, a soaking step is sometimes applied. This is sometimes called secondary fermentation where a fermentation step is included in the process or fermentation where mechanical mucilage removal has been used. After mucilage removal the parchments are held under water for a period from overnight up to, rarely, 48h. The principle effect is to cause the beans to become more uniformly dark blue- green, a desirable physical character that itself has no taste implication. The colour is the same as that generated by the hydrated bean in response to physical injury, say damage by a coffee berry borer or cutting with a scalpel. The colour is likely to be a hydrolysis reaction akin to the chlorogenic acid reaction – it is not chlorophyll production.
Some authorities claim that soaking removes or reduces any harsh ‘edge’ the cup may have but, if true, it is unclear whether this is due to leaching (some slight leaching has been reported), or the metabolism of the seeds in essentially anoxic conditions. For coffee without this ‘edge’ there is no change in cup quality for up to 7 days, according to one study. The harshness is usually attributed to phenolic compounds so the implication would be that, through one mechanism or another, certain phenolic compounds are removed or altered.
After washing of the parchments, considerable yeast and bacteria remain on the surface and, with the yeasts, even in the bean tissue. However, there is very little substrate for microbial growth so metabolically, this period under water, is quiescent. Short periods of soaking do not seem to be associated with flavour defects outside of the use of tainted water for the soaking.
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]]>Agricultural practices should preserve the soil fertility, which is the wealth of coffee growers. If possible increase the organic matter in the soil to promote the microbial life and the exchange capacity.
Whenever a soil is destroy it, It is observed that the coffee quality is affected therefore by contrast coffee trees. It will be healthier on a soil rich in active organic matter. They will have a better leaf area-to-fruit ratio leading to a better quality.
Soil is the main reservoir of mineral nutrients for plants. Roots grow and absorb water and nutrients according to the physical, chemical, and biological properties of the soil .
For most regions worldwide where coffee is cultivated. the nutritional reservoirs in soil are not sufficient to completely cover the coffee plants’ demand. it is necessary to continue ousel supply the soil in a balanced way with sufficient amounts of organic and inorganic fertilizers.
Fertilization and Coffee Quality
fertilization does influence this chemical effect and due to the final coffee quality in the cup. Among the macronutrients, those containing nitrogen and potassium are the most predominant in the bean, usually followed by calcium, magnesium, phosphorus, and sulfur. The effect of iron and manganese make it to be higher than zinc.
Soil fertility
Possible effect on cup quality , Most acidic coffee are produced on volcanic soils.
Fertilization
Reduction in percentage of hollowed fruits , Chemical fertilization does not affect cup quality, Breaking down fertilization applications does not affect cup quality , Fertilization does not affect cup quality
Nitrogen fertilization
Fertilization with nitrocalcium and ammonium nitrate produced lower sensory quality. The higher dosage of ammonium sulfate had negative effects on chemical composition and bean quality , Nitrogen fertilization increased bean N content and affected negatively cup quality
Phosphorus fertilization
Cup quality was negatively affected by the omission of phosphor in the fertilization.
Potassium fertilization
High potassium-K dosage reduced boron and Zinc in the bean. Excessive dosage of that reduced quality in inconsistent manner. , Excess of potassium can induce Mg deficiencies and negatively affect coffee quality , Bean quality improved with dosage.
Micronutrients fertilization
Zinc supply positively affected bean quality in terms of less percentage of medium and small size beans. Lower CBB infestation, lower potassium leaching and electric conductivity.
Higher contents of zinc and Chlorogenic , higher antioxidant activities , Cup quality is not affected by using two sources of Micronutrients .
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]]>There are many factors that make coffee valuable to consumers and one of them is shade effect of growing on coffee quality. Shade matters to some from an environmental perspective; others because they feel it influences the flavor. What I actually know about these important issues is :
The good news is, much research has been done on the ecological and economic impacts of shade-grown coffee. Sadly, there is far less information available on how this influences cup quality. When we hear the term “shade-grown” coffee we many imagine a pristine ecosystem where coffee just happens to be planted and coffee farmer happen to be walking around in the woods picking the beautifully ripe coffee they stumble upon. This romantic vision is rare in the coffee industry. There are, however, varying definitions and variations of forested coffee and agroforestry to consider when thinking of purchasing or promoting such a coffee.
Trees and agroforestry can provide environmental advantages to the planet, and simultaneously in coffee production. Trees act as carbon sinks in the landscape, make oxygen, save water, and provide a myriad of other benefits to the local microclimate and ecosystem. Trees provide the ecosystem with structural and chemical resources. Their roots help prevent erosion. They offer the soil much-needed nutrients from their fallen litter, and certain species can fix nitrogen from the air.
Trees act as buffers to the coffee microclimate. That means that they can act as insulators for the understory, where coffee grows. They can both protect coffee from frost as well as cool the microclimate during very warm weather. Another large way that trees regulate microclimate conditions is through holding moisture in the ecosystem, leaving more water in the soil and therefore theoretically available to coffee plants. There is also evidence that tree cover reduces the leaching of nitrogen from the coffee.
There is a large body of literature supporting the idea that when shade is added to a coffee-growing system, the biodiversity of the ecosystem increases. Here we should stop, and remember that biodiversity is an important intrinsic value. It is a choice to recognize and care about biodiversity. While many of us hold this value, the challenge is to quantify the value of it. How much “better” is a coffee that is produced in a highly diverse environment? Our community faces this challenge daily.
What about flavor: can we taste shade-grown coffee?How does it impact the coffee quality? The answer varies depending on the individual situation. What we do know is that generally, the smaller coffee yield under shading leads to fewer, larger coffee fruits. Also, there is evidence that shade-grown coffee seeds have higher sugar and lipid contents than sun-grown coffee, which may increase the cup quality of coffees. Multiple studies have found that the acidity and body of brewed low-altitude coffee was improved by shading. They suggested that a lower growing temperature (provided by shade) produced a more uniform ripening of berries, which led a better quality cup. However, there are also conflicting studies that have found no perceivable difference in quality. What is the problem here? In the end, unless we understand the biochemistry of fruit ripening time and how this directly affects the chemical composition of coffee seeds and link this to repeatable and consistent flavor differences, it is impossible to say with certainty what is going on. That’s right folks—here is another example of why we reach this same conclusion again and again: more research is needed to help fully understand why coffee tastes the way it does!
Unfortunately, there can also be true drawbacks to shade-grown coffee. In many situations, shade lowers coffee yield, delays ripening, and is more labor-intensive to harvest. These are luxuries that not all producers, as people who must balance costs and benefits, can choose. Any value or perception thereof must make business sense. Fortunately, some farms that use agroforestry can benefit from pricing incentives offered by certification programs. However, the reality is, that the value of shade coffee is not always translated into farmer benefit.
How does it impact the coffee quality?
Where does this leave us? Certainly, flavor alone is not an indicator of whether or not a coffee was shade-grown. Great-tasting specialty coffee can be produced using many/any/all/unknown production strategies. There are real ecological benefits of shade-growing coffee, and there may be quality benefits too. However, if we seek to support this method of coffee growing, we must recognize and value it for its own sake.
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Coffee from Al-Mokha began to be referred to simply as Mocha coffee, a name originally having little to do with the chocolatey coffee drink you can buy today. (Mocha is also used to refer to a coffee varietyoriginating from Yemen, one that the SCA describes as “genetically very close to Bourbon.”)
Yemen coffee has a distinct flavor and aroma. It’s complex earthiness often holds tones of dried fruit, partly due to being dried with the fruit husk. This Arabian Yemen coffee also carries notes of chocolate, cinnamon, cardamom or tobacco. The strongest of these notes is chocolate, which might account for the modern use of the word “Mocha” in association with Yemen coffee.
How It’ Grown ?
Yemen coffee farms are typically small and on the wilder side, with farmers hand-picking the coffee cherries from ancient varieties of Arabica plants growing on gorgeous, terraced mountainsides. The microclimate has produced drought-resistant coffee plantsthat create very unique, complex-tasting coffee beans with that iconic chocolate flavor The coffee is typically harvested between November and December and is sun-dried, often right on the rooftops of the farmers’ houses! It’s an easy process in the bright and hot Yemeni climate. The leftover cherry husks are also used to create qishr(the local brand of cascara)
Sanani Coffee
First, we have the Sanani variety, which comes from various coffee plants grown in the regions west of the capital city of Sana’a. This region tends to include some crops grown at lower altitudes, and can, therefore, be of lower quality. Beans from this region have a balanced and fruity flavor profile, a medium body, and typically exhibit less acidity than other Yemeni coffees.
Hirazi Coffee
Hirazi coffee also comes from the western regions of the nation, located a couple mountain ranges west of the capital of Sana’a. This coffee tends to be light and fruity, with a winey acidity.
Ismaili Coffee
One of the few categorized ancient coffee tree varieties of Yemen, Ismaili is the name of a coffee plant varietal. Typically grown in central Yemen, it yields a unique, high-quality, pea-like coffee bean that tends to be bright and berryish, though this brightness can be muted. This tree/region name overlap can lead to some confusion regarding whether a particular coffee with this name comes from the region itself, or from a tree of that variety
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]]>Coffee trees are pruned short to conserve their energy and aid in harvesting, but can grow to more than 30 feet (9 meters) high. Each tree is covered with green, waxy leaves growing opposite each other in pairs. Coffee cherries grow along the branches. Because it grows in a continuous cycle, it’s not unusual to see flowers, green fruit and ripe fruit simultaneously on a single tree. It takes nearly a year for a cherry to mature after first flowering, and about 5 years of growth to reach full fruit production. While coffee plants can live up to 100 years, they are generally the most productive between the ages of 7 and 20. Proper care can maintain and even increase their output over the years, depending on the variety. The average coffee tree produces 10 pounds of coffee cherry per year, or 2 pounds of green beans. All commercially grown coffee is from a region of the world called the Coffee Belt. The trees grow best in rich soil, with mild temperatures, frequent rain and shaded sun.
Botanical classification
Coffee traces its origin to a genus of plants known as Coffea. Within the genus there are over 500 genera and 6,000 species of tropical trees and shrubs. Experts estimate that there are anywhere from 25 to 100 species of coffee plants. The genus was first described in the 18th century by the Swedish botanist. Botanists have disagreed ever since on the exact classification, since coffee plants can range widely. They can be small shrubs to tall trees, with leaves from one to 16 inches in size, and in colors from purple or yellow to the predominant dark green.
In the commercial coffee industry, there are two important coffee species — Arabica and Robusta.
Coffea Arabica — C. Arabica
Varieties: Bourbon, Typica, Caturra, Mundo Novo, Tico, San Ramon, Jamaican Blue Mountain
Coffea Arabica is descended from the original coffee trees discovered in Ethiopia. These trees produce a fine, mild, aromatic coffee and represent approximately 70% of the world’s coffee production. The beans are flatter and more elongated than Robusta and lower in caffeine.
On the world market, Arabica coffees bring the highest prices. The better Arabicas are high grown coffees — generally grown between 2,000 to 6,000 feet (610 to 1830 meters) above sea level — though optimal altitude varies with proximity to the equator. The most important factor is that temperatures must remain mild, ideally between 59 – 75 degrees Fahrenheit, with about 60 inches of rainfall a year. The trees are hearty, but a heavy frost will kill them. Arabica trees are costly to cultivate because the ideal terrain tends to be steep and access is difficult. Also, because the trees are more disease-prone than Robusta, they require additional care and attention.
Coffea canephora — C. canephora var. Robusta
Variety: Robusta is a one canphora variety
Most of the world’s Robusta is grown in Central and Western Africa, parts of Southeast Asia, including Indonesia and Vietnam, and in Brazil. Production of Robusta is increasing, though it accounts for only about 30% of the world market. Robusta is primarily used in blends and for instant coffees. The Robusta bean itself tends to be slightly rounder and smaller than an Arabica bean. The Robusta tree is heartier and more resistant to disease and parasites, which makes it easier and cheaper to cultivate. It also has the advantage of being able to withstand warmer climates, preferring constant temperatures between 75 and 85 degrees Fahrenheit, which enables it to grow at far lower altitudes than Arabica. It requires about 60 inches of rainfall a year, and cannot withstand frost. Compared with Arabica, Robusta beans produce a coffee which has a distinctive taste and about 50-60% more caffeine.
The Anatomy of a Coffee Cherry
The beans you brew are actually the processed and roasted seeds from a fruit, which is called a coffee cherry. The coffee cherry’s outer skin is called the exocarp. Beneath it is the mesocarp, a thin layer of pulp, followed by a slimy layer called the parenchyma. The beans themselves are covered in a paper-like envelope named the endocarp, more commonly referred to as the parchment. Inside the parchment, side-by-side, lie two beans, each covered separately by yet another thin membrane. The biological name for this seed skin is the spermoderm, but it is generally referred to in the coffee trade as the silver skin.
In about 5% of the world’s coffee, there is only one bean inside the cherry. This is called a peaberry (or a caracol, or “snail” in Spanish), and it is a natural mutation. Some people believe that peaberries are actually sweeter and more flavorful than standard beans, so they are sometimes manually sorted out for special sale.
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The beans we roast, grind, and brew to make coffee are the seeds of a fruit. The coffee plant produces coffee cherries, and the beans are the seeds inside. Coffee trees can naturally grow to over 30 ft/9 m. But producers prune and stump plants short to conserve the plants’ energy and to help harvesting. Smaller trees have better yield and quality in a limited space. Each tree is covered with green, waxy leaves that grow in pairs and coffee cherries grow along its branches. Depending on the variety, it takes three to four years for a coffee plant to produce fruit. The National Coffee Association USA states that the average coffee tree produces 10 lbs. of coffee cherry per year, which results in around 2 lbs of green beans. But there are different varieties of coffee and their beans have many different characteristics. Size, flavor, and disease resistance vary, among other factors. beans, which are the unroasted seeds from inside the ripe coffee cherry. Beneath the cherry skin is a thin layer called the mesocarp, more commonly known as the pulp. Mucilage is the inner layer of the pulp. There’s also a layer of pectin underneath the mucilage. These layers are full of sugars, which are important during the fermentation process. Then we reach the coffee seeds, which are technically called the endosperm but that we know better as beans. There are usually two beans in a coffee cherry, each of which is covered by a thin epidermis known as the silver skin and a papery hull that we call parchment (technically the endocarp). The parchment is usually removed in hulling, which is the first step in the dry milling process. Machines or millstones are used to remove any remaining fruit and the dried parchment from the beans. But sometimes green beans are sold with this layer intact as parchment coffee. The silver skin is a group of sclerenchyma cells that are strongly attached to the beans. These cells form to support and protect the seed. They come off during roasting, when they are known as chaff.
A coffee cherry’s skin is called the exocarp. It is green until it ripens to a bright red, yellow, orange, or even pink, depending on variety. Green coffee cherries shouldn’t be confused with green coffee.
Sometimes there is just one seed inside a coffee cherry and it is rounder and larger that usual. This happens in about 5% of coffee cherries and the beans are known as peaberries. Peaberries can be an anatomical variation of the plant or they can form when there is insufficient pollination and one ovule isn’t fertilized. Sometimes the seed simply fails to grow, whether due to genetic causes or environmental conditions. Peaberries usually occur in the parts of the coffee plant that are exposed to severe weather conditions. There is some debate over whether peaberries have a sweeter and more desirable flavor and they are sometimes sold at a premium. Regardless of whether you think they taste different, their rounded shape allows for better rolling in the roasting drum. So it’s best to keep them apart from other beans to avoid an inconsistent roast. Coffee cherry skin and fruit is usually discarded, but sometimes they are dried to make cascara for tea and other products. It is difficult to remove skin and mucilage from coffee beans and different processing methods have developed to do so. Each method has an effect on the flavor and profile of the final coffee. For example, washed coffee has all of the fruit flesh removed before drying. But in natural coffee the fruit flesh is removed after drying. In honey and pulped natural processing, the skin and sometimes part of the mucilage is removed before drying but the remaining mucilage and other layers are removed after. Leaving the mucilage on results in sweeter coffee with more body. It’s easier to understand why if we compare both dry and wet post-harvest processes. When coffee cherries are taken from the branch, they start to germinate. This uses the sugar in the seed. Germination stops when drying begins. Natural processed coffees go to the drying terrace earlier than pulped naturals or washed coffees. Because of this, more sugars remain in the naturals and you end up with a sweeter bean. Washed coffees have clean, more consistent flavors that can show off a lot of acidity. Natural coffees have a lot more fruitiness, sweetness, and body. The sugars of the mucilage also ferment during both dry and wet processing, and this has an impact on the final flavor. Without careful monitoring and consistent drying, the unpredictable process of fermentation can undesirable qualities. Understanding the basics of the coffee cherry can help you better understand production, processing, and roasting. Next time you are choosing between a natural processed and washed coffee, you can have more confidence in knowing what that means and its impact on your cup.
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]]>Why Are Coffee Varieties Important?
How important coffee varieties are depends on your role in the coffee supply chain: producer, barista, roaster, consumer, If you’re a consumer, you might be wondering why you really need to learn another set of labels for your coffee. Is the variety really that important, compared to the country of origin, roast level, and processing method? And if it is important, why do only some coffee bags tell you about it? The simple answer is that coffee varieties can affect the flavour of the coffee. Some, like Bourbon, are known for their sweet taste. Others, like Gesha/Geisha, are known for tea-like qualities. But coffee flavour isn’t just about the variety: it’s also about the growing conditions, processing, and more. The uniqueness of a high-quality coffee is part of what makes this beverage so wonderful. Roasters, you need to know about varieties because they don’t just affect the flavour profile – they also affect how you roast. Different beans will have different sizes: Maragogype is famously large, while Mokka is tiny. And since roasting is a physical transformation, how heat is transferred throughout the bean is of key importance. You need to understand the physical makeup of your coffee (especially if you’re blending). And producers, varieties are of critical importance to you. Your choice will affect the flavour profile and potential cup score, the hardiness of the plant and its resistance to disease, its productivity, which altitude and temperature it grows at best, and more. Another reason to care about varieties is that Arabica coffee has a worryingly low genetic diversity. This means it is more susceptible to disease and climate change – and could even theoretically become extinct in the future. Creating and/or finding more genetic variety is of key importance right now.
Species, Variety, Cultivar They are many different species of coffee – over 100, according to World Coffee Research (WCR) – but the main three are Arabica, Robusta, and Liberica. Specialty coffee shops rarely sell anything but Arabica, shunning Robusta for its harsher, more bitter taste – although some shops are making the case for Fine Robustas. Liberica is usually only consumed in the Philippines. The category below “species”, when describing plants, is “variety”. Varieties refer to different variations within the species. For example, Caturra is a variety of Arabica while Nganda is a variety of Robusta. As for a cultivar, that’s a coffee variety that has been created by humans in an agricultural setting. Another point that confuses many people is the difference between varietal and variety. Simply put, “variety” is a noun and “varietal” is an adjective. However, because language is almost as complex as coffee genetics, it’s possible to use “varietal” in a way that acts as a noun when discussing the coffee product rather than the plant (something called nominalisation). But this is an article about coffee, not linguistics: it’s enough to say that the differences between “varietal” and “variety” are just grammatical. There are many coffee varieties around the world, and we couldn’t hope to cover all of them in just one article. However, we’re going to take a quick look at some of the most famous or noteworthy Arabica varieties.
Typica
Typica coffee is one of the earliest and most important coffee varieties, having been around for centuries and engendered numerous others. Notable Typica varieties include Java, Maragogype, and Timor Hybrid. You’ll find this plant being farmed in Central America, Jamaica, and Asia. The WCR label it as low-yield, high-quality, and susceptible to rust and pests. It’s often described as having a clean, sweet acidity.
Bourbon
A natural mutation of Typica, Bourbon is a high-quality, medium-yield coffee known for its sweet taste. It has, however, low resistance to leaf rust, coffee berry borer, and other diseases and pests. It’s commonly grown in Burundi and Rwanda, as well as throughout Latin America. Why should you know about Bourbon? For the same reasons why you should know about Typica: its early appearance in the “coffee variety tree” makes it a common variety that has also engendered numerous others.
Ethiopian Heirloom
While most Arabica coffee varieties come from Typica or Bourbon, coffee originally comes from Ethiopia – and Kew Gardens have established that the country holds 95% of coffee’s genetic diversity. When you see “Ethiopian Heirloom” written on a bag of coffee, it means that it was probably grown wild or in a lightly cultivated garden.
Timor Hybrid
Timor Hybrid is a controversial coffee, since it’s a (spontaneous) Arabica-Robusta hybrid. Robusta is a more, well, robust coffee species: it offers hardiness and resistance to coffee leaf rust in exchange for a less appealing flavour and aroma profile. As a result, this unique coffee has been used in many cultivars, particularly Catimors and Sarchimors. Catimors are a group of Caturra and Timor Hybrid crosses, Sarchimors a group of Villa Sarchi and Timor Hybrid crosses. Examples of these include Castillo, Colombia, and Marsellesa.Specialty coffee buyers can be wary of any plant with a Timor Hybrid parentage – but some producers, especially those at lower altitudes where coffee leaf rust is more likely, believe less risk is worth a potentially lower cup quality and price.
Gesha/Geisha
Gesha/Geisha originated in the village of Gesha, Ethiopia, but remained under the radar until 2003 in Panama. Since then, Panamanian Geisha has become one of the industry’s most-famous coffees. With most coffee championship finalists using it. it’s become a byword for excellence – and exclusivity. It has a distinctive profile: tea-like with a jasmine aroma, orange blossom and bergamot notes, and delicate florals. As for the plant, it grows best at high altitudes (WCR recommend above 1,400 m.a.s.l.), is low-yielding, and can be delicate. While it has earned high prices at auction, there have been horror stories of producers growing it outside of Panama only to see their plants die in incompatible climates and soil.
F1 Hybrids
F1 hybrids are a new generation of coffee varieties that have the potential to be high-quality, rust-resistant, and high-yielding. They are typically mass-produced in advanced nurseries. Notable F1 hybrids include Centromeric, which has seen recent success in the Nicaraguan Cup of Excellence.One of the most important points about F1 hybrids, for producers, is that they are typically more expensive and harder to obtain. They are mass propagated in sophisticated nurseries with tissue culture labs (i.e., they are cloned) instead of by seed. This is necessary because their germinated seeds (the F2, or second generation) will not necessarily possess the same great qualities as the F1 mother plant, meaning that farmers cannot rely on the performance of the plant. For this reason, WCR advises that producers only buy from reputable nurseries.
Caturra
A natural Bourbon mutation, Caturra is a dwarf tree with an average yield, average quality, and average bean size – in fact, the WCR description of an average yield is “Caturra-like”. It is susceptible to rust and pests, and commonly grown throughout Brazil and Latin America. I’ve included it here because of how common it is.
Catuai
Catuai is a Mundo Novo and Caturra cross that shares many of the same characteristics as Caturra: average yield, average quality, average bean size, susceptibility to rust and pests, and dwarf status. This is only an introduction to the wonderful world of coffee varieties. There are many more that deserve attention: Pacas, Pacamara, Maracaturra, Rume Sudan, Laurina, SL-28, SL-34… The list goes on and on. Producers, pick your coffee varieties carefully. Do your research: understand the demands of each one, and the risks that come with it. When planting a new variety, consider starting slowly, with only a small portion of your farm. As for you, coffee lovers, taste as many varieties as possible. Pay attention to how they vary. Compare different varieties grown in the same region – or the same variety grown across different regions. As you start to learn more about how the variety can affect your cup, your appreciation of coffee will only grow.
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]]>Agronomy is the science of plant production for food, fuel, and fiber. The work of an agronomist encompasses plant genetics and physiology as well as meteorology and soil science. This very simple video from USAID agency working in Uganda will give you an impression of some of the areas that an agronomist oversees. In coffee-producing countries, agronomists operate in the field, working directly with coffee farmers and cooperatives.
They are trained to monitor the terroir of a farming area. Through careful measurements, agronomists can advise farms on practical farm management, helping them achieve the correct levels of soil drainage and teaching them how to implement preventative measures against soil erosion. They can help farmers achieve a sustainable planting density and choose the right fertilizers, and they can offer advice on how to prune and manipulate their trees. Agronomists are the interface between the body of scientific research and the local terroir. To better understand this important practice, we talk about it from other point of view :
hoping to understand more about the science of agronomy. When you are making decisions as to what to plant on your farm or you are advising others on what to plant, what measurements do it need to help more is experiment with varieties that have not been planted at the farm. They are in a kind of Coffee Garden, where we have many varieties expressing their phenotype (meaning, how the plant adapts to the environmental conditions, and how it expresses itself in the cup profile). By now, it really like the behavior and taste of Red Bourbon, Yellow Catuai, Pacamara, Geishas, Rume Sudan, and SL28. All of them are yummy, per se, and we like how cup profile is expressed As a result, it takes years before we set it. For example, you should know know Pacamara and Yellow Catuai will not need too much shade, [which is required] by Bourbon, SL28, and … the Geisha varieties we plant at the farm. the elevation, as our cupping trials have shown, has an impact on the level of acidity. also, we have seen that some of the additional flavor attributes will be more pronounced if the coffee flavor is modulated at the wet-mill. For example, Pacamara and Yellow Catuai will score 84 to 85 points if I do a traditional full-washing process.
But if I do an Orange Honey (semi washed) for Yellow Catuai, or a Natural for a Pacamara, the flavor will explode in my mouth. The Bourbons and Geishas have more versatile cherries; their expression will be great as Natural, or semi-washed or a Double Soak process that is a Full Wash variant, on which prefer is the cherries before depulping, and then give its normal dry fermentation. choosing varieties is something that comes down to microclimate, or the right variety perform well across a range of different conditions in the same terroir, but don’t forget Climate and Edaphic Factors absolutely contribute to the final flavor quality of the bean. Bourbon and Geisha will always express better in a forest environment; Its architecture is full, meaning that their leaves will dress completely the plants. Plants with no stress will always express their happiness in the cup profile J Coffee plants, any variety, will express more crispy flavor when a source of water is close to them. I think mist will help the coffee plants to maintain more fresh temperatures, together with good shade, their system is more stable and with more equilibrium; remembering that this system is found at the forests from Ethiopia where the coffee genetics comes from. Also, coffees grown at higher elevations have a higher chance to score high at the cupping table than coffees grown at lower elevations. 70 percent shade determine normal level of shade , It is very important to handle the architecture of the tree and avoid this kind of parasite.
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