Grind Size Guide

Visual grind size reference for every brewing method. Compare particle sizes from Turkish (extra fine) to cold brew (extra coarse) with visual examples. Includes grinder setting recommendations for popular grinders.

Calculator

Extra Fine Extra Coarse
100μm 300 500 800 1200μm
Contact Time
Темп. воды
Соотношение
Texture

Tip:

Particle sizes based on standard burr grinder settings. Blade grinders produce inconsistent particles.

How to Use

  1. 1
    Identify your brewing method

    Select your brewing method from the guide — each method has a specific grind size range based on contact time and extraction mechanism. Espresso uses very fine grinds for 25-30 second extraction under pressure; cold brew uses very coarse grinds for 12-24 hour immersion.

  2. 2
    Reference the particle size chart

    Locate your target grind size on the particle size spectrum, measured in microns. Espresso targets 200-300 microns; pour-over 600-800 microns; French press 800-1,000 microns. Use this as your starting dial position when setting a new grinder.

  3. 3
    Adjust based on taste feedback

    Taste your brew and adjust grind size in small increments based on flavor. If it tastes sour and thin (under-extracted), grind finer to increase surface area and slow flow. If it tastes bitter and dry (over-extracted), grind coarser to reduce contact time and surface area.

About

The Grind Size Guide maps the physical relationship between particle size and extraction across all major brewing methods, translating the technical complexity of coffee grinding into practical, actionable guidance. Coffee grinding is not simply 'making it smaller' — it is the precise engineering of surface area and flow resistance to achieve a target extraction yield within a specific time window. Every brewing method has a grind size range optimized for its contact time, water temperature, and flow dynamics.

Particle size distribution — not just average grind size — is what separates exceptional coffee from mediocre coffee. A grinder producing uniform particles within a narrow size range extracts far more evenly than one producing the same average size with high variance. Fines (very small particles below 100 microns) extract almost instantaneously and disproportionately contribute bitterness and turbidity. Coarse particles extract slowly and contribute under-extracted, sour notes. The ideal distribution minimizes both extremes. This is why grinder quality is consistently identified by coffee professionals as the single highest-impact equipment investment.

Understanding grind size also enables you to adapt when circumstances change. A bean lot from a different harvest year may be denser or less dense than the previous crop. Seasonal humidity changes affect how grounds flow through a filter. A new bag of the same coffee from a different roast date will behave differently as CO2 content changes with rest time. The Grind Size Guide gives you the framework to make informed, incremental adjustments rather than starting from scratch each time conditions shift.

FAQ

Why does grind size affect coffee flavor so dramatically?
Grind size controls two critical variables simultaneously: the surface area exposed to water and the flow resistance (in contact methods). Finer grinding creates more surface area by breaking coffee particles into smaller pieces, allowing water to access more of the soluble compounds per unit of time. In pour-over, finer grinds also slow the flow rate through the filter bed, extending contact time. Both effects increase extraction yield. The relationship is not linear — there are diminishing returns and quality thresholds. Over-grinding beyond the optimal surface area extracts bitter, high-molecular-weight tannins and polyphenols that are less soluble and require more aggressive extraction conditions.
What is the difference between burr and blade grinders?
Burr grinders use two abrasive surfaces (burrs) to crush coffee between them at a controlled gap, producing relatively uniform particle sizes. Blade grinders use spinning blades that chop randomly, producing a bimodal distribution — very fine dust mixed with large chunks. The fine particles over-extract (bitter), the large pieces under-extract (sour), and the result averages out to a flat, muddled cup. Even inexpensive flat or conical burr grinders produce dramatically more uniform particle size distributions than blade grinders. The SCA's brewing protocols specify burr grinding as a requirement for controlled brewing experiments, and virtually all specialty coffee preparation uses burr grinders for this reason.
How do conical burrs differ from flat burrs?
Conical burrs use a tapered inner burr that nests inside an outer ring, creating a long cutting path that grinds coffee through shear and compression forces. They generally run at lower RPM, generate less heat, and produce a bimodal distribution skewed toward larger particles — often described as producing sweeter, rounder flavors. Flat burrs use two parallel rings that grind through direct impact, running at higher RPM and producing a tighter, more unimodal particle distribution — often associated with clarity, brightness, and more defined acidity. High-end competition grinders use either geometry to achieve specific flavor profiles. Neither is objectively superior; they produce characteristically different flavor expressions from the same beans.
Does roast level affect how I should grind?
Yes, roast level significantly changes coffee's physical structure and therefore how it responds to grinding. During roasting, CO2 pressure and heat cause the cellular structure of coffee beans to become progressively more porous and brittle. Dark roasted beans are physically more fragile — they shatter more easily and generate more fine particles (fines) at any given grind setting compared to the same setting used on lighter roasts. This means dark roasts often need a slightly coarser grind setting to achieve the same effective particle distribution and extraction time as light roasts. Conversely, very dense, high-altitude light roasts resist shattering and may need a finer setting or higher RPM to achieve adequate particle breakdown.
How does grinder consistency affect coffee quality?
Grinder consistency refers to the reproducibility of the particle size distribution from one grind session to the next and within a single dose. High-quality grinders with precision-machined burrs, stable motor speeds, and minimal wobble produce the same distribution reliably. Inconsistency manifests as varying extraction times from shot to shot with no recipe changes — the grinder is not delivering the same particle distribution each time. Burr alignment also matters: even slightly misaligned burrs produce more fines on one side, increasing extraction unevenness. Professional baristas recalibrate grinders whenever they notice shot time variation, and high-volume cafes perform burr alignment checks seasonally. For home use, single-dose grinders with static brushes or RDT (Ross Droplet Technique) significantly reduce fines migration and retention.