(Brief Introduction) 150-200 words Importance of Subsurface mapping 1. Understanding subsurface (lithology, structure...): important in several discipline: geotechnical engineering, volcanology, geomorphology, civil engineering, economic geology... 2. Drilling borehole: traditional method, but invasive 3. Geophysical survey: non-invasive method to image the subsurface

Ambient noise as alternative geophysical survey method 4. Example of geophysical survey technique: electrical resistivity, gravity anomaly, seismic 5. Geophysical survey is more convenient in seismic active region: more active seismic source for correlation 6. For less seismic region: Use of ambient noise: raising usage and thus attention

Draft 2 Most of the geological maps only show the superficial deposits and outcrops, which allows the public to discover the geological structures that are above the sea surface. For most of the geology related disciplines, such as geotechnical engineering, volcanology, geomorphology, civil engineering, exploration geology, however, understanding on the subsurface structures and to a small extent, lithology, is as important as those on surface. One of traditional method would be borehole drilling but it is invasive to the ground surface. Instead, geophysical survey is a non-invasive alternative for subsurface exploration and thus subsurface mapping.

Major geophysical survey techniques include electrical resistivity, gravity anomaly and seismic. Seismic survey is particularly reliable on the detection of subsurface rock structures and even hydrocarbons. Seismologists attempt to correlate the velocity anomaly with the geological structure after the collection and further analysis of the seismic signals. The collection of seismic signals is easier for regions with frequent earthquakes. For some seismic inactive regions like Korea Peninsula, however, the seismic signal analysis is more difficult^[1]. Instead of the correlation from strong seismic sources like earthquake, the potential of ambient noise on subsurface structure mapping is discovered in recent years, which will be introduced below.

Part 1: Source of Ambient Noise 700-800 words 1. Brief description of seismic source

  1.1 1st stage of seismic research: seismic noise collection
  1.2 seismic noise primary classification
     1.2.1 active: airgun, hammer, can generate apparent seismic pulse; large source like explosion, similar magnitude as earthquake
     1.2.2 passive: background noise, either natural or humane
  1.3 Increasing application of passive seismic noise on seismic research

2. Nature of Ambient Noise

  2.1 Anthropogenic
     2.1.1 Commerical shipping
     2.1.2 Seismic Exploration
     2.1.3 Urban traffic and other activities
  2.2 Natural Noise
     2.2.1 Earthquake
     2.2.2 Ocean wave, wind
     2.2.3 Typhoon

3. Variation of Ambient Noise

  3.1 Cause of variation
  3.2 Examples

Draft 2 Data collection of ambient noise is the prior stage of subsurface mapping, which is important for further analysis and correlation. The seismic noise can be transmitted either body wave (P-wave, S-wave) or surface wave (Rayleigh wave, Love wave), so as the constructed velocity models. For some of the seismic research and exploration, active seismic sources would be created intentionally to record the velocity change of seismic waves. Some examples of tools creating active seismic source include hammer[note1], airgun, and even artificial explosion, which may create seismic waves with similar magnitude as large earthquakes. Other than the artificial seismic sources, passive ambient noise can also be recorded and analysed. Ambient noise refers to the background noise originated either from natural events or anthropogenic activities. The use of ambient noise on velocity structure modelling has received more attention, especially in seismically inactive regions.

From an extensive range of frequency, ambient noise can be further classified into several categories, which are based on their origins.

The anthropogenic ambient noise, excluded those artificial seismic sources produced intentionally for research, are originated from human activities. Considering the ocean ambient noise source as an example, there are noises that are created unintentionally by human activities, such as shipping and offshore engineering work[ref2]. The importance of shipping reflects on the well-developed trading and commercial industries. International immigration and emigration of products and goods can be done via shipping. The shipping activities are thus becoming frequent. During the shipping process, the mechanical waves can be driven up along water surface and propagate through the ocean. Other than shipping, offshore engineering work can also produce surface waves. Engineering works, which are usually done on the continent to usually fulfil the demand of urban development, include but not limited to borehole drilling, foundation construction and geophysical surveys. Extended from the continent, reclamation has been actively carried out by many countries to create more land for urban development. Those engineering works can thus also be carried out offshore. The processes of offshore drilling and exploration create continuous mechanical waves that can also propagate through ocean.

Regarding the continental urban areas, there are more examples of human activities creating the background noise. Other than the engineering works, the urban traffic is the major component of urban ambient noise. Although the mechanical waves of the continent are not as visible than those from the ocean, they can still be transmitted via the soil and rock layers. Cars travelling on the road can produce repeatable vibration on the road which can then be transmitted through the soil layers.

Natural ambient noise refers to the background noise produced from the natural events. Our natural environment is not stationary but constantly changing every moment because the nature itself is continuously modified by the weather, tectonic movements and biogenic activities. They can also produce low frequency background noise that can be further analysed. Some of the most significant events are listed below.

Earthquake, as mentioned before, is one of the most remarkable events that can produce the most significant background noise. Earthquakes can be caused by the movement along two faults or plates. Seismic waves are released and penetrate through the soil and rock layers, causing the continents to shake. There are numerous earthquakes happened every day with different scales around the world. By recording the seismic waves produced from the earthquake, we can further understand the interior structure of the Earth.

The ocean wave is another possible natural ambient noise source. As mentioned before, the ocean wave can be produced by anthropogenic activities, such as commercial shipping and offshore engineering work. Besides, natural wind and marine animals can also induce weak ocean wave propagating through the ocean, which can be recorded by seismometers.

Other than the natural ambient noise propagated through solid and liquid, ambient noise propagated via air can also be recorded if it is strong enough. One of the examples is typhoon. Typhoon is one of the natural hazards whose frequency and strength are magnified by global warming. The strong thermal current creates a low-pressure zone where the air can circulate around the centre. In such case, the vibration of the air is strong enough to be recorded by seismometers.

To evaluate whether the collected ambient noise source can be further analysed, we must carefully consider if there are any regular variations or patterns of certain ambient noise source. Referring to the urban noise source, it may experience a daily variation, where the human activities are conducted mostly in daytime and reduced in nighttime. The ambient noise should thus increase in daytime while reduce in nighttime. Apart from the temporal variation, the spatial variation can also matter. For example, the commercial shipping is usually concentrated on certain routes. The corresponding amplitude of ambient noise should also decrease when moving away from the shipping routes. Nevertheless, it is still difficult to distinguish the ambient noise sources.

Part 2: Seismic Velocity Structure Modelling 700-800 words 1. Data collection method

  1.1 Tools of collection
  1.2 Available online source

2. Ambient noise correlation

  2.1 cross correlation
  2.2 green's function
  2.3 Inversion

3. Subsurface structure correlation with velocity imaging

  3.1 example of subsurface structure
  3.2 linkage of structure with velocity zone
     3.2.1 low-velocity zone
     3.2.2 high-velocity zone

4. Limitation

  4.1 Factors affecting quality of resolution

The collected ambient noise can be further analysed to produce velocity structure maps which are used to correlated with the possible subsurface structures. The processes involved are complex and require multiple mathematical calculations.

As mentioned before, the data collection of ambient noise is the primary step of any seismic research. The most common tool for seismic data collection is the seismometer. Other example could be the geophones. There are also seismic stations or observatories authorized by different official bodies. For example, Hong Kong Observatory has set up several seismic stations in different locations in Hong Kong. The seismic waves are recorded by the seismometers and shown as seismographs. Semimoist and geophysicists can then identify the arrival time of different body waves and surface waves. The seismic waves usually arrive in the order of P-wave, S-wave, Rayleigh wave, and Love wave. Nevertheless, the analysis of ambient noise is more difficult than simply identify the waves above.

Compared the seismographs of ambient noise with those recording active seismic sources, or simply reviewed any seismographs, you can discover the 'thickness' of the seismic waves. Despite the occasional increase in amplitude due to the active seismic source, the entire seismic waves are also in certain amplitudes, showing that there are certain activities that also produce weak seismic waves. The ambient noise seismographs are required to correlate together such that the velocity map can be produced.

Cross-correlation is a widely used tool in several aspects. It is used to discover the time difference between two events and the factors behind. In seismology, cross correlation is also used in analysing the ambient noise. The basic idea of ambient noise cross correlation is to find the green's function of the two seismic ambient noise. Imagine if there are two seismic stations with one seismic source. The seismic wave will arrive both seismic stations at different time if their distances from the seismic sources are different. Seismologists try to find the travelling time lag between two stations. Expanding the sample into an area with multiple ambient noise sources, the seismic waves from the two stations can be cross-correlated if the source distribution is even across the whole sample area. Otherwise, the green's function will be uneven and difficult to correlate any relationship between two factors.

Inversion of a function involving finding the origin

Part 3: Application of Subsurface Mapping 700-800 words 1. Exploration of underground mines 2. Volcano Monitoring 3. Landslide Monitoring