A: Read on:
One of the major contributions hops give to beer is a characteristic bitterness that provides a counterpoint to the rich sweetness provided by the malt. This bitter flavor is extracted from the hops during the boil. It is during this time that virtually insoluble alpha acids are isomerized (rearranged without changing their composition) into more soluble and stable iso-alpha acids, the main bittering substance in beer. Five different naturally occurring alpha acids have been isolated from hops which are:
humulone
cohumulone
adhumulone
prehumulone
posthumulone
Although isomerized alpha acids are the biggest contributers, hops contain beta acids which also add bitterness to beer. The beta acids are similar to alpha acids both in structure and abundance. In contrast to alpha acids, it is not isomerized beta acids that add bitterness, is the oxidation products of the beta acids, which are bitter and soluble, that make their presence felt.
Both the alpha and beta acids are very susceptible to oxidation, especially at temperatures above freezing. Theoretical losses of alpha acids of up to 60% have been calculated for hops which are packaged and stored poorly. This is important because once alpha acids have been oxidized they can no longer be isomerized into iso-alpha acid, thus decreasing the hop's bittering potential. As stated above, oxidation components of beta acids contribute to bitterness, thus the bittering potential of oxidized hops may not decrease as much as is commonly thought. This does not, in any way, argue against storing hops well, since essential oil is dramatically altered by oxidation.
For these reasons, the "storageability" of each hop variety is often provided, along with the alpha and beta acid levels, by the hop broker. This parameter is usually given as a percentage of the alpha acids present after 6 months at 20C. Some good storage hops (usually high alpha acid) lose only 15-20% of their alpha acids: Cluster, and Galena are among the best. Most high quality aroma hops lose anywhere from 35-65% of their alpha acids unless anaerobic conditions and cold storage (<0c) are provided.
This is why it is imperative for brewers to buy the freshest hops available and store them in the freezer, properly packaged.
Essential Oils
Hops bring a lot more to beer than bitterness. The volatile oil, usually 0.5 - 3.0% (vol/wt) of hop cone, is an important part of many types of beer. Brewers seeking to maximize hop flavor and aroma generally make late kettle additions (0-15 min. before cooling) with high quality "aroma" hops. Dry hopping, i.e. the addition of hops to the secondary fermenter or serving tank, is another way to add hop character to a beer although the aroma components retained by this method differ from those obtained in late kettle additions. The maximum oil utilization is about 10 - 15% which decreases with increased boiling time.
The essential oils are what give hops their unique aroma; each variety has its own distinct profile. The smell of hops freshly crushed in your hand is quite often different than that in a finished beer. This is due to the fact that the major components in hop oil, beta-pinene, myrcene, beta-caryophylene, farnesene and alpha-humulene, are not usually found in beer. However, fermentation and the oxidation products of these compounds, especially humulene epoxides and diepoxides are considered contributors to "hoppy" flavors and aroma. The exception here is with dry-hopping, where some of the hop oil components do survive into the beer intact.
Researchers have not been able to duplicate the complexities of hoppy character by adding pure chemicals in any proportion or combination. Consensus is that there is a synergistic blend of several compounds, some of which may have not yet been discovered.
Hop researchers, using capillary gas chromatography, have detected and identified more than 250 essential oil components in hops. Twenty two of these have been pinpointed as being good indicators of hoppiness potential. They are subdivided into 3 groups, humulene and caryophyllene oxidative products, floral/estery compounds, and citrus/piney compounds, as listed below:
Oxidation Products:
caryolan-1-ol
caryophyllene oxide
humulene diepoxide a
humulene diepoxide b
humulene diepoxide c
humulene epoxide I
humulene epoxide II
humulene epoxide III
humulenol II
humulol
Floral/Estery Compounds:
geraniol
geranyl acetate
geranyl isobutyrate
linalool
Citrus/Piney Compounds:
delta-cadinene
gamma-cadinene
citral
limonene
limonene-10-ol
alpha-muurolene
nerol
beta-selenene
A: Much has been written about what form of hops should be used. Loose hops are just that: loose cones which have been dried after picking. Plugs are loose hops which have been subsequently pressed into a bung, generally in 0.5 oz. sizes. Pellets are loose hops which have been ground to a fine powder and then pressed into rabbit-food-sized pellets.
LOOSE HOPS
Advantages: They are the most natural form of the ingredient. They float, which is good for siphoning out from under, and form a natural filter bed. When they are fresh, they beat all others in terms of aromatic hop oils.
Disadvantages: They float, so some contact with a still wort (as in dry hopping) is lost, when compared to pellets. This problem can be overcome, though by using weighted hop bags, or it can be ignored. Since they are loose, exposure to air is the greatest and they lose quality quickly when compared to the other forms of hops. When stored in vacuum-sealed or CO2 or nitrogen purged Oxygen barrier bags or jars, this problem can be avoided. They are bulkier than other forms.
PLUGS
Advantages: Are nearly the same as loose hops, in that, when hydrated, they become whole hop cones again. Like loose hops, they float. Unlike loose hops, they are better protected from air.
Disadvantages: Few hop varieties come in this form. Currently, any domestic varieties are first shipped to England where they are made into plugs and then shipped back to the U.S. This may negate any freshness advantage they have over loose hops (for U.S. varieties) It is difficult, but not impossible to separate into increments smaller than 0.5 oz.
PELLETS
Advantages: Convenient to measure and have the best protection from air. They sink, so they get maximum contact in a still wort, as when used for dry hopping. This advantage may be mitigated though, if they are subsequently covered with dead yeast, so later additions are recommended. They reportedly contribute 10% more alpha acids to the wort because of maximized surface area, so are a more efficient use of this relatively expensive ingredient. They are generally available in more varieties and are generally a more consistent product.
Disadvantages: They sink, so it is sometimes difficult to avoid them when siphoning. The extra processing may reduce/change hop aromatics.
Given the pros and cons listed, the choice of which form of hop to use in a certain application is up the individual brewer.
A: Alpha Acid Units (AAU) and Homebrew Bittering Units (HBU) are the same. For the sake of discussion we will use AAU's, which are calculated as follows: AAU = AA * W
where AA = alpha acid % provided with the hops W = weight of the hops in ounces
AAU's are literally hundredths of an ounce, so the units would be ounces. This is a bit awkward, and they are usually discussed as if they are "unit-less". It is generally assumed that, when using AAU or HBU, the batch size is the standard homebrewing unit of 5 gallons. If a beer is said to have 10 AAU's of bitterness in it, and it is a 5 gallon batch, there would probably be no confusion. On the other hand, if it is a 10 gallon batch, there is actually half the AAU's per gallon when compared to the 5 gallon batch and the beer would be quite different. Another drawback to using AAU's is that they don't consider the utilization obtained from long, intermediate, or short boil times. Fudge factors are sometimes added but at best they offer a rough approximation.
To help solve these problems, the International Bittering Unit (IBU) may be
used. With it, the brewer can get a more accurate approximation of the
bitterness given up by a given quantity of a given AA hop for a given boil
time. It is independent of batch size so that a 5 gallon batch with 29 IBU's
has the same bitterness as a 50 barrel batch with 29 IBU's. The equations are
commonly quoted from Jackie Rager's article in the Zymurgy "Hops and Beer"
Special Edition published in 1990. The tables and formulae follow:
Boiling Time (minutes) % Utilization ---------------------- ------------- less than 5 5.0 6 - 10 6.0 11 - 15 8.0 16 - 20 10.1 21 - 25 12.1 26 - 30 15.3 31 - 35 18.8 36 - 40 22.8 41 - 45 26.9 46 - 50 28.1 51 - 60 30.0Utilization can be reduced to the following smooth function, as opposed to the table, which produces many discontinuous lines. Either can be used with sufficient accuracy for the homebrewing operation.
%UTILIZATION = 18.10907 + 13.86204 * hyptan[(MINUTES - 31.32275) / 18.26774] (Of course, you can drop some of those significant figures.)Jackie Rager's numbers have been used successfully by hundreds of homebrewers and provide a consistent base with which to work. It is apparent that his constant 7462, derived from metric to US conversion, is actually closer to 7490. The ADJUSTMENT factor could be questioned as well, as it is intuitively obvious that a gravity of 1.049 does not affect utilization exactly the same as a gravity of 1.000 (water). It is assumed that the utilization table is corrected for this assumption and/or the difference is small enough that it has little effect on the final bitterness of the beer.If the gravity of the boil exceeds 1.050: ADJUSTMENT = (BOIL_GRAVITY - 1.050) / 0.2 otherwise, ADJUSTMENT = 0 IBU_PER_OZ = %UTILIZATION * %ALPHA * 7462 / (VOLUME * (1 + ADJUSTMENT)); UTILIZATION is the percent alpha acids expressed as a decimal fraction ALPHA is the percent alpha acids expressed as a decimal fraction VOLUME is the final number of gallons in the batch (usually 5).
To calculate IBU's if you know the number of ounces of hops to be used: IBU = OUNCES * IBU_PER_OZ To predict the number of ounces needed to hit a target IBU: OUNCES = IBU / IBU_PER_OZ
Note also that Mr. Rager's numbers are often used for pellet hops thrown loose in the boil. Al Korzonas suggests adding 10% more hops if used in a hop bag, and 10% more than that if loose hops or plugs are used.
It has been reported that since iso-alpha acids possess a slight electrical
charge, they can be lost in many ways. Among these are absorption into the
yeast cell walls (and subsequent removal of the yeast), attachment to
coagulating proteins (and subsequent removal of this trub), attachment to
filters, etc. It is unclear if Mr. Rager's utilization numbers have assumed
these losses. A revised utilization table has been presented by Mark Garetz
and can be used if desired. It is shown below for reference.
The same IBU formulae from above can be used with this table. It represents one of the many arguable topics of hops in homebrewing.Boiling Time (minutes) % Utilization (adjusted for average yeast) ---------------------- ------------- less than 5 0.0 6 - 10 0.0 11 - 15 1.0 16 - 20 4.0 21 - 25 6.0 26 - 30 11.0 31 - 35 13.0 36 - 40 19.0 41 - 45 23.0 46 - 50 24.0 51 - 60 25.0
Balanced Beer Hop Chart Wort OG IBU ------- --- 1.010 4 1.020 8 1.030 12 1.040 16 1.050 24 1.060 32 1.070 40 1.080 48 1.090 56 1.100 64
A: At as low a temperature as possible, likely to be in your freezer. Also, attempt to remove as much air as possible from the package and use airtight, preferably oxygen-barrier packages.
Hops for beer-making grow from the rhizomes of female hop plants. Rhizomes look like root cuttings but have buds growing from them that will become new vines. Rhizomes also contain stored nutrients to support initial growth.
Hops grow vertically as one or more vines that spiral up a twine or other support. Depending on latitude, location, and variety, they sprout from March or April and grow through the summer and early fall. A single plant can easily grow 40 feet tall when it is mature but growth in the first year is usually much less. In most instances by the second or third year the plants will exhibit full growth. Height is very closely linked to the amount of sunshine the plant gets.
Hops grow best in full sun and you should pick a spot with the best possible southern exposure. Hops grow best in loose, well drained soil. Blended peat moss and sand make a good growing environment. In cases of poor soil drainage, it can be helpful to create a mound of soil a foot or so tall which will aid drainage.
Hops need lots of water. As they grow be sure to give them a very good soaking at least once a week. There are reports that once-a-day waterings (up to 6.5 gallons per mound) give greater growth and yield. Mulch in the summer helps with weed control and also holds water. Hops also have big appetites; composted cow manure is an excellent well-balanced fertilizer for them.
Once a bed has been prepared the rhizomes are planted about 4 inches below the soil surface with any obvious buds coming from the rhizome oriented to point upward.
After several inches the new vines should be thinned so that just the most healthy and vigorous three vines are left to continue growing. This will be an ongoing process as new shoots may show up later, but the initial thinning is important. It's been reported that the young shoots that are culled may be steamed and eaten like asparagus. On the other hand, some growers espouse cutting the new shoots at all, allowing all vines to grow to full height.
As the vines grow over a foot tall they should be trained to grow up a twine. This can be done by twisting the vine around the line. This may have to be repeated for a few days before the vine gets the idea. Hops will have a natural tendency to wrap clockwise looking down.
The most common hops trellis consists of strings running from the roof of a building down to stakes driven into the soil near the plants. Another option, often used by commercial growers, consists of a large central pole, with strings running from the top of the pole down to the foot of each plant, similar to the spokes on a wheel. Expect the string or twine to hold a lot of weight as the vines grow tall. A 25+ foot plant may weigh 20+ pounds.
Hop blossoms start out looking like large sand burrs, and then take on a characteristic cone shape as they grow in size. The size of a fully developed cone depends on the variety, varying from 1 to 2 inches long by 1/2 to 1 inch in diameter.
The hops are fully mature and ready for picking when two changes take place. First, immature hops have a damp, soft feel and when squeezed slightly tend to stay compressed. Mature hops feel more like paper, spring back when squeezed, and feel noticeably lighter. The second key test is to pick an average example hop and cut it lengthwise down the center with a knife. When ready to pick, the yellow powder (the lupulin sacs containing the essential oils and bitter compounds) will be a dark shade of yellow, like the stripes on a highway, and it will be pungent. If a light shade of yellow then its likely the hops are immature.
When ready to pick it is best to snip the stems of the cones with scissors or a knife to avoid jarring the hops and knocking lupulin powder out or worse, pulling the center of the cone out with the stem, causing a great loss of lupulin. Touching hops plants can cause skin irritation in some people; gloves and long sleeves can help in this matter.
Just-picked hops are roughly 80 percent water; if left alone they spoil rapidly. For proper storage most of the water is removed by drying. A good drying method is to lie the hops on a card or screen in an attic. Just a few hours during the heat of summer or a few hours more in cooler weather is enough to dry the hops. Use a before and after weighing (and trial and error) to try to achieve about 7-10 percent residual moisture after drying.
After drying, hops keep best at low temperatures and away from oxygen. A kitchen freezer easily takes care of temperature but to get the hops away from oxygen is difficult. Tightly packing hops in canning jars will minimize the trapped air but be careful not to use too much force and break the all important lupulin sacs since this accelerates oxidation. Purging the canning jar of oxygen by blowing in carbon dioxide from a kegging system will also help prolong freshness.
It's common to get 4 or 5 harvests per year by picking the biggest, most mature hops every 2 weeks or so as the flowers ripen. Patience and judgement are important since cones left on the vine too long turn brown and begin to oxidize and spoil, while immature hops have little lupulin to give.
At the end of the growing season when the leaves have fallen or turned brown, cut the vines at the surface of the soil and if possible remove the twine. After cutting back the vines a layer of 3 or 4 inches of mulch and composted manure can be put over the exposed vines for insulation and nutrition during the winter.
Japanese beetles are the number one nuisance in many areas. A common remedy is to position a "Bag a Bug" type beetle trap about 30 feet directly up wind from the hop vines. There is some concern that the "Bag a Bug" traps may actually attract more beetles than they catch, but that probably depends on the situation. Certain plants such as rose bushes may also attract the beetles, so it's best to keep those plants away from your hops. Also, the beetles' larvae live in the ground, and in cases of extreme Japanese Beetle infestation the surrounding lawn may need to be treated accordingly. A number of other pests, such as aphids, can harm hops, and can be treated with any number of pesticides. Since you will be consuming these hops, you should use low toxicity natural pesticides, such as 1% Rotenone dust, for direct pest control on the plants. As with any consumable, you should ensure that any pesticide is well washed before using the hops.
Ladybugs are the best, most natural way to get rid of aphids and a lot of other bugs. However, it can be difficult to keep them on your hop plants once you run out of food for them. A good idea is to plant some cilantro/coriander between your hop hills. Ladybugs are attracted to this plant and it will keep their attention between feedings of aphids. You can even harvest the cilantro (the leaves) for cooking and use the coriander (the seeds) in Witbier.
One other hazard is animals. A short fence of rabbit wire will keep cats, dogs, rabbits, etc. at bay, but won't do much against deer.
Rhizomes are available from an increasing number of sources. American Brewmaster in Raleigh, NC and Freshops in Philomath, OR are two well-known suppliers. Cost is usually a few dollars each. They should be kept in plastic bags, moist and cold in your refrigerator until they are planted.
Additional information about hop growing can be found in "Homegrown Hops" by David R. Beach. Also, the 1990 special issue of "Zymurgy" is devoted to hops and contains an article about growing hops by Pierre Rajotte. The AHA also has additional hops-oriented publications.
There are several ways to dry hop, if one considers the variations of making hop teas, etc. The best time to dry hop is generally considered to be after primary fermentation has slowed and little CO2 is being driven off the wort. Dry hopping earlier than this point is inefficient as the volatile hop oils are scrubbed away by the exiting CO2. Also, if using pellets, dry hopping early in the fermentation phase may result in the hops (which will sink to the bottom) being covered with yeast and inefficient extraction of aroma.
The proper length of time for dry hopping is dependent on the temperature. At ale temperatures, 7-14 days of contact time is widely used. At lager temperatures, although little data is available, it seems obvious that longer contact times, on the order of 14-21 days, are called for. It is common to use 0.5 - 2.0 oz. or more in a 5 gallon batch, but as always it is up the individual's preferences.
Fuggles, Northern Brewer, Saaz, Cascades, all Hallertauer variants, and many other hops have been used successfully. It should be noted that the aroma of the beer greatly influences the profile, and that the "correct" aroma hop should be used to match the style (i.e. English hops for English ales, German hops for German lagers, etc.). American brewers have traditionally used hops from all over the globe so European hops, for example, can be used without much fear of an ungodly mismatch. It should be noted that traditionally, German beers are not dry-hopped but that American versions of German styles are sometimes dry hopped.
The first and foremost way to dry hop is to simply put the hops into the fermenter. The most common worry with this method is about infecting a beer which is nearly ready to bottle/keg. Hops are natural preservatives, and infections from this method are unheard of. If loose hops or plugs are used, they will float, and many use a sanitized hop bag and marbles to sink the hops for maximum contact. If pellets are used they will sink, but may be difficult to avoid when bottling/kegging. Also, the pellet hops can be easily covered by yeast falling out of suspension, so they should be added after virtually all fermentation activity has ceased, and a good amount of the yeast has fallen.
Another method used to dry hop is to steep the hops in a warm white alcohol (grain, vodka, etc.) and sometimes water solution for hours or days, then pour this solution into the fermenter. This is a common practice among those who want to protect against the remote possibility of infection with normal dry hopping. It should be noted that as the temperature of the alcohol/water/hops mixture is raised, the effect approaches that of finish hopping, as the most volatile hop oils are driven off.
Adding hop oil, a product recently introduced to the homebrewing market, is another way of "dry-hopping". It should be done after primary fermentation has slowed for the same reasons.
These dry hopping methods, and others, will produce different results, mainly because the desired compounds are so volatile. The variety of reactions taking place duration processing and fermentation will affect the results. The "best" method is the one which gives the desired result to the individual homebrewer.
A final note about dry-hopping: the volatile hop compounds will react quickly with oxygen. For this reason, extra measures should be taken to avoid mixing with air during bottling, in order to retain the hop aroma in the bottle for extended periods of time. These extra measures may include the use of CO2 purging the bottling vessel, very quiet siphoning, oxygen scavenging caps, and possibly delayed capping (up to one hour). This method allows any CO2 coming out of solution during the bottling process to push the oxygen out of the bottle before the caps are secured. This method is used by some homebrewers but the results are inconclusive. The simplest method is to use the oxygen scavenging caps, which requires no extra effort and little extra cost. For further reference, the Summer 1993 Zymurgy contains an article by Mark Garetz on this subject.
A: The following table lists many common hop varieties available to the homebrewer:
DISCLAIMER: Hop substitutes should generally be thought of as "last resort" options. Some of them work better than others, and of course, the individual brewer must decide which substitutes are best. No attempt was made here to label "good" and "not-so-good" substitutes, because the opinions vary wildly.
The following hops are generally considered aroma hops although in recent years they have started to gain a following in the homebrew community for bittering as well:
Name: CASCADE Grown: US Profile: spicy, floral, citrus (esp. grapefruit) aroma Typical use: bittering, finishing, dry hopping for American style ales Example: Sierra Nevada Pale Ale, Anchor Liberty Ale & Old Foghorn AA Range: 4.5 - 7% Substitute: CentennialName: CRYSTAL (CFJ-HALLERTAU) Grown: US Profile: mild, pleasant, slightly spicy Typical use: aroma/finishing/flavoring Example: ??? AA Range: 2 - 5% Substitute: Hallertauer Mittelfrueh, Hallertauer Hersbrucker, Mount Hood, Liberty.
Name: EAST KENT GOLDINGS Grown: UK Profile: spicy (candy-like?) flavor; spicy/floral, earthy, rounded, almost pungent aroma Typical use: bittering, finishing, dry hopping for British style ales Example: Young's Special London Ale, Samuel Smith's Pale Ale, Fuller's ESB AA Range: 5 - 7% Substitute: BC Goldings
Name: FUGGLES Grown: UK, US, and other areas Profile: mild, soft, floral aroma Typical use: finishing / dry hopping for all ales, dark lagers Example: Samuel Smith's Pale Ale, Old Peculier, Thomas Hardy's Ale AA Range: 4 - 5.5% Substitute: East Kent Goldings, Willamette
Name: HALLERTAUER HERSBRUCKER Grown: Germany Profile: pleasant, spicy/mild, earthy aroma Typical use: finishing for German style lagers Example: Wheathook Wheaten Ale AA Range: 2.5 - 5% Substitute: Hallertauer Mittelfrueh, Mt. Hood, Liberty, Crystal
Name: HALLERTAUER MITTELFRUEH Grown: Germany Profile: pleasant, spicy, mild herbal aroma Typical use: finishing for German style lagers Example: Sam Adams Boston Lager, Sam Adams Boston Lightship AA Range: 3 - 5% Substitute: Hallertauer Hersbrucker, Mt. Hood, Liberty, Crystal
Name: LIBERTY Grown: US Profile: fine, mild aroma Typical use: finishing for German style lagers Example: Pete's Wicked Lager AA Range: 3 - 5% Substitute: Hallertauer Mittelfrueh, Hallertauer Hersbrucker, Mt. Hood, Crystal
Name: LUBLIN Grown: Poland Profile: reported to be a substitute for noble varieties. Typical use: aroma/finishing Example: ??? AA Range: 2 - 4% Substitute: Saaz, Hallertauer Mittelfrueh, Hallertauer Hersbrucker, Tettnang, Mount Hood, Liberty, Crystal.
Name: MT. HOOD Grown: US Profile: mild, clean aroma Typical use: finishing for German style lagers Example: Anderson Valley High Rollers Wheat Beer AA Range: 3.5 - 5.5% Substitute: Hallertauer Mittelfrueh, Hallertauer Hersbrucker, Liberty, Tettnang
Name: NORTHERN BREWER Grown: UK, US, Germany (called Hallertauer NB), and other areas (growing region affects profile greatly) Profile: fine, fragrant aroma; dry, clean bittering hop Typical use: bittering and finishing for a wide variety of beers Example: Old Peculier(bittering), Anchor Liberty(bittering), Anchor Steam(aroma?) AA Range: 7 - 10% Substitute: ???
Name: SAAZ Grown: Czechoslovakia Profile: delicate, mild, floral aroma Typical use: finishing for Bohemian style lagers Example: Pilsener Urquell AA Range: 3 - 4.5% Substitute: Tettnang (not ideal by any means)
Name: SPALT Grown: Germany/US Profile: mild, pleasant, slightly spicy Typical use: aroma/finishing/flavoring, some bittering Example: ??? AA Range: 3 - 6% Substitute: Saaz, Tettnang
Name: STRISSELSPALT Grown: France -- Alsace area Profile: medium intensity, pleasant, similar to Hersbrucker Typical use: aroma/finishing Example: ??? AA Range: 3 - 5% Substitute: Hersbrucker, German Spalt
Name: STYRIAN GOLDINGS Grown: Yugoslavia (Fuggles grown in Yugoslavia), also grown in US Profile: similar to Fuggles Typical use: bittering/finishing/dry hopping for a wide variety of beers, popular in Europe, especially UK Example: Ind Coope's Burton Ale, Timothy Taylor's Landlord AA Range: 5.5 - 7 Substitute: Fuggles, Willamette
Name: TETTNANG Grown: Germany, US Profile: fine, very spicy aroma Typical use: finishing for German style lagers Example: Gulpener Pilsener, Sam Adams Octoberfest, Anderson Valley ESB AA Range: 4 - 6% Substitute: Saaz, Spalt
Name: WILLAMETTE Grown: US Profile: mild, spicy, floral aroma Typical use: finishing / dry hopping for American / British style ales Example: Sierra Nevada Porter, Ballard Bitter, Anderson Valley Boont Amber AA Range: 4 - 6% Substitute: Fuggles
(note that the examples given may not enlighten the taster as much as the aroma hops in theprevious section):
Name: BREWER'S GOLD Grown: UK, US Profile: poor aroma / sharp bittering hop Typical use: bittering for ales Example: ??? AA Range: 8 - 9% Substitute: BullionName: BULLION Grown: UK (maybe discontinued), US Profile: poor aroma, blackcurrant flavor when used in the boil Typical use: bittering hop for British style ales, perhaps some finishing Example: ??? AA Range: 8 - 11% Substitute: Brewer's Gold
Name: CENTENNIAL Grown: US Profile: spicy, floral aroma, clean bittering hop (Super Cascade?) Typical use: general purpose bittering, aroma, some dry hopping Example: Sierra Nevada Celebration Ale, Sierra Nevada Bigfoot Ale AA Range: 9 - 11.5% Substitute: Cascade
Name: CHINOOK Grown: US Profile: heavy spicy aroma, strong bittering hop, astringent in large quantities Typical use: strong bittering Example: Sierra Nevada Celebration Ale, Sierra Nevada Stout AA Range: 12 - 14% Substitute: Galena, Eroica, Brewer's Gold, Nugget, Bullion
Name: CLUSTER Grown: US, Australia Profile: poor, sharp aroma, sharp bittering hop Typical use: general purpose bittering (Aussie version used as finishing hop) Example: Winterhook Christmas Ale AA Range: 5.5 - 8.5% Substitute: Galena, Cascade, Eroica
Name: EROICA Grown: US Profile: clean bittering hop Typical use: general purpose bittering Example: Ballard Bitter, Blackhook Porter, Anderson Valley Boont Amber AA Range: 12 - 14% Substitute: Northern Brewer, Galena
Name: GALENA Grown: US Profile: clean bittering hop Typical use: general purpose bittering Example: ??? AA Range: 12 - 14% Substitute: Northern Brewer, Eroica, Cluster
Name: NUGGET Grown: US Profile: heavy, spicy, herbal aroma, strong bittering hop Typical use: strong bittering, some aroma uses Example: Sierra Nevada Porter & Bigfoot Ale, Anderson Valley ESB AA Range: 12 - 14 Substitute: ???
Name: PERLE Grown: Germany, US Profile: pleasant aroma, almost minty bittering hop Typical use: general purpose bittering for all lagers except pilsener Example: Sierra Nevada Summerfest AA Range: 7 - 9.5% Substitute: ??? Name: PRIDE OF RINGWOOD Grown: Australia Profile: citric aroma, clean bittering hop Typical use: general purpose bittering Example: ??? AA Range: 9 - 11% Substitute: ???
Business catalogs referenced:
The Hop Source Silverton, OR HopTech Danville, CA Hopunion USA Yakima, WA
Authors referenced in the text:
Jackie Rager
Quentin B. Smith
Also, Messieurs Miller and Papazian should not be overlooked. They have both contributed indirectly to this FAQ.
This FAQ Was HTML'ized by Paul Timmerman
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