I

Residences and institutions invested a large amount of time and resources in brewing and its related processes. This expenditure could leave a detailed written record. Numerous household accounts were examined for this experiment. The most detailed evidence for beer made in Ireland are the household accounts of Lord Deputy William Fitzwilliam at Dublin Castle, which date to several years in the 1570s and 1590s.Footnote ²⁷ The castle was a major military and residential complex, the home of successive lords deputy, the queen's representatives in Ireland. It housed 100 staff of varied status and welcomed numerous guests and messengers. The Fitzwilliam records provide remarkable detail about the beer with which all these people were provided and how it was made over the annual brewing cycle. The buttery accounts from 1574 (see, for example, Figure 1) are especially rich, listing for each brew the quantities of malt and hops used along with the volumes of beer produced. It is helpful that the grain is quantified using the English statute bushel, rather than the variable, regional alternatives.Footnote ²⁸ Importantly, these are not recipes like those in manuscript or print collections, which we can never be sure were actually followed. Instead, they are records of production in a specific institution, at a given moment in time, making them highly suitable to guide experimental reproduction.

Figure 1.

Sample entry from buttery account, Fitzwilliam household, week ending 13 March 1574.

Source: NRO, Fitzwilliam Manuscripts (Irish), MS 51. Reproduced with permission of Sir Philip Naylor-Leyland Bt and Milton (Peterborough) Estates Company.

The beer in these accounts was graded with the nomenclature typical of the period. Historians generally identify three main strengths of beer in accounts and brewing instructions: ‘strong beer’, perhaps with a particular seasonal association like ‘October’ or ‘March’; ‘ordinary’ or ‘household’ beer; and ‘small’ beer. Within these categories, there was variation in quality and strength, and a tendency for types to overlap.Footnote ²⁹ Names also varied over time. While such issues make estimating the relative amounts of each type produced difficult, there are indications that ordinary beer was the most consumed overall, particularly by the working classes.Footnote ³⁰ This is confirmed by the Irish accounts. At Dublin Castle, household production focused on two kinds, strong and ordinary, of which far more was drunk of the latter. In the yearly account for 1574, only 13 per cent of beer consumed was strong. Other years showed similar values.Footnote ³¹ Furthermore, when Fitzwilliam was away from the castle on ‘journeys’, the proportion of strong beer produced fell. Further sources underline the suggestion that the ordinary beer was destined for servants and labourers, the majority of the household. A 1580 estimate of annual expenses under one of Fitzwilliam's successors distinguished beers in hierarchical terms. Beer malt was recorded for ‘6 good brewings of beer onlie for his lordship’, with malt recorded separately for a further 36 brewings ‘for the household’.Footnote ³² Conversely, small beer is not identified in any of the Irish accounts examined. As elsewhere, it was likely considered unsuitable for working adults, being ‘injurous to health’ on grounds of its thinness and weakness.Footnote ³³

Ordinary beer was brewed in two different ways. Either different types of beer could be made at once: hot water was poured on the malt twice or even three times, with the first wort being used to make the strongest beer and the last the weakest.Footnote ³⁴ Or ordinary beer was brewed ‘entire’, blending all the washes of grain from one charge of malt. This method of brewing ‘every kind of malt-liquor separate’ had advantages in taste and quality. (Strong beer could be made in a similar fashion but with additional malt.)Footnote ³⁵ The latter option may have been more common in summer months when brewing was complicated by the heat, which made it difficult to control the fermentation of stronger brews.Footnote ³⁶ This seasonality is conspicuous in the accounts for Dublin Castle, where entire ordinary beers were produced predominantly between May and October.Footnote ³⁷

At the lord deputy's residence, the amount of malt used to produce each gallon of beer was consistent throughout the year. The brewers generally achieved 13.5 gallons of ordinary drink from every bushel of grain. In terms of strength, this is towards the middle of the scale for similar ales and beers outlined in recipes or produced in English households around this time.Footnote ³⁸ In Richard Arnold's Customs of London (1502), the oldest brewing instructions for beer in England currently known, 1 bushel of malt makes 19.2 gallons.Footnote ³⁹ In William Harrison's Description of England (1577), the same quantity of malt yielded 18 gallons of a ‘good beer for poor men’.Footnote ⁴⁰ At the other end of the range, the household of Dame Alice de Bryene yielded just 7 gallons of ale.Footnote ⁴¹ These comparisons suggest that the usual Dublin Castle drink, neither exceptionally strong nor weak, is a good representation of the ‘stronger middle beer’ that was most consumed by workers in this period.Footnote ⁴²

Where the beer in the Irish accounts may be somewhat distinctive is in the type of malt used. Specifically, Irish beers contained a high proportion of oat malt in relation to barley. This would have affected the flavour, nutritional content, and the alcohol level of the resulting drink.Footnote ⁴³ In the Fitzwilliam household between January 1574 and October 1575, the total volume of malt in each of the ninety-one brewings was equally divided between barley and oats.Footnote ⁴⁴ Other Irish institutions brewed with even higher shares, and, occasionally, entirely with oat malt.Footnote ⁴⁵ Growing well in marginal soils and cool, damp climates, oats were one of the main cereal crops in early modern Ireland. Their consumption, in the form of bread as well as beer, has been seen as one of the features of a characteristically Irish diet in this period.Footnote ⁴⁶ Throughout the middle ages, oats were a core ingredient of ales across Europe.Footnote ⁴⁷ Over the course of the sixteenth century, however, as cultivation of other cereals increased, there was a general drift away from oats towards barley-based beers.Footnote ⁴⁸ English writers like Harrison and Gervase Markham proposed adding only a small quantity of oats in their recipes. Even then, caution was advised. Brewing with oats was risky if not carefully managed, the grain being prone to ‘clunter [clot] and fall into lumps…thereby becoming unprofitable’.Footnote ⁴⁹ Tastes may have changed too: there were warnings that using too much oat malt could cause bitterness or ‘give the drink a smack’.Footnote ⁵⁰ Irish beer, then, might be seen as a throwback to earlier tastes.

Ireland, however, was far from an outlier. There were exceptions to the shift from oats in regions like the Low Countries, where oat beers continued to be popular.Footnote ⁵¹ Brewing with oats may also have remained common in Scotland and the north of England.Footnote ⁵² Meanwhile, in the West Country, where oats were a prominent cereal, ale and beer were disparaged much like Irish examples. Andrew Boorde mocked Cornish ales as ‘dycke and smoky…lyke wash, as pygges had wrestled dryn’.Footnote ⁵³ An English visitor to Ireland criticized ‘a kind of beer (which I durst not taste) called charter beer, mighty thick, muddy stuff’.Footnote ⁵⁴ In fact, in southern England, there is also evidence of a sustained interest in oat beers. A manuscript recipe in the possession of Elizabethan courtier Sir Hugh Plat includes instructions for a beer with ‘halfe oate malte & halfe barly malte’ – the same ratio employed at Dublin Castle.Footnote ⁵⁵ Even physicians recommended their application. Tobias Venner concluded that beer made of equal parts oat and barley was better than that made of barley alone, being more effective at quenching thirst and balancing the humors while also being more ‘lively’ in taste.Footnote ⁵⁶ This means that recreating a beer made with plenty of oats is highly relevant for the swathes of Europe where the cereal remained central to brewing. For the purposes of comparison, the specific Irish recipe, selected from Dublin Castle in 1574, has a significant but not overwhelming proportion of oats. This allows us to consider the nature of oat-based beer, while ensuring the conclusions remain useful for places and periods where barley was the dominant malt.

II

While the evidence is clear about the balance of malts used in the past, sourcing appropriate grains for the purposes of reconstructing the beer is challenging. There are two main issues. First, there is uncertainty surrounding the exact cereals in use. This problem is not new. Even in 1726, Caleb Threlkeld, in his Synopsis stirpium hibernicarum, noted that ‘botanists [were] confused about the kinds of barley’ grown in Britain and Ireland.Footnote ⁵⁷ Second, assuming that we could distinguish which species were used for beer-making, the characteristics of early modern cereals were different from their modern counterparts. Before advances in genetics and plant-breeding, which proliferated from the early twentieth century, most crops were kept as landraces.Footnote ⁵⁸ Within species, individual crops were genetically distinct, with seed from the most successful crops selected, stored, and reproduced according to the local climate and soil and farming conditions. Few landraces survive today and, even where their seed has been preserved in gene banks, there is generally no information on provenance and only miniscule quantities are available for research. This is a problem because, where these older varieties are grown successfully, they stand out from hybridized, modern-day strains. In general, they have a greater root mass to mine deeper in less fertile soils, and they grow taller and have less standing ability than modern varieties.Footnote ⁵⁹ This also has implications for their nutritional properties and taste. Studies of their use in brewing have suggested that landrace malts produce distinctive flavours, but also lower alcohol yields, mainly due to the smaller grain size and higher nitrogen levels.Footnote ⁶⁰

When it came to sourcing oats for this project, neither the historical nor the archaeological evidence proved of assistance. The Irish archaeological record reveals the cultivation of Avena sativa or common oats and, less frequently, Avena strigosa or black oats. Despite extensive collation of archaeobotanical remains as part of the wider FoodCult Project, no examples of germinating oats have been found which would have suggested the species was used for malting.Footnote ⁶¹ Furthermore, no gene bank holds seeds from Irish landraces of Avena sativa. We attempted to malt a heritage crop of Irish ‘Sonos’ oats which, while not a landrace, do share characteristics with earlier varieties, but they only germinated to 84 per cent, insufficient to make malt.Footnote ⁶² Given these issues, the only practical solution was to work with modern flaked oat malt, in the knowledge that this may have had a slight impact on the beer.

Distinguishing and accessing viable barley afforded more satisfactory results. Many sources record the cultivation of several types of barley in pre-modern Ireland. Threlkeld's Synopsis identified three: Hordeum distichum or common barley (two rows); Hordeum polystichum vernum or bigg (six rows); and Hordeum polystichum hibernum or beer barley (six rows).Footnote ⁶³ An anonymous 1636 poem from Ireland notes that ‘They spar'd not to beat bear, barley and wheat.’Footnote ⁶⁴ A proclamation made by the country's lord lieutenant in Dublin in 1644, raising levies on various commodities, pointed to a similar range of cereals, with ‘rye, beare, barley, pease, beans and buckwheat’ all accruing an imposition of 18s per peck.Footnote ⁶⁵ Importantly, there is evidence that of the types available, bere was a common choice for malting and brewing. In household accounts, barley malt is variously referred to as ‘beare’, ‘bere’, or ‘beyre’ malt.Footnote ⁶⁶ This is further supported by descriptive sources. In 1690, an English officer observed that all Irish beer and ale, as well as some cakes, were made from bere.Footnote ⁶⁷

The cereal is no longer produced commercially in Ireland, where it has been supplanted by more efficient cultivars, as it has been elsewhere. However, bere is still grown in Orkney in Scotland, where it remains one of the oldest preserved cereal landraces in Europe. For the experiment, we secured a small quantity from the Agronomy Institute at the University of the Highlands and Islands.Footnote ⁶⁸ It should be noted that, though it is an ancient varietal, modern bere differs genetically from earlier counterparts and the specific nature of any landrace depends on the local conditions where it is cultivated over a long period of time. Nonetheless, this cereal represents the most viable landrace that can be used for the recreation of early modern beer in a northern European context.

The most significant change to occur in early modern brewing was the addition of hops. While much has been written about the pace of this innovation in England and Ireland, little information exists on the nature of historical varieties.Footnote ⁶⁹ Household accounts tell us volumes but never specific varietals. They do, however, indicate that hops were imported and sometimes where they came from.Footnote ⁷⁰ One of the Dublin Castle accounts from 1591 described hops that were ‘Flemish’ in origin.Footnote ⁷¹ Our search for an appropriate candidate centred on locating a surviving heritage variety with roots in Flanders. Piecing together some of the earliest descriptions, there is evidence to suggest that one of the first varieties introduced to England was the ‘Flemish red bine’, though it does not survive today.Footnote ⁷² The most similar extant example is ‘Tolhurst’, brought to England in 1882. This shares traits with the old Flemish varietals and is considered by experts to be a direct descendant.Footnote ⁷³ It is also no longer produced commercially and quantities sufficient for the experiment had to be harvested from the few plants preserved in the UK's National Hop Collection.Footnote ⁷⁴ Collecting the amounts required took three years, the hops being dried and stored after each harvest.Footnote ⁷⁵

The final ingredient sourced was yeast. Yeasts are single-cell microorganisms naturally present in a variety of environments. They have been used by humans for producing fermented foods and beverages for thousands of years. The processes of making bread and beer are quite similar because they involve the same yeast metabolic activity: namely, the conversion of simple sugars derived from grain into alcohol and carbon dioxide. Although many yeasts are capable of alcoholic fermentation, humans have selected particular strains of the species Saccharomyces cerevisiae to perform our fermentations. These strains, sometimes colloquially referred to as ‘baker's’ or ‘brewer's’ yeast, evolved characteristics that make them especially suitable for baking and brewing. Examples include a superior ability to use barley-derived sugar maltose as a food source, and tolerance to ethanol.Footnote ⁷⁶

Little is known about the nature and use of yeast in historical brewing. It is generally assumed that in this period it was transferred from one batch of drink to the next as barm, the froth reserved from the fermenting wort.Footnote ⁷⁷ In the Irish records considered here, this was not always the case, with yeast occasionally purchased for brewers at considerable cost, suggesting some standardization of preferred strains by the late sixteenth century.Footnote ⁷⁸ Ideally, this study would have used a sixteenth-century strain but this is not possible because the first pure cultures of yeast were only cultivated by Emil Christian Hansen working for Carlsberg in 1883.

The search for the most appropriate proxy was led by Professor John Morrissey, in collaboration with the UK National Collection of Yeast Cultures (NCYC). Recent research into the evolution of modern yeast strains has indicated that around the fifteenth century a lineage emerged that is a direct ancestor of all modern beer (ale) and bread strains. It can be assumed that this group was well suited to brewing and so was circulated among European brewers, rapidly becoming dominant.Footnote ⁷⁹ While we do not have the ancestral strains, it is possible to use modern genome science and molecular archaeology to infer what might be the closest living yeasts to the ancestor. Among those used for fermentation, there are two large families or clades, termed ‘Beer 1’ and ‘Beer 2’. The former contains two main groups, one associated with Belgium and Germany and the other with Britain and the USA. Some studies described a family of ‘Irish/British ale yeasts’.Footnote ⁸⁰ Therefore, it can be postulated that strains closest to the root of the British and Irish clade are genetically close to those used at Dublin Castle.

We consulted Jo Dicks and Carmen Nueno-Palop at the NCYC, a collection of yeasts deposited by British breweries during the twentieth century. Following analysis of their genome sequences, two strains, NCYC 84 and NCYC 1026, were selected on the basis that they are genetically close to the root of the tree. These strains were recovered from cryopreserved stocks and tested to ensure that they retained brewing traits of interest. In fermentation trials, NCYC 1026, as shown in Figure 2, exhibited more robust growth on both barley wort and ethanol-enriched media, so was chosen for the experiment. It had the further advantage that it had been examined in a previous scientific comparative study.Footnote ⁸¹ Sufficient NCYC 1026 was grown in bioreactors using wort as the nutrient source, concentrated to a slurry, and shipped on ice back to the UK.

Figure 2a and b.

Reconstitution of candidate yeast strains in the laboratory.

Source: Images © John Morrissey.

Once the raw materials were selected, the next stage was making malt. Little is known about the process in sixteenth-century Ireland, but it is likely that, as in England, most grain was malted in purpose-built premises by specialist maltsters who were a feature of every market town. The methods hardly changed before the eighteenth century.Footnote ⁸² Contemporary accounts describe a sequence of soaking the grain in a cistern for a few nights, draining and resting or ‘couching’ it in a heap, before spreading it on a floor to be turned regularly until it germinated. The last step was kilning, which halted the germination and dried the malt.Footnote ⁸³ Although building an early modern malthouse would be a worthwhile venture, it was outside the scope of this experiment. The bere was shipped to Warminster Maltings in Wiltshire, the oldest operational malthouse in the UK and one of a few establishments still using traditional floor-malting methods. Warminster's set up compares well with what is known about excavated Irish malthouses. They were also arranged along an in-line model, with a steeping trough adjacent to a clay-tiled germination floor, with a kiln nearby.Footnote ⁸⁴

The malt was ground using a hand-operated quern, as shown in Figure 3.Footnote ⁸⁵ For the volumes required, working by hand allowed greater control and the ability to tweak the process as needed.Footnote ⁸⁶ Large institutional brewhouses, like the one at Dublin Castle, probably relied on a local water mill.Footnote ⁸⁷ For smaller institutions, however, hand-querning was common. An inventory dated to 1590 for a castle in Co. Kerry listed a pair of querns to grind malt, along with miscellaneous brewing equipment.Footnote ⁸⁸ They were common in England too: William Harrison's wife ground her malt on a quern-stone at home, to avoid paying a toll to the miller.Footnote ⁸⁹

Figure 3.

Quern stone with bere malt.

Source: Image © Susan Flavin.

III

While written evidence for the components of beer is abundant, descriptions of the equipment and techniques early brewers used are vague and thin on the ground. Wills and inventories record brewing kit, but without further details.Footnote ⁹⁰ Examples of this equipment rarely survive, and there is no pictorial evidence for Ireland. The visual sources that exist from elsewhere in Europe, such as Figure 4, are formulaic, typically showing an idealized image of a man or woman stirring a pot. Despite these limitations, it seems that most of the paraphernalia used in sixteenth-century brewing was relatively simple and standard.Footnote ⁹¹ It comprised a boiling vessel or copper to heat water; a ‘mash vat’ or tub in which water was added to ground malt; stirring implements or a brewing oar for mixing; an ‘underbuck’ or tub for collecting the wort drained from the mash vat; ladles to move wort from the underbuck back to the copper for re-boiling with hops; a cooler or tub for allowing the wort's temperature to drop; and a cask in which the wort was fermented. Exactly this list of equipment was itemized in a set of inventories of Henry VIII's brewhouses at Portsmouth in 1525/6.Footnote ⁹² Over time, this arrangement was scaled up, the gap widening between large commercial or military production and the kitchen-based brewing of small homes, but in essence brewing technology and techniques remained broadly consistent between the middle ages and the end of the seventeenth century.Footnote ⁹³ The Dublin Castle brewhouse, pumping out around 10 hogsheads of 54 gallons each week, was at the larger end of the spectrum.

Figure 4.

A sixteenth-century brewhouse.

Source: Jost Amman, ‘Der Bierbreuwer’, 1568: Wellcome Library, 34958i.

The only exception to this standardization appears in the method and use of the mash vat. Before the late seventeenth century, brewers did ‘top-mashing’, pouring malt into the vessel from above. After the allotted time, the wort was run off through a drain in the centre of the tun and the grains were left behind. To facilitate this process, various sieving systems were employed. Although no set of brewing instructions describes the sixteenth-century mash vat, we know that three methods of sieving were used in Europe: the ‘long tap’ (also called a tapstaff or mash staff), ‘huckmuck’, and tube tap. The decision on which adopt was based on early brewing histories, along with artefacts and manuscript sources. The firmest evidence was in favour of the tube tap. With this method, the tub has a hole towards the bottom of one of the staves. A tube and tap are fitted into this hole. Withdrawing the tap allows wort to flow from the tub. Affixed internally to the back of the tube is a ‘wilch’, a woven wicker filter. According to a work on traditional Norwegian brewing, this system was the most common in southern England.Footnote ⁹⁴ Aside from general mentions of wort sieves, few sources point to which system was used in Irish brewing.Footnote ⁹⁵ But imports from the 1560s of large quantities of ‘taps and cannells’, in tandem with rising inward shipments of hops, implies the use of similar technology.Footnote ⁹⁶ Models for a tube tap and wilch are scarce. However, there are published images of historic brewing equipment, and surviving examples at the Museum of English Rural Life and the Museum of East Anglian Life.Footnote ⁹⁷ These provided exemplars for replication, as depicted in Figure 5.

Figure 5.

Replica tube tap with wilch made by historic wicker-worker, Linda Mills.

Source: Image © Susan Flavin.

The reproduction of the brewhouse took three years and drew on the expertise of craftspeople from across Europe, including coppersmiths, historical woodworkers, a cooper, and a wicker-weaver, all commissioned by the project's lead brewer.Footnote ⁹⁸ The brewhouse was assembled at the Weald and Downland Living Museum, which hosted the project in the pre-existing Tudor kitchen, as shown in Figures 6 and 7.Footnote ⁹⁹ This site offered the most authentic environment available, as well as access to a range of technological expertise. It was also chosen because of its water quality. For comparison, water was tested from a surviving portion of the medieval watercourse on the River Dodder in Dublin.Footnote ¹⁰⁰ This showed hardness in the 200–300 milligram range, not far off the levels at the museum. Once the on-site water was filtered to remove modern additives, the pH and hardness were almost identical to the Dublin samples.

Figure 6.

Detail of the mash vat at the assembled brewhouse.

Source: Image © Susan Flavin.

Figure 7.

The assembled brewhouse at the Weald and Downland Living Museum.

Source: Image © Susan Flavin.

IV

Brewing was carried out over a two-week period in September 2021. The recipe selected was from Dublin Castle in May 1574, when in one seven-day span, the brewer produced 11.75 hogsheads (635 gallons), from 47 bushels of malt, comprising 23.5 of bere and 23.5 of oats, with the addition of 20.5 lb of hops. These details were not quite enough. The buttery accounts do not state how much water was added to reach the final volume of beer, even though this entirely determines the strength of beer and therefore is essential for recreating the same type of drink (a point that historians rarely acknowledge). This is part of the craft knowledge of the brewer and is arguably unknowable. Every brewhouse and each brew were unique. Evaporation from boiling would have depended on local conditions such as the building's air flow, and the dimensions of kettles and tubs. Yet the brewing instructions of Hugh Plat and Edward Whitaker give an indication.Footnote ¹⁰¹ Allowing for the liquid lost in mashing and boiling, both noted that achieving 3 gallons of beer required starting with 5 gallons of water. Through the experiment, we found that these figures were accurate, with some flexing for each brew. With a sense of how concentrated the wort should be, the original Dublin Castle recipe was scaled down to match our equipment, which could produce up to 36 gallons a day, as shown in Table 1.

Table 1.

Dublin Castle ordinary beer recipe, week ending 15 May 1574

* Scaled down from the weekly production of 635 gallons.

In the months before the experiment proper, two practice runs were carried out with modern grains to test the kit and develop the project team's brewing proficiency. In September, the aim was to repeat the Dublin Castle recipe three times and carry out two further runs, one using modern grains and yeast, and a further using two bushels of bere, producing the same volume of beer but omitting the oats. This was to assess the technical and nutritional significance of the oats and to produce a beer closer to some contemporary English versions. In practice, we had to brew the Irish beer a fourth time, as one of the efforts produced a ‘stuck mash’, when the oats turned to porridge in the tun.

Before each brew, the malt was measured using a replica Winchester bushel, shown in Figure 8. This simple process had interesting results. A bushel of ground malted barley weighed on average 33.7 lb (15.31 kg) and a bushel of flaked oat malt 41 lb (18.63 kg). In the past, the weight of the volume measure would have varied somewhat depending on the crop, levels of moisture, and the method of malting. But the figure for the barley was considerably less than the 42 lb per bushel applied by historians quantifying the calories available in beer, emphasizing the benefit of integrating practical methods.Footnote ¹⁰²

Figure 8.

Striking a bushel.

Source: Image ©Susan Flavin.

Our brewing protocol followed numerous contemporary printed and manuscript guides.Footnote ¹⁰³ According to a principle adhered to throughout, data was collected using modern scientific equipment, but this was never allowed to guide the process. On each brewing day, the fire was lit under the copper boiler filled with water. The water was brought to a boil then allowed to cool in the copper ‘till the steam is near spent, and you can see your face in it’.Footnote ¹⁰⁴ When checked with a thermometer, the water was ready at 60–70 °C.Footnote ¹⁰⁵ After this, the liquor was ladled into the mash vat and the combined bushels of bere and oats were added, a paddle being used to stir and break up any lumps. At this stage, around 25 gallons of water were added to the tun. After an hour, a ladleful of wort was tapped off from the bottom and poured back over the grains. After a further thirty minutes, the wort was drained. Following early modern advice, the speed was kept slow, the flow regulated so it was running ‘as small as a straw’ (Figure 9).Footnote ¹⁰⁶ This avoided spillages and disruption of the settled grain bed inside the mash vat. Along with the wilch on the end of the tap, the grain bed filtered the wort which, except in one case, worked efficiently and ran clear.

Figure 9.

Wort running through the wilch and tube tap into the ladle.

Source: Image © Susan Flavin.

After draining, this first wash returned about 19–20 gallons of wort. This was stored in the buck. As we were making an entire ordinary beer, we added another 10–15 gallons of hot water to the mash vat (the exact amount depended on how much wort was initially produced, as we were aiming to achieve 25–8 gallons at the end). Once again, the mash was left for an hour and a half, with a gallon of tapped-off wort poured over thirty minutes before the time was up.

After the allotted wait, the second wash was drained and poured into the copper, along with the wort from the first wash waiting in the buck. The combined wort was brought to the boil. At that point, 12 oz of dried hops were added, and the liquid was left to boil for a further ninety minutes. Finally, the wort was ladled into buckets and transferred to a covered barrel and left to cool overnight. The following morning, the starter culture of yeast was fed with a small measure of wort. Once the barrel's temperature had dropped to room temperature, described as ‘blood warm’ in contemporary instructions, the yeast was pitched.Footnote ¹⁰⁷ The preparation was poured into the barrel and stirred vigorously, providing the yeast with plenty of oxygen.

Fermentation took place in upright casks with the heads removed, which were lidded but not sealed. The yeast began working quickly. Daily visual checks were carried out for the end of fermentation, looking for signs like a reduction in bubbling and a flat surface to the beer. It continued for five to seven days, at which point the yeast sank to the bottom. As one manuscript source put it, the beer could be tunned once the ‘barme on ye head…doth descend’.Footnote ¹⁰⁸ The finished drink was then decanted into casks for storage.

Throughout the process, a complex sampling regime was followed.Footnote ¹⁰⁹ For the present study, samples were collected when the wort was boiled with hops before the addition of yeast; after fermentation was complete; and after three weeks of storage, when the beer had cleared and was considered ripe for drinking. This timing was influenced by a seventeenth-century indenture from Trinity College Dublin, which indicates that contemporary beers should be at least three weeks old before consumption.Footnote ¹¹⁰

V

The experiment produced five batches of beer. The results considered here relate to the three completed Dublin Castle beers which, owing to repetition, supplied the most meaningful data. These batches had a slightly bitter taste, with a gentle flavour from the hops. They had a light honey colour and were hazy, probably due to the oats.Footnote ¹¹¹ The samples were sent to the International Centre for Brewing Science at the University of Nottingham for examination. The analysis used various modern methods to quantify the alcohol and carbohydrates, and thus infer the total calorie content.Footnote ¹¹²

Initially, the specific gravity (SG) of the wort was characterized, a measure that broadly describes the degree of fermentability based on available sugars for fermentation. Another way this can be described is by Degrees Plato, defined as a measure of the amount of extracted soluble material (predominantly fermentable sugars) as a percentage of total wort mass.Footnote ¹¹³ Furthermore, the total nitrogen content of each batch of wort was calculated, as yeast requires both sugar and protein for successful propagation and fermentation. Despite following the same procedure for sample preparation, there was some variation in the quantity of extract in each batch of wort (Table 2). Likewise, there were significant differences in the SG of the three brews.

Table 2.

The specific gravity (as both SG and Degrees Plato), density values, and total nitrogen content of the wort samples prepared in this study using the Dublin Castle recipe

On measuring the alcohol content of the fresh beer, batch 1 recorded a much lower value than batches 2 and 3 (Table 3). These two batches provided alcohol by volume (ABV) values quite close to a typical modern English cask ale. Furthermore, their fermentation performance, as described by the apparent degrees of fermentation (ADF), behaved in a manner not dissimilar to modern ale fermentations.

Table 3.

Alcohol content by volume (ABV), specific gravity (SG), Degrees Plato (°P), density and apparent degrees of fermentation (ADF) of the three batches of ‘fresh’ Dublin Castle beer

To further understand the difference in SG and ABV, the specific sugars in each batch of wort were quantified (Table 4). Wort from batch 1 had a reduced concentration of both maltose and maltotriose, the main sugars fermented into alcohol by yeast and products of the enzymatic hydrolysis of solubilized starch during mashing. The enzymes are sensitive to temperature, so it is plausible that that the temperature of wort production for batch 1 was greater than the optimum range for starch hydrolysis (63–73 °C), resulting in less fermentable sugar that could produce alcohol. The variation in values could also be attributed to fluctuations in the volume of water used. Batch 1 produced 28 gallons of wort from 39 gallons of water, while batches 2 and 3 both returned 26 gallons from 35 and 36 gallons of water respectively. More or less liquid was soaked up in the mash vat due to the fineness of the ground malt and the temperature of the water.

Table 4.

Concentration of glucose, maltose, and maltotriose in each batch of the Dublin Castle recipe beers

After the maturation period, all three batches showed an increase in ABV with a corresponding fall in SG (Table 5). This is to be expected, as the residual suspended yeast particles present in the beer were still alive and able to continue fermenting any residual sugars.

Table 5.

Alcohol content by volume (ABV), specific gravity (SG), Degrees Plato (°P), density, and apparent degrees of fermentation (ADF) of the three batches of beer prepared to the Dublin Castle recipe after conditioning

Nutritional analysis was restricted to the three-week old samples, deemed to be fit for consumption. The total calorie content was determined by quantifying the components that impart energy upon digestion: carbohydrates (starches, sugars, and dietary fibres), protein, and alcohol. Table 6 summarizes how much of these components each batch of the beer contained, as well as the total calorie content determined using the Atwater system (per litre and per UK pint or 568 mL).Footnote ¹¹⁴ For comparison, we also performed the same analysis on a lager beer now consumed worldwide.

Table 6.

Macronutrient content and inferred total calorie content per unit volume for the three batches of matured Dublin Castle beer, as well as a modern lager beer for comparison

The total calorie content of batches 2 and 3 was almost equivalent to the modern lager. Meanwhile, batch 1 recorded a much lower figure. This can largely be attributed to the reduced level of alcohol, which has the greatest contribution to calorie content of the measured nutrients. This batch's higher content of starches derived from the incomplete starch hydrolysis during wort production.

In summary, the beer from batch 1 was an outlier with a lower alcohol and calorific content than the other two. Its differences were explained by the reduced level of fermentable sugars, perhaps due to a higher water temperature or the variable amount of water added. Despite the variability inherent to early modern brewing, batches 2 and 3 showed remarkably similar results. The Dublin Castle beer, after three weeks of maturation, had an ABV of 5–5.3 per cent and an energy content of 260–72 kCal per pint. These characteristics made it highly comparable to modern beverages.

VI

These results shed some light on the practice of early modern brewing as well as the dietary importance of beer. From a purely theoretical perspective, we might have assumed that crude equipment, top-mashing, and basic filtration limited the extraction of sugar from the malt and turned out an inconsistent product. We might also have expected that the pre-modern grains restricted the potency of the end-product, and that old yeast strains struggled to ferment either fast enough or fully. These reasonable assumptions feature in much of the historiography around beer.Footnote ¹¹⁵ This is why the careful reconstruction of each stage of sixteenth-century brewing was vital. Brewed following contemporary formulas and using grains that compared to pre-industrial cereals, traditional processing techniques, and early modern technology, the Dublin Castle beer had much in common with those consumed for leisure today. By this point in the past, the experiment suggests, the key features of modern brewing were in place. This chimes with what we know about the precocious development of the trade by the sixteenth and seventeenth centuries, with large-scale, commercialized businesses servicing a mass demand already achieving efficiencies in the use of raw ingredients, fuel, and human resources.Footnote ¹¹⁶ Not only did these brewers anticipate the even greater upscaling of the industrial era, but their equipment and processes were able to produce a beer with which modern drinkers would be familiar.

However, there is one major difference with the industrialized beer-making that has characterized recent history: standardization. Modern brewers have far more control of every stage in the process. Today's varieties of cereal and strains of yeast have been bred to behave in a consistent manner and produce the same end-result. Measuring temperature using a digital thermometer, rather than the brewer's eye or a dipped finger, is also necessarily more precise. Nowadays, the aim is to make the same beer each time. Despite following the same recipe and processes, the Dublin Castle brews all varied to differing extents. In the final analysis, the second two batches were much closer in composition. This was probably a question of control, particularly if a difference in water temperature lay behind the variable extraction of sugars. It also reflects the benefits of practice. The outlying batch 1 was the first of the three brews carried out. As the team gained proficiency, we quickly learned to adjust to any problems. One misstep in the experiment exemplifies this. On one aborted brewing day, the mash became ‘stuck’ in the tun and would not filter.Footnote ¹¹⁷ After discussion and returning to contemporary instructions, we reasoned that the water might not have cooled sufficiently before adding the malt. By tweaking our approach and allowing the temperature to drop a while longer, this mistake was avoided in subsequent brews. This experience mirrored that of brewers in the past, who noted that when working with oat malt, ‘cold’ water should be added.Footnote ¹¹⁸ Early beer-makers likely built up a bank of experience, developing solutions to possible problems related to the ingredients, equipment, and environment with which they worked, mitigating undesirable variations in quality and reducing the number of wasteful failures. Stripped back as their processes seem, we should not underestimate the skill and knowledge of early modern brewers.

When considering beer's dietary importance, we should note that calculating the nutritional value of an alcoholic drink is problematic. Alcohol is an energy-dense substance, but is less easily converted by the body than carbohydrates, and the metabolic significance of this is a long-standing question among scientists. Exactly how the body uses energy from alcohol is more complex than can be explained by a simple conversion to calories.Footnote ¹¹⁹ Further projects in this vein could collaborate with nutritionists to consider the different forms of available energy within historical beer. While providing a breakdown of the macronutrients, which could be powerful data underpinning future research, this experiment has employed basic energy estimates to enable comparison with previous studies.

Our results confirm that beer was a fundamental source of energy in early modern diets. Assuming that the Dublin Castle drinkers had between 5 and 10 pints a day, beer provided each member of household staff with as many as 2,700 kCal. That is still very high, but it is notable that the most energy-rich beer from the experiment (batch 2) contained 32.5 per cent fewer calories, pint for pint, than the 400 kCal estimate for ordinary table beer Craig Muldrew used in his study of pre-industrial food and energy.Footnote ¹²⁰ The recipe the experiment replicated used an amount of malt that sits within the standard range of values for beer of this strength. In reality, beers would have varied significantly, even within a category, but these new results suggest the need for a downward revision in some estimates of the calories provided from drink.Footnote ¹²¹ Because of the experiment's limitations, it is not the authors’ intention to claim that the Dublin Castle beer should be a universal stand-in for what most people drank in this period, when calculating how successfully communities were fed and watered. While quantitative analysis always requires using generalized averages, it is important to take greater account of the conditions and processes involved in producing food in the past.

The results also make plain that ordinary beer in the early modern period could be as potent as its present-day counterpart. The two Dublin Castle batches that showed complete starch hydrolysis and good fermentation responses yielded figures of over 5 per cent.Footnote ¹²² Given this finding, historians should be wary of assuming that people drank so much in the past because the beer was weaker. When converted to a measure used to track and regulate alcohol consumption today, each pint of Dublin Castle beer contained just over 3 units of alcohol.Footnote ¹²³ The current UK recommendation is for both males and females to not exceed 14 units per week to avoid health risks. Even if the residents of the Irish lord deputy's household consumed just 5 pints a day, they may have hit 15 units every 24 hours. In other words, what is now considered a safe weekly limit was exceeded on most days of the week. Thus, the quantities of alcohol that staff and family members at institutions like Dublin Castle were encouraged to drink on a daily basis, as part of their regular diet, had the potential to cause significant inebriation. Once again, the authors are hesitant to over-generalize, given the preliminary nature of the experiment, but this may have implications for our understanding of the early modern concept of intoxication. If the beer that people were supposed to drink as a nutritious foodstuff was already getting them drunk, then it is little wonder that imbibing to excess in other social venues was often cast as dangerous and unruly.

These are baseline findings. As such, they raise questions beyond the scope of the initial project. Subsequent studies might consider the strength of other beers in this and earlier periods. They might look at the effect of using the same recipes at a greater or smaller scale, to mimic the circumstances of a proto-industrial, commercial brewhouse or a family making drink for themselves. They might also isolate specific variables, for example reproducing barley- or oat-only recipes or using the same ingredients with modern equipment. Developing collaborations with nutritionists might also advance our understanding of how beer was metabolized in the past, an avenue with direct relevance for scientists studying over-consumption in the present. Furthermore, what we have learned about the alcoholic strength of beer may be connected to the cultural and social contexts of drinking. Micro-studies might look at when and how people drank these great quantities and their level of inebriation. Was beer only consumed with solid food or drunk during work as hydration? Was it slugged down in great gulps or sipped throughout the day? How much extra beer was drunk for leisure, on top of workmen's allowances, and was this beer even stronger?

VII

This experiment set out to estimate the nutritional content and alcoholic strength of early modern beer, by means of a thorough reconstruction of the equipment, ingredients, and processes employed in the past. Analysis of three batches of a drink comparable to the ordinary beer brewed at Dublin Castle in 1574 suggested that, in calorific terms, the sixteenth-century beverage was strikingly similar to a modern lager. While this may mean historians need to reduce their benchmarks for the number of calories beer provided, it was still a significant source of energy, especially given the very high levels of consumption noted in this and other studies. The analysis also indicated that this beer could ferment very well and result in an ABV on a par with present-day cask ales. Contrary to long-held assumptions, there is no reason why historical beer was necessarily weaker, though more work is needed to explore the contemporary experience of a specific drink's potency. Beyond the core research questions, the experiment offered insight into the practices of brewing at this point in European history. By the sixteenth century, beer-making techniques and technology were not essentially different from later industrial methods, which mostly made advances in scale, precision, and repeatability. Brewers like those working at Dublin Castle possessed a profound knowledge of their craft and made careful judgements based on sensory observation to produce a good quality, consistent product. Such implicit knowledge was not necessarily written down, highlighting the value in looking beyond recipes and towards experimental archaeology. Cumulatively, this project has demonstrated the benefits of radical interdisciplinarity. By engaging with colleagues in a multitude of fields, from microbiology to brewing science to craft-based historical interpretation, at an early stage in planning and throughout the analysis, more challenging questions can be posed, and more complex answers put forward. The study of food and drink lends itself to such approaches, because it can be examined from a range of perspectives, from the social and cultural to the biological and physiological. Experimentation of this kind throws up difficulties and expends plenty of resources but has the potential to paint a more holistic picture of the foundations of early modern life and help us understand issues in the present as well as the past.