Tuesday 2 April 2019

Purpose of my field survey

I am a geologist (sedimentologist) in ​​Japan. This time, from June 2018 to March 2019, I conducted overseas research in United Kingdom, and went around many areas. My living expense was covered by Rutherford Fund Strategic Partner Grants by Universities UK and Green Port Growth Programme by Aura of University of Hull. I appreciate the grants and the persons concerned.

I will introduce my activities in this blog. It would be nice if it could be a reference for researchers in adjacent field and trigger new joint researches, and it would be also nice if people who like geology simply enjoy what I saw and felt. Here I explain the purpose of my field survey in many areas.

My job is geological mapping. We clarify what kind of rock or sediment are distributed where and write a explanatory note in the maps. We also post new findings obtained in the process as academic papers. Geological maps are useful for disaster prevention planning (for earthquake, volcanic eruption, land slide, etc.), resource exploration, land and marine development and general geological researches by researchers.

The truth is always one, but geological maps sometimes have slightly different results depending on the researcher. This is not a subject that which one is correct and the others are mistakes. This is due to summarization. summarization is necessary to explain complex things in an easy-to-understand manner, and the way of extraction are different in view points and purposes. To make maps useful, the ability to identify what is the essence of an object is required. This is similar to the fact that description of a character of a person may differ from person to person.

The knowledge about the formation processes is also required. The results of analysis of the physical properties of sediment are same regardless of researchers, but to clarify the distribution, we have to interpolate because we can get the information only from outcrops distributed discretely. To better interpolation, we use the information about the formation processes (for example, is target sand a part of fans or delta plain or submarine channels ?) and direction of sediment supply. This is difficult to reconstruct. We can observe only the results, and there is no way but to estimate the phenomena leading to the results. It looks like a detective to identify the murderer. Therefore, it is necessary to know a lot of phenomena and results, and geologists have been struggling marine observations, flume experiments and theoretical calculation for the purpose.

I research in Japan and the phenomena that can be observed in Japan are limited. Geology is originated in the Europe, and most of basic theories are produced based on geology in Europe or North America. I use these theories but often need to modify them when I adapt to Japanese sediments because the river slope and the tidal range in Japan are completely different from such pivotal areas.
In order to generalize the new findings about geology in Japan, it is necessary to understand the situation in Europe. And even if I research only in Japan, I can't interpret the sediments using only the knowledge obtained in Japan in many cases, for example, the tidal range is large in the age when the target sediment was formed.
So it is very meaningful for me to observe a wide range of phenomena by my own eyes and from my interests although I can study them in textbooks and academic papers. From such a point of view, I surveyed the coasts of UK to observe a sedimentary processes, sediment and geography not found in Japan in order to improve my research and the skill, find new research topics and the suitable areas, get new view points.

I can not write the details of the survey, but I wrote what is unusual from the perspective of Japanese geologist and what kind of researches can be done in each area.

Monday 1 April 2019

Norfolk Coast (salt marsh, sand flat, bedform)

Norfolk Coast (Norfolk)  5 March to 7 March, 2019

Keywords: Beach, Sand flat, Mud flat, Bedform, Sedimentology

I visited Norfolk Coast to observe tidal flat and beach.
Locality of Norfolk Coast.


Firstly, I visited Brancaster. I could observe the broad salt marsh and mud flat along the promenade (Norfolk coast path) which is on levee to protect the reclaimed land and located next to the main road of the town (A149).
In this marsh and mud flat, We can observe many sedimentary processes as below. I was deeply moved because this was first time to see broad salt marsh which is rare in Japan today although it is often found from ancient sediments.

Salt marsh along the Norfolk coast path. Most of this area is submerged during high tide.

Promenade in salt marsh.


Mud flat in salt marsh.

Meandering channel in mud flat.

Tide pool in salt marsh. There are many burrows. See next figure.

Close-up of burrow. Feces of polychaetes.


Norfolk coast path on levee. Left: salt marsh. Right: reclaimed land.


Norfolk coast path. The way people walk is covered with moss without grass. Fantastic !


Second, I visited Wells-next-the-Sea. From this town, we can easily access to sand flat and beach. In this area, we can observe many kind of bedforms, current and wave ripple, wind ripple which are very useful indicaters of water or wind current when they were formed. The grain size of the ground is various and water current and wave are also various due to the interference of tidal current and local topography. So this may be suitable field to discuss about the effects of grain size to bedform.

Map of Norfolk Coast. Yellow areas are sandy areas, brown areas are muddy areas.


Flat-topped ripple in sand flat.


Close-up of flat-topped ripple. Exactly the same to textbook ! I firstly saw it although I sometimes describe it in ancient sediment.


Variation of direction of ripple crest. left side (landward) is parallel to the channel but right side (seaward) is perpendicular. Left ones are wave ripple and right ones are current ripple ?


Flat-topped ripple perpendicular to coast line.


Transition zone of ripple with two type of directions.


Ripple only in sandy area. Mud prevent ripple development ? How did mud distributed like this ?


Close-up of muddy area.


Close-up of sandy area.


No ripple on mound.


Ripple and sand dune in left with white color.


How can we get the information about the paleo water-current from such a ripple ?


White dry sand transported by wind deposits around obstacles.

Ripple with stepped slope. Is it a result of erosion during falling tide ?

Secondary crests in seaward side of ripple.

White and dry sand is transported by wind from sand dunes and covers the wet and brown sand in beach.


White sand is supplied by wind from sand dune.


Erosional structures by wind.

Close-up of erosional structures.


Sand (white) transported by wind deposits on upwind side of wave ripple.


Wave ripple is changing to wind ripple ? The wind is from lower to upper in this photo.


Friday 29 March 2019

Geology and Cathedrals (Geology & life)

Keyword: Traditional architectures, Geology in life

I visited many towns in UK to observe outcrops, coasts and rivers. In every towns, I found cathedrals and castles build in middle ages. Most of them have a highest towers in the areas and I can climb them. The view from the towers is very useful to glasp geological and geographical background of the area. So (not only for siteseeing), I visited them during my field surveys.
At first, I surprised the beautiful Gothic or Norman style structures made of stones, stained glass and their histories. But next, I began to be interested in the lithology of them. As I visited many areas, I noticed that the lithology of such a old buildings seems to be different depending on areas. It represents the relationships between geology and human activities. Most of the buildings are made of the stones in the area but some ones are made of others. There will be fascinating stories about the history of logistics, culture and politics. Most of Japanese old buildings are made of woods so It is difficult to enjoy and discuss about these topics in Japan.
I am just a geologist (Sedimentologist) in Japan not a specialist in traditional architectures or history in UK. But I would like to introduce the lithology of cathedrals and castles in many areas.
We can easily get the lithological information in each areas from website "Geology of Britain viewer" by British Geological Survey. Please compare and enjoy the lithology of the buildings and geology in the area.

Hartlepool (County Durham), sandy tidal flat deposit
Flaser forks (mud drapes in trough of ripple) which indicate repetition of water current and stop (tide)
Double mud drapes which indicate diurnal inequality of tide.

Herring bone structures which indicate bidirectional flows (tidal currents).

York (North Yorkshire), shallow marine deposit
City wall made of sand stones with cross laminae.
Sand stone with trough cross laminae and borrows.

Frambrough (East Riding of Yorkshire), chalk
Lighthouse made of chalk.

Cromer (Norfolk), flint
Cromer Parish Church made of flint.
Close-up of the church.
Wells (Norfolk), gravel
Wall made of gravels.
Close-up. Flint ?
Norwich (Norfolk), flint
Tower made of flint.
Close-up of the tower.
City wall.
City wall made of flint.
Close-up of the wall. Holes by boring shells.
Close-up of the wall. Limestone (bryozoan sand ?).

Dover (Kent), flint
City wall made of flint.
St. Marys Church in Dover made of flint.
Close-up of wall made of filnt.

Portchester (Hampshire)
Portchester Castle near tidal flat and chalk bed with white color.
Outer wall of Portchester Castle. It is originally made of flint and repaired by other stones.
Inside of the castle. It has been repaired many times and by various stones, including bricks.
Close-up of inside wall of the castle.


Nottingham (Notthinghamshire)
Outer wall of Nottingham Castle. The lower is natural sand stone.
Close-up of the wall with cross bed.
Close-up of the wall.
Sand stone in the castle. The half of the pub, oldest in England, is in the sand stone.
We  can enjoy ale and attractive sedimentary structures at the same time !


Bath (Somerset)
Sand stone with trough cross laminae in thermae (public bath in Roman style).
It was constructed during ancient Roman periods and repaired during the Middle Age.

Bristol (South West England)
Wall made of schist ?

Cardiff (Wales)
Outer wall of Cardiff Castle. It was repaired many times.
Close-up of the wall. Sand stone with many shells.
Close-up of the wall. Poor sorted sand-gravel stone.
Close-up of the wall. Sand stone with many shells.
Close-up of the wall. Gravel.

Cotswolds (Gloucestershire), honey-colored limestone
Beautiful buildings with honey color.
Beautiful buildings made of limestone and flint.
Fence made of limestone.
Close-up of honey-colored stones.
Close-up of buildings made of flint and limestones.

Windermere (Lake District, Cumbria), schist
Windermere with buildings made of schist (?).

Fence made of schist (?).

Church made of schist (?).
Close-up of buildings made of schist (?).