Add to ORKGSupplementary material 1. Core lithology corresponding to spike horizons in reported visual core descriptions. Supplementary material 2. Major-element compositions of ATHO-G (a secondary standard glass of the MPI-DING series) and glass shards from tephras. Supplementary material 3. Major-element compositions of cummingtonite grains from tephras. Supplementary material 4. Comparison of data obtained by using different EPMA systems
Electron microprobe analyses were conducted on volcanic glasses extracted from Holocene tephra marke...
Tephrochronology, the characterisation and use of volcanic-ash layers as a unique chronostratigraphi...
We assessed sediment coring, data acquisition, and publications from the North Pacific (north of 30°...
Appendix S1: Major element compositions (by SEM-EDS) of volcanic glass shards from tephras intercala...
AbstractWe refine the tephrostratigraphy and cryptotephrostratigraphy of the Middle Pleistocene deep...
Major element geochemical composition was established for 59 tephra horizons from Ocean Drilling Pro...
Five widespread upper Cenozoic tephra layers that are found within continental sediments of the west...
We reinvestigated tephra and cryptotephra stratigraphy of the Late Pleistocene deep-sea C9001C cores...
AbstractWe investigated late Quaternary deep-sea sequences of the C9001C cores (D/V Chikyu shakedown...
The main goal of the study is to establish the spatial and temporal distribution of pyroclastic mate...
The main goal of the study is to establish the spatial and temporal distribution of pyroclastic mate...
This paper presents the first detailed study of a late Pleistocene marine tephra sequence from the N...
The study of ‘non-visible’ tephra layers (cryptotephra) can provide insight into the volcanic histor...
Electronic Supplement Table S1. Electron microprobe analysis data for glass shards: control (non-tre...
Highlights: • Ca. 418 ka Pauzhetka tephra from South Kamchatka was found in 11 marine sediment core...
Electron microprobe analyses were conducted on volcanic glasses extracted from Holocene tephra marke...
Tephrochronology, the characterisation and use of volcanic-ash layers as a unique chronostratigraphi...
We assessed sediment coring, data acquisition, and publications from the North Pacific (north of 30°...
Appendix S1: Major element compositions (by SEM-EDS) of volcanic glass shards from tephras intercala...
AbstractWe refine the tephrostratigraphy and cryptotephrostratigraphy of the Middle Pleistocene deep...
Major element geochemical composition was established for 59 tephra horizons from Ocean Drilling Pro...
Five widespread upper Cenozoic tephra layers that are found within continental sediments of the west...
We reinvestigated tephra and cryptotephra stratigraphy of the Late Pleistocene deep-sea C9001C cores...
AbstractWe investigated late Quaternary deep-sea sequences of the C9001C cores (D/V Chikyu shakedown...
The main goal of the study is to establish the spatial and temporal distribution of pyroclastic mate...
The main goal of the study is to establish the spatial and temporal distribution of pyroclastic mate...
This paper presents the first detailed study of a late Pleistocene marine tephra sequence from the N...
The study of ‘non-visible’ tephra layers (cryptotephra) can provide insight into the volcanic histor...
Electronic Supplement Table S1. Electron microprobe analysis data for glass shards: control (non-tre...
Highlights: • Ca. 418 ka Pauzhetka tephra from South Kamchatka was found in 11 marine sediment core...
Electron microprobe analyses were conducted on volcanic glasses extracted from Holocene tephra marke...
Tephrochronology, the characterisation and use of volcanic-ash layers as a unique chronostratigraphi...
We assessed sediment coring, data acquisition, and publications from the North Pacific (north of 30°...