모멘트 규모(Moment Magnitude Scale) 이해하기

What Seismic Moment Tells Us About Earthquakes

To understand the Moment Magnitude ScaleThe modern standard for measuring earthquake size (Mw), based on the seismic moment — the product of fault area, average slip, and rock rigidity. Accurate for all earthquake sizes. scale, you must first understand seismic moment — the physical quantity it measures. Seismic moment (M0) is the most fundamental description of earthquake size, rooted directly in the mechanics of fault rupture rather than in any instrumental quirk. It captures three essential physical properties of an earthquake: how large an area of the fault ruptured, how far the two sides of the fault slipped past each other, and how rigid the rock surrounding the fault is.

The intuition is straightforward. Imagine tearing a piece of paper. The larger the tear, the further the paper has separated, and the stiffer the paper, the more energy was released. Seismic MomentA measure of the total energy released by an earthquake, calculated as the product of the fault area, average displacement, and the shear modulus of the rocks. The basis of moment magnitude. works exactly the same way. A great earthquake like the 2011 Tohoku event ruptured a fault area roughly 500 kilometres long and 200 kilometres wide, with average slip of perhaps 20 metres, in very rigid oceanic crust — yielding a seismic moment so enormous it dwarfs nearly all other recorded earthquakes.

The Formula: Fault Area x Slip x Rock Rigidity

The seismic moment is defined as M0 = μ × A × d, where μ (mu) is the rigidity of the rock (typically around 30 GPa for crustal rock), A is the area of the Fault RuptureThe breakage of rock along a fault during an earthquake, releasing stored elastic energy as seismic waves. Rupture length can range from meters (small quakes) to 1,000+ km (great earthquakes). surface, and d is the average displacement (slip) across that surface. All three quantities must be measured or estimated from seismological data, geodetic measurements, or field observations.

The Moment Magnitude ScaleThe modern standard for measuring earthquake size (Mw), based on the seismic moment — the product of fault area, average slip, and rock rigidity. Accurate for all earthquake sizes. (Mw) is then derived from seismic moment using a formula established by Hanks and Kanamori (1979): Mw = (2/3) × log10(M0) − 10.7, where M0 is in dyne-centimetres. This formula is deliberately scaled so that Mw values align closely with the Richter ScaleThe original logarithmic magnitude scale developed by Charles Richter in 1935 to measure local earthquake magnitude. Largely replaced by moment magnitude but still commonly referenced in media. for moderate earthquakes, providing continuity with the historical record. The logarithm compresses the enormous range of seismic moments — spanning more than 20 orders of magnitude from micro-earthquakes to mega-quakes — into the familiar 0–10+ MagnitudeA single number that quantifies the total energy released by an earthquake. Each whole number increase represents roughly 31.6 times more energy released. range.

Advantages Over Richter Scale and Other Scales

The primary advantage of Mw over the Richter ScaleThe original logarithmic magnitude scale developed by Charles Richter in 1935 to measure local earthquake magnitude. Largely replaced by moment magnitude but still commonly referenced in media. and other earlier scales is that it does not saturate. Earlier scales were based on specific wave types or frequency ranges that become insensitive at large earthquake sizes. The original Richter local magnitude saturates around M 6.5–7.0; surface wave magnitude saturates around 8.0–8.5. Moment magnitude, anchored in the true physical size of the earthquake, keeps growing for the largest events ever recorded.

Mw is also physically meaningful in a way earlier scales were not. Because it is derived from seismic moment, it can be independently verified by multiple methods: long-period seismogram analysis, field measurements of fault slip, InSAR (Interferometric SAR)A satellite radar technique that measures ground deformation with centimeter accuracy by comparing radar images taken before and after an earthquake. Reveals fault slip patterns. satellite geodesy measurements of ground deformation, and GPS geodesy (GPS GeodesyThe use of Global Positioning System receivers to measure tectonic plate motion and crustal deformation with millimeter precision. Reveals how strain accumulates on faults between earthquakes.) that tracks how the ground moves before and after the event. The convergence of these independent estimates gives scientists high confidence in Mw values for well-studied earthquakes.

Another practical advantage: Mw is defined globally and does not depend on local calibration curves. The Richter ScaleThe original logarithmic magnitude scale developed by Charles Richter in 1935 to measure local earthquake magnitude. Largely replaced by moment magnitude but still commonly referenced in media. was calibrated specifically for Southern California. When seismologists tried to apply it elsewhere, they needed correction factors. Mw requires only the seismic moment, which can be estimated from any well-calibrated global Seismic NetworkA coordinated group of seismograph stations that continuously monitor earthquake activity. The Global Seismographic Network (GSN) includes 150+ stations providing worldwide coverage..

How Seismologists Calculate Mw in Real Time

Modern seismological agencies estimate moment magnitude by analysing the long-period content of seismograms recorded on Broadband SeismometerA seismometer capable of recording seismic waves across a wide frequency range (0.001-50 Hz). The primary instrument in modern global seismograph networks. networks around the world. When a significant earthquake occurs, automated systems at USGS (United States Geological Survey)The primary US government agency responsible for monitoring earthquakes, operating the National Earthquake Information Center, and publishing real-time earthquake data worldwide. and national agencies like Japan's JMA ingest data from dozens or hundreds of stations simultaneously.

The key step is determining the seismic moment tensor — a mathematical representation of the earthquake's focal mechanism that encodes the orientation of the fault, the direction of slip, and the seismic moment. Automated algorithms can produce an initial moment tensor solution and a preliminary Mw estimate within minutes of a major event, good enough for tsunami warning systems and initial response decisions. A more precise solution is refined over hours to days as more data are processed.

For very recent earthquakes, the first reports may cite a slightly different value than the final Mw. This is normal and reflects the iterative nature of the process. Initial estimates from body-wave analysis may differ slightly from the final centroid moment tensor solution, but for earthquakes above about magnitude 5.0 the differences are usually small.

Notable Earthquakes on the Moment Magnitude Scale

The moment magnitude scale's ability to handle extreme events is best illustrated by the largest earthquakes ever recorded. The 1960 Valdivia, Chile earthquake holds the record at Mw 9.5 — a rupture that broke approximately 1,000 kilometres of the subduction zone boundary between the Nazca and South American plates. The seismic moment of this single event was so large that it represents a substantial fraction of all the energy released by earthquakes worldwide in the entire 20th century.

The 1964 Alaska Good Friday earthquake (Mw 9.2) remains the second-largest in the instrumental record, followed by the 2004 Indian Ocean earthquake (Mw 9.1–9.3) and the 2011 Tohoku, Japan earthquake (Mw 9.0–9.1). At the other end of the scale, modern high-sensitivity networks can detect earthquakes with negative magnitudes — tiny events releasing less energy than a firecracker. The Mw scale thus spans an enormous dynamic range with a single consistent formula, a feat that no earlier magnitude scale could match.