An Introduction to the Maillard Reaction: 
The Science of Browning, Aroma, and Flavor 
by Eric Schulze on Serious Eats

   If you're a regular reader of Serious Eats, you've definitely seen us refer 
   to the Maillard reaction time and again. That's because the Maillard reaction 
   is responsible for the browned, complex flavors that make bread taste toasty 
   and malty, burgers taste charred, and coffee taste dark and robust. If you 
   plan on cooking tonight, chances are you'll be using the Maillard reaction to 
   transform your raw ingredients into a better sensory experience.

   But the Maillard reaction doesn't just make food taste delicious. 
   Understanding the reaction, even on a surface level (that's a Maillard pun, 
   and you'll totally get it soon), is a gateway to understanding the chemical 
   and physical processes of cooking. Grasping the variables involved and 
   learning how to manipulate them is one of the best ways to become a more 
   confident cook-it's the difference between being a slave to a recipe and 
   being free to make a recipe work for you.

   The good news is that the Maillard reaction is everywhere, which means plenty 
   of chances to practice and learn. We use it so often that it's easy to forget 
   it's there, but when it's missing, you'll certainly notice. Imagine a steak 
   that tastes boiled instead of roasted, or a stir-fry that tastes more like a 
   stir-steam. Each one represents a missed opportunity to exploit the Maillard 
   reaction's potential.

So, What Is the Maillard Reaction?

   The Maillard reaction is complex. So complex, in fact, that it's only in the 
   last few years that scientists have begun to figure out what it actually is. 
   While they still don't entirely understand it, they do know the basics: The 
   Maillard reaction is many small, simultaneous chemical reactions that occur 
   when proteins and sugars in and on your food are transformed by heat, 
   producing new flavors, aromas, and colors.

   Practically speaking, the Maillard reaction makes food more enticing to us 
   humans, encouraging us to dig into a steak, drink a coffee, or chug a beer.* 
   Unlike all the other omnivores prowling this earth, we no longer tend to find 
   a hunk of raw cow shoulder particularly appetizing. But if that same muscle 
   is ground up, formed into patties, and seared on a flattop, we'll eagerly 
   line up around the block. In large part, that's because we have evolved to 
   respond to two important signals when encountering food. The first is a 
   "nutrition" signal that tells us the food will deliver a hefty dose of easily 
   digestible calories, vitamins, and minerals. The second is a "general 
   harmlessness" signal that tells us the food won't kill us. The Maillard 
   reaction is evolution's way of combining these two signals into one 
   super-signal, specific to the roasty or browned flavors of cooked food.

   * Yes, even beer undergoes the Maillard reaction-when the grains are roasted 
   prior to brewing.

   All that cooking we've come to seek out is, at its heart, the process of 
   applying heat to food over a period of time. If all goes well, it also makes 
   you hungry. A burger, to extend our example, is composed of a basic set of 
   building blocks: proteins, sugars, and water. The Maillard reaction is what 
   can happen to those proteins and sugars when heat and time are added to the 
   equation.

   Long story short: With the right amount of heat, moisture, and time, those 
   specific sugars and proteins will act like a couple of lust-drunk lovers 
   making out in the back of a Chevy, rapidly becoming a tangled, hot mess, 
   until, nine months later, a whole new creation emerges. Except that with the 
   proteins and sugars, it takes minutes, not months, and instead of a child, 
   the result is an increasingly complex array of flavor and aroma molecules, 
   along with a darker color courtesy of newly formed edible pigment molecules 
   called melanoidins.

Heat, Moisture, and Time

   The first thing you need for the Maillard reaction to take place is heat. A 
   steak left to sit on the counter for a week at room temperature will 
   certainly undergo some chemical changes, but the Maillard won't be one of 
   them.

   That steak doesn't just need heat, though-it needs a relatively high level of 
   it if you want surface browning to kick in. Boiling water, which tops out at 
   212F (100C) at sea level, isn't hot enough. That's why a boiled steak turns 
   gray instead of dark brown, exciting the palate of exactly no one.

   The Maillard can work at lower temperatures, and with a lot more water. If 
   you cook a chicken or beef or vegetable stock at a bare simmer for eight or 
   12 hours, the result is still a brown, fragrant liquid-a dead giveaway that 
   the Maillard has occurred.

   But most of us aren't cooking stocks for that many hours, and none of us are 
   boiling a steak for anywhere close to that period of time. Instead, we're 
   roasting, frying, and grilling. These cooking processes happen relatively 
   fast, in minutes rather than hours, and for the Maillard to happen quickly, 
   we need to drive off enough moisture to break free of that 212F cap.

   By cooking a steak in a ripping-hot skillet, you can dehydrate its surface 
   thoroughly enough that the temperatures on that surface will begin to climb, 
   to upwards of 300F (149C). At that point, the Maillard reaction will kick 
   into full gear, creating new flavors, aromas, and the characteristic brown 
   colors that give the reaction its more commonplace name, the "browning 
   reaction."

   This is why it can be a smart move to pat your meat dry with towels or let it 
   dry in the fridge for several hours before you cook it. It's also why you 
   should salt your meat either more than 45 minutes in advance of cooking 
   (allowing enough time for the salt to draw out moisture through osmosis from 
   the meat, which then reabsorbs that salty brine, turning the meat more tender 
   and moist) or immediately before (allowing you to avoid significant moisture 
   loss through osmosis altogether). Ideally, you'll have enough time to combine 
   the two using a technique called dry-brining: salting the meat generously, 
   then letting it air-dry in the fridge at least overnight and up to a few days 
   before cooking. You'll end up with meat that's deeply seasoned while also 
   sporting a nicely dried surface, perfectly primed for maximum Maillard once 
   roasted or seared.

Proteins and Sugars

   Heat, moisture, and time may be key to getting the Maillard reaction going, 
   but without proteins and sugars to work with, it simply won't happen. 
   Proteins are long chains of amino acids, crumpled up like wads of paper. Some 
   of them are Maillard-susceptible, meaning they really love to bond with 
   sugars. But not just any sugar will do. Molecules of complex sugars, like 
   starches or table sugars, are too big to react with Maillard proteins. 
   Instead, these proteins require "reducing sugars," which are essentially 
   simple sugars that attract amino acids at certain moisture and temperature 
   levels.

   That's a critical point: The Maillard reaction starts with a somewhat limited 
   set of proteins and sugar molecules, and, as these bond and mix over time, 
   more and more new molecules are added to the equation. It's kind of an 
   incestuous molecular orgy, when you stop to think about it. (Gross! And 
   also...yum!) These promiscuous molecules mix and match over and over, 
   billions and trillions of times per second, on the surface of a food, forming 
   a growing, recursive, recombinatory aroma and flavor engine.

   This engine is influenced by temperature, time, and pH—all things that home 
   cooks can control. If you want to make lots of flavor and aroma compounds, 
   just raise the pH a little with baking soda (as Kenji does to make 
   quick-caramelized onions for his Pressure Cooker French Onion Soup). Looking 
   for a crisp, browned crust? Just lower the pH with a little acid, or increase 
   the temperature. Want a little of both? Frying in fats gives you the best of 
   both worlds.

But...Why Do We Like It?

   Let's think about the humble potato for a moment. A raw potato, most of
   us would agree, is pretty unappealing. Sure, you can eat a raw potato,
   and it won't hurt you-after all, it's just a large lump of concentrated
   starch, and starch is energy that's essential to our survival. But,
   thanks to the twists and turns of our evolution, we humans can no
   longer efficiently digest that raw spud. Our digestive system would
   struggle to break down a potato's complex starches into simpler ones,
   and it would fail to extract many of the nutrients hidden inside.
   Cooking breaks down the starches and unlocks those nutrients, improving
   their ability to be absorbed into our bodies.

   When we cut up a potato and then roast it, a sequence of events takes
   place. First, the water on the exposed surfaces mostly boils off,
   bursting the starches open into a fluffy mass and breaking them down
   into simpler sugars. As the heat on those surfaces increases due to the
   loss of water, the proteins and broken-down sugars begin to break down
   even more, then recombine. A familiar faint-brown color emerges on the
   surface of each potato chunk. Some of the various protein-sugar
   molecules created on the surface of the now-cooked potato will lift off
   into the hot air above the pan, wafting toward your nose. That smell of
   roasted potatoes tells your body that it's in the presence of a food
   that can provide it with nutrients it not only needs but can readily
   use. Take a bite, and your mouth confirms-it's delicious.

   Now, I can see some of you in the back saying, "Wait a minute-mashed
   potatoes are my fave, and they aren't Maillard-ed at all!" You make an
   important point: Boiled and steamed potatoes, because of the high
   volume of water present during those relatively short cooking
   processes, do not undergo the Maillard reaction, yet can still produce
   delicious results. I'd argue, though, that these potatoes only really
   become delicious once they're mixed with some other source of flavor
   and aroma, like butter. Butter's main flavor molecule is called butyric
   acid, and butyrates, it just so happens, are also the primary aroma
   molecules produced by the Maillard reaction when meats are roasted.
   Almost always, the path leads back to the Maillard reaction.

There's More to Maillard Than Just Maillard

   Here's the next thing you need to know: The Maillard reaction isn't the
   only reaction that can happen to those building blocks of protein,
   sugar, and water—and, depending on the ratios of those building blocks,
   you can get different effects out of the Maillard reaction itself.

   Cookie dough, for example, is made up of the same building blocks as a
   steak. What differentiates the two is the proportions: A steak is
   obviously much higher in protein, while cookies have a lot more sugar.
   This has a profound effect not only on the way in which the Maillard
   reaction occurs, but also on the degree to which these foods experience
   other, related reactions, like caramelization.

   Caramelization is what occurs when sugars are heated and begin to react with 
   water in a process known as hydrolysis, breaking down and reforming into a 
   complex, sweet, nutty, and slightly bitter substance known as...caramel. I 
   like to think of caramelization as a first cousin to the Maillard reaction. 
   When protein levels are low, sugar levels are high, and the temperature is 
   north of 350F (177C)-such as in a batch of cookies baking in the 
   oven—caramelization becomes a much more prominent factor. Like the Maillard 
   reaction, caramelization also produces a darker color and more complex 
   flavor, which is one of the reasons the two are often mistaken for each 
   other.

   Keep in mind that, though different, these reactions are not mutually
   exclusive. Both the Maillard reaction and caramelization can and do
   take place in both a steak and a cookie, but they produce markedly
   different, often complementary, flavors and aromas in each.

   A steak is made of muscle, which is mostly protein and water and
   comparatively little sugar; the high concentration of protein leads to
   a Maillard reaction that yields more flavor molecules and fewer
   aromatic ones. Cookies, on the other hand, are the opposite: With a
   high volume of sugar and relatively little protein, the Maillard
   reaction produces more aromatic compounds and fewer flavor molecules.

   On the other hand, because cookies have more sugar, they also undergo
   more robust caramelization, which contributes flavors that the Maillard
   reaction didn't. The steak, meanwhile, is short on Maillard-produced
   aromas, but thankfully, the scent of its lightly singed fat does the
   trick, contributing the aroma it might otherwise have lacked. The
   ability to leverage both of these processes can help us create more
   delicious food.

   My grandfather used to say that cooking by recipes alone would have
   never given us the magic that is chicken and waffles. Sure, a recipe
   can show you how to make each one separately, but it's experimentation
   that taught us that putting both together tastes better. Knowledge of
   the Maillard reaction reveals my grandfather was even more right than
   he knew. Chicken and waffles go so well together because they are the
   perfect combination of different kinds of Maillard reactions. In the
   waffles, it's a sugar-heavy Maillard that's high on aroma and low on
   flavor; in the protein-heavy chicken, it's the opposite. Together,
   slathered in maple syrup (hello, caramelization!), you have an ideal
   science-driven meal just begging to be consumed.

   It's another reminder that cooking is just edible science-the Maillard
   reaction is our geeky foundation, recipes our experiments, and you, our
   scientist, whose sustenance, satisfaction, and, ultimately, survival
   depend on the results.