\section{Debugging your crumb structure}% \label{section:debugging-crumb-structure} The crumb structure of your bread provides insights into how well your fermentation process has gone. You can also spot common flaws arising from improper technique. This chapter will provide you with information that you can use to debug your baking process. \begin{figure} \includegraphics[width=\textwidth]{crumb-structures-book} \caption[Debugging your crumb structure]{A schematic visualization of different crumb structures and their respective causes. The final bread's crumb is a key aspect to identify potential issues related to fermentation or baking technique.}% \label{fig:crumb-structures-book} \end{figure} \subsection{Perfect fermentation} \begin{figure} \includegraphics[width=\textwidth]{open-crumb} \caption[Perfectly fermented bread]{The bread has a somewhat open crumb with areas featuring a honeycomb structure.}% \label{fig:open-crumb} \end{figure} Of course the perfect fermentation is debatable and highly subjective. To me the perfect sourdough bread features a crisp crust paired with a fluffy, somewhat open crumb. This is the perfect balance of different consistencies when you take a bite. Some people are chasers of a very open crumb, meaning you have large pockets of air (alveoli). It's subjective whether that's the style of bread that you like; however, to achieve it you need to ferment your bread dough perfectly. It takes a lot of skill both in terms of mastering fermentation and technique to achieve a crumb structure like that. Personally, I~like a bread like that, just with a slightly less wild crumb. The style of crumb I~like is called the \emph{honeycomb crumb}. It's not too open, but just enough open to make the bread very fluffy. To achieve the previously mentioned open crumb, you have to touch your dough as little as possible. The more you interact with your dough, the more you are degassing your dough. Excess touching of the dough results in the dough's alveoli merging together. The crumb will not be as open. That's why achieving such a crumb works best if you only ferment one loaf at a time. Normally, if you have to pre-shape your dough, you will automatically degas your dough a little bit during the rounding process. If you skip this step and directly shape your dough, you will achieve a more open crumb. A good rule of thumb is to not touch your dough for at least 1--2~hours before shaping, to achieve as open a crumb as possible. \begin{figure} \includegraphics[width=\textwidth]{honeycomb} \caption[Honeycomb crumb structure]{A whole-wheat sourdough with an almost exclusive honeycomb crumb structure.}% \label{fig:honeycomb} \end{figure} Now this is problematic when you want to make multiple loaves at the same time. Pre-shaping is essential as you are required to divide your large bulk dough into smaller chunks. Without the pre-shaping process, you would end up with many non-uniform bread doughs. This technique is also used when making ciabattas. They are typically not shaped. You only cut the bulk dough into smaller pieces, trying to work the dough as little as possible. With pre-shaping you will converge your dough's alveoli into more of a honeycomb structure, as large pockets of air will slightly merge. Similarly to the open crumb structure, you also have to nail the fermentation process perfectly to achieve this crumb. Too long a fermentation will result in gas leaking out of your dough while baking. The honeycombs won't be able to retain the gas. If you ferment for too short a time, there is not enough gas to inflate the structures. To me this is the perfect style of crumb. As someone who appreciates jam, no jam will fall through a slice of this bread compared to an open crumb. \subsection{Overfermented}% \label{subsec:overfermented-dough} \begin{figure} \includegraphics[width=\textwidth]{fermented-too-long} \caption[Overfermented sourdough bread]{A relatively flat dough that has many tiny pockets of air.}% \label{fig:fermented-too-long} \end{figure} When fermenting your dough for too long, the protease enzyme starts to break down the gluten of your flour. Furthermore, the bacteria consume the gluten in a process called \emph{proteolysis}~\cite{raffaella+di+cagno}. Bakers also refer to this process as \emph{gluten rot}. The gluten that normally traps the \ch{CO2} created by the fermentation process of your microorganisms can no longer keep the gas inside of the dough. The gas disperses outward resulting in smaller alveoli in your crumb. The bread itself tends to be very flat in the oven. Bakers often refer to this style of bread as a \emph{pancake}. The oven spring can be compared to bread doughs made out of low-gluten flour like einkorn. Your bread will feature a lot of acidity, a really strong distinctive tang. From a taste perspective, it might be a little bit too sour. From my own tests with family and friends (n=15--20), I~can say that this style of bread is typically appreciated less. However, I~personally really like the hearty strong taste. It is excellent in combination with something sweet or a soup. From a consistency perspective, it is no longer as fluffy as it could be. The crumb might also taste a little bit gummy. That's because it has been broken down a lot by the bacteria. Furthermore, this style of bread has a significantly lower amount of gluten~\cite{raffaella+di+cagno} and is no longer comparable to raw flour, it's a fully fermented product. You can compare it with a blue cheese that is almost lactose free. When trying to work with the dough, you will notice that suddenly the dough feels very sticky. You can no longer properly shape and work the dough. When trying to remove the dough from a banneton, the dough flattens out a lot. Furthermore, in many cases your dough might stick to the banneton. When beginning with baking I~would use a lot of rice flour in my banneton to dry out the surface of the dough a lot. This way the dough wouldn't stick, despite being overfermented. However as it turns out the stickiness issue has been my lack of understanding the fermentation process. Now I~never use rice flour, except when trying to apply decorative scorings. Managing properly fermentation results in a dough that is not sticky. If you are noticing, during a stretch and fold or during shaping, that your dough is suddenly overly sticky, then the best option is to use a loaf pan. Simply take your dough and toss it into a loaf pan. Wait until the dough mixture has increased in size a bit again and then bake it. You will have a very good-tasting sourdough bread. If it's a bit too sour, you can just bake your dough for a longer period of time to boil away some of the acidity during the baking process. You can also use your dough to set up a new starter and try again tomorrow. Lastly, if you are hungry, you can simply pour some of your dough directly into a heated pan with a bit of oil. It will make delicious sourdough flatbreads. To fix issues related to over-fermentation, you need to stop the fermentation process earlier. What I~like to do is to extract a small fermentation sample from my dough. Depending on the volume increase of this sample, I~can mostly judge when my fermentation is finished. Try to start with a \qty{25}{\percent} volume increase of your main dough or sample. Depending on how much gluten your flour has, you can ferment for a longer period of time. With a strong flour featuring a \qtyrange{14}{15}{\percent} protein, you should be able to safely ferment until a \qty{100}{\percent} size increase. This however also depends on your sourdough starter's composition of yeast and bacteria. The more bacterial fermentation, the faster your dough structure breaks down. Frequent feedings of your sourdough starter will improve the yeast activity. Furthermore, a stiff sourdough starter might be a good solution too. The enhanced yeast activity will result in a more fluffy dough with less bacterial activity. A better yeast activity also will result in less acidity in your final bread. If you are a chaser of a very strong tangy flavor profile, then a stronger flour with more gluten will help. When retarding sourdough (cold-proofing in the refrigerator), temperature plays a pivotal role in fermentation rates. As the dough chills in the refrigerator, fermentation decelerates. Starting the retarding process at a warmer temperature means this deceleration takes longer. For instance, a dough that's ideal after 8 hours of retarding might be ready in merely 4~hours if it began at a higher temperature. Thus, it's crucial to experiment and determine the optimal retarding duration for your specific conditions. Conversely, if the dough starts colder, fermentation halts more rapidly in the refrigerator. In such scenarios, allowing the dough to proof at room temperature briefly before refrigerating can be beneficial. \subsection{Underfermented} \begin{figure} \includegraphics[width=\textwidth]{fermented-too-short-underbaked} \caption[Underfermented bread]{A dense dough featuring a gummy, not fully gelatinized area. The picture has been provided by the user wahlfeld from our community Discord server.}% \label{fig:fermented-too-short-underbaked} \end{figure} This defect is also commonly referred to as \emph{underproofed}. However underproofed is not a good term as it only refers to having a short final proofing stage of the bread-making process. If you were to bake your bread after a perfectly-timed bulk fermentation stage, the result will not be underproofed even if you skipped the proofing stage entirely. Proofing will make your dough a bit more extensible and allows your sourdough to inflate the dough a bit more. When faced with an underfermented bread, something went wrong earlier during the bulk fermentation stage, or maybe even before with your sourdough starter. A typical underfermented dough has very large pockets of air and is partially wet and gummy in some areas of the dough. The large pockets can be compared to making a non-leavened wheat or corn tortilla. As you bake the dough in your pan, the water slowly starts to evaporate. The gas is trapped in the structure of the dough and will create pockets. In case of a tortilla, this is the desired behavior. But when you observe this process in a larger dough, you will create several super alveoli. The water evaporates, and the first alveoli form. Then at some point, the starch starts to gelatinize and becomes solid. This happens first inside of the pockets as the interior heats up faster compared to the rest of the dough. Once all the starch has gelatinized, the alveoli holds their shape and no longer expand. During this process other parts of the bread dough are pushed outwards. That's why an underfermented dough sometimes even features an ear during the baking process. This is also commonly referred to as a \emph{fool's crumb}. You are excited about an ear which can be quite hard to achieve. Plus you might think you finally created some big pockets of air in your crumb. But in reality you fermented for too short a period of time. \begin{figure} \includegraphics[width=\textwidth]{fools-crumb} \caption[Fool's crumb large alveoli]{A typical example of a fool's crumb featuring an ear and several overly large alveoli. The picture has been provided by Rochelle from our community Discord server.}% \label{fools-crumb} \end{figure} In a properly fermented dough, the alveoli help with the heat transfer throughout the dough. From within the many tiny fermentation-induced pockets, the starch gelatinizes. With an underfermented dough, this heat transfer does not properly work. Because of that you sometimes have areas which look like raw dough. Bakers refer to this as a very gummy structure sometimes. Baking your dough for a longer period of time would also properly gelatinize the starch in these areas. However, then other parts of your bread might be baked too long. To fix issues related to under-fermentation, you simply have to ferment your dough for a longer period of time. Now, there is an upper limit to fermentation time as your flour starts to break down the moment it is in contact with water. That's why it might be a good idea to simply speed up your fermentation process. As a rough figure, I~try to aim for a bulk fermentation time of around 8--12~hours typically. To achieve that you can try to make your sourdough starter more active. This can be done by feeding your starter daily over several days. Use the same ratio as you would do for your main bread dough. Assuming you use \qty{20}{\percent} starter calculated on the flour, use a 1:5:5 ratio to feed your starter. That would be \qty{10}{\gram} of existing starter, \qty{50}{\gram} of flour, \qty{50}{\gram} of water for instance. To boost your yeast activity even more, you can consider making a stiff sourdough starter. The bacteria produces mostly acid. The more acidity is piled up, the less active your yeast is. The stiff sourdough starter enables you to start your dough's fermentation with stronger yeast activity and less bacterial activity. \subsection{Not enough dough strength} \begin{figure} \includegraphics[width=\textwidth]{flat-bread} \caption{A very flat bread without enough dough strength.}% \label{flat-bread} \end{figure} When a dough flattens out quite a lot during the baking process, the chances are that you did not create enough dough strength. This means your gluten matrix hasn't been developed properly. Your dough is too extensible and flattens out mostly rather than springing upwards in the oven. This can also happen if you proofed your dough for too long. Over time the gluten relaxes and your dough becomes more and more extensible. You can observe the gluten relaxing behavior too when making a pizza pie. Directly after shaping your dough balls, it's very hard to shape the pizza pie. If you wait for 30--90~minutes stretching the dough becomes a lot easier. The easiest way to fix this is probably to knead your dough more at the start. To simplify things consider using less water for your flour too. This will result in a more elastic dough right away. This concept is commonly used for no-knead style sourdough. Alternatively, you can also perform more stretch and folds during the bulk fermentation process. Each stretch and fold will help to strengthen the gluten matrix and make a more elastic dough. The last option to fix a dough with too little dough strength is to shape your dough tighter. \subsection{Baked too hot} \begin{figure} \includegraphics[width=\textwidth]{baked-too-hot-v2} \caption{A bread with very large alveoli close to the crust.}% \label{baked-too-hot} \end{figure} This is a common mistake that has happened to me a lot. When you bake your dough at too high a temperature, you constrain your dough's expansion. The starch gelatinizes and becomes more and more solid. At around \qty{140}{\degreeCelsius} (\qty{284}{\degF}) the Maillard reaction starts to completely thicken your bread dough's crust. This is similar to baking your bread dough without steam. As the internal dough's temperature heats up, more and more water evaporates, gas expands and the dough is being pushed upwards. Once the dough reaches the crust, it can no longer expand. The alveoli merge into larger structures close to the surface of the dough. By baking too hot, you are not achieving the ear which adds extra flavor. Furthermore, by restricting it's expansion, the crumb will not be as fluffy as it could be. If you have an extensible dough with high hydration, baking too cold will result in the dough flattening out quite a lot. The gelatinization of the starch is essential for the dough to hold its structure. After conducting several experiments, it seems that my sweet spot for maximum oven spring seems to be at around \qty{230}{\degreeCelsius} (\qty{446}{\degF}). Test the temperature of your oven, because in several cases the displayed temperature might not match the actual temperature of your oven~\cite{too+hot+baking}. Make sure to turn off the fan of your oven. Most home ovens are designed to vent the steam as fast as possible. If you can not turn the fan off, consider using a Dutch oven. \subsection{Baked with too little steam} \begin{figure}[h] \includegraphics[width=\textwidth]{no-steam} \caption[Bread baked with too little steam]{One of my earlier breads that I~baked at a friend's place where I~couldn't steam the dough properly.}% \label{no-steam} \end{figure} Similar to baking too hot, when baking without enough steam, your dough's crust forms too quickly. It's hard to spot the difference between the two mistakes. I~typically first ask about the temperature and then about the steaming technique to determine what might be wrong with the baking process. Too little steam can typically be spotted by having a thick crust around all around your dough paired with large alveoli towards the edges. The steam essentially prevents the Maillard reaction from happening too quickly on your crust. That's why steaming during the first stages of the bake is so important. The steam keeps the temperature of your crust close to around \qty{100}{\degreeCelsius} (\qty{212}{\degF}). Achieving steam can be done by using a Dutch oven, an inverted tray and/or a bowl of boiling water. You might also have an oven with a built-in steam functionality. All the methods work, it depends on what you have at hand. My default go-to method is an inverted tray on top of my dough, paired with a bowl full of boiling water towards the bottom of the oven. \begin{figure}[ht] \includegraphics[width=\textwidth]{apple-experiment-temperatures} \caption[Measuring ambient and surface temperature]{An apple with 2 probes to measure ambient and surface temperatures of several steaming techniques in a Dutch oven.}% \label{apple-experiment-temperatures} \end{figure} Now there can also be too much steam. For this I~tested using a Dutch oven paired with large ice cubes to provide additional steam. The temperature of my dough's surface would directly jump close to 100°C. The steam contains more energy and thus through convection can heat up the surface of your dough faster. I~tested this by putting an apple inside a Dutch oven and measuring its surface temperature using a barbecue thermometer. I~then changed the steaming methods to plot how quickly the temperature close to the surface changes. I~tested an ice cube inside of a preheated Dutch oven, a plain preheated Dutch oven, a preheated Dutch oven with spritzes of water on the apple's surface and a non-preheated Dutch oven where I~would only preheat the bottom part. The experiment then showed that the ice-cube method would heat up the surface of the apple a lot quicker. When replicating this with a bread dough, I~would achieve less oven spring. \begin{figure}[ht] \input{plots/fig-temperature-surface.tex} \caption[Surface temperature versus steaming technique]{A chart showing how the temperature of the apple's surface changes with different steaming techniques.}% \label{apple-experiment-surface-temperatures} \end{figure} \begin{figure}[ht] \input{plots/fig-temperature-ambient.tex} \caption[Dutch Oven temperature versus steaming technique]{This figure shows how the ambient temperatures inside of the Dutch oven change depending on the steaming technique that is used.}% \label{apple-experiment-ambient-temperatures} \end{figure} Generally though, achieving too much steam is relatively challenging. I~could only make this mistake when using a Dutch oven as the steaming method paired with relatively large ice cubes. After talking with other bakers using the same Dutch oven, it seems that my ice cubes (around \qty{80}{\gram}) were 4 times as heavy as the ones other bakers would use (\qty{20}{\gram}).