Particle size distribution analyses of volcanic ash from Campi Flegrei (Italy) and Sakurajima (Japan) volcanoes

Cite as:

Del Bello, Elisabetta; Taddeucci, Jacopo; Scarlato, Piergiorgio; Giacalone, Emanuele (2017): Particle size distribution analyses of volcanic ash from Campi Flegrei (Italy) and Sakurajima (Japan) volcanoes. GFZ Data Services. https://doi.org/10.5880/fidgeo.2017.013

Status

I N R E V I E W : Del Bello, Elisabetta; Taddeucci, Jacopo; Scarlato, Piergiorgio; Giacalone, Emanuele (2017): Particle size distribution analyses of volcanic ash from Campi Flegrei (Italy) and Sakurajima (Japan) volcanoes. GFZ Data Services. https://doi.org/10.5880/fidgeo.2017.013

Abstract

This data publication includes particle size distribution data of natural volcanic ash samples used as starting material for laboratory experiments simulating the aggregation/disaggregation of colliding volcanic ash particles. Full details of the experimental method can be found in Del Bello et. al. (2015) and in the data description file provided here.

Here we report raw particle size distribution data obtained through separation analysis. Two types of volcanic ash were analysed: i) andesitic ash from the Sakurajima volcano (Japan), collected from July 2013 deposits (named Sak sample); ii) phonolitic ash collected from the basal fallout layer of the ~10 ka old Pomici Principali eruptive unit [Di Vito et al., 1999]) of the Campi Flegrei (named Ppa). For both compositions, 3 different starting materials were obtained by hand sieving the natural samples into three main particle size classes: (i) <32 μm, (ii) 32–63 μm, and (iii) 63–90 μm. For the phonolitic composition Ppa two additional starting materials were obtained by mixing the <32 μm and the 32–63 μm classes in known proportions.

For each starting material, the grain size distribution of the sample was measured by a multiwavelength separation analyzer (LUMIReader®, https://www.lum-gmbh.com/lumireader_en.html). This device measures space and time resolved profiles of the transmitted light across the water-diluted sample (5% solid content) during sedimentation of particles. The cumulative volume-weighted particle size distribution is obtained from the extinction profiles using the multi-wavelength Particle size Analyser modulus (PSA). Details on the sample preparation procedure can be found in Detloff et al. (2006).

For each measurement performed (see Table 1), a pdf file and a excel file are provided. The pdf file lists the analysis summary, including a description of the analysis settings and conditions, materials used, and distribution model adopted for the fit. It also provides graphs of the obtained volume weighted cumulative grain size distribution, and of the measured transmission profiles for each wavelength (870 nm, 630 nm and 470 nm, respectively). The Excel (*.xlsx format) file include 4 datasheets, listing the results (sheet name ending *_R) and the fit data (sheet names ending *_F01,*_F02, *_F03) obtained for the different instrument wavelength. In each datasheet the following data are listed in the columns: particle grain size (x3 in µm), volume weighted distribution (Q3(x) in %), Martin diameter (x3m in µm), volume weighted density distribution (q3(x) in 1/µm). The fit datasheets also include information on the fit such as distribution model used and distribution parameters (quantiles, median, standard deviation, span, etc..).

A full list of the files included is given in List_of_files_DelBello et al 2017.pdf.

Measurement name Sample type Size class (µm)*
Ppamag32_01 Phonolite (Ppa) 32-63
Ppamag32_03 Phonolite (Ppa) 32-63
Ppamag32_61 Phonolite (Ppa) 32-63
Ppamag64_01 Phonolite (Ppa) 63-90
Ppamin32_00 Phonolite (Ppa) <32
Ppamin32_02 Phonolite (Ppa) <32
Ppamin32_35 Phonolite (Ppa) <32
Ppamix32_02 Phonolite (Ppa) <32 + 32-63 (1:1)
Ppamix32_03 Phonolite (Ppa) <32 + 32-63 (1:10)
Ppamix32_04 Phonolite (Ppa) <32 + 32-63 (1:5)
Ppamix32_05 Phonolite (Ppa) <32 + 32-63 (1:2)
Ppamix32_06 Phonolite (Ppa) <32 + 32-63 (1:1)
Ppamix32_70 Phonolite (Ppa) <32 + 32-63 (1:10)
Ppamix32_71 Phonolite (Ppa) <32 + 32-63 (1:5)
Ppamix32_72 Phonolite (Ppa) <32 + 32-63 (1:2)
Ppamix32_73 Phonolite (Ppa) <32 + 32-63 (1:1)
Ppamix63_02 Phonolite (Ppa) <32 + 63-90 (1:1)
Ppatotal_01 Phonolite (Ppa) total
Sakmag32_02 Andesite (Sak) 32-63
Sakmag63_01 Andesite (Sak) 32-63
Sakmag90_01 Andesite (Sak) 63-90
Sakmin32_01 Andesite (Sak) <32
Sakmin32_02 Andesite (Sak) <32
Saktotal_01 Andesite (Sak) total

Table 1. List of particle size characterization measurements included in this dataset. *When mixed sample are used, the respective weight proportion of the component classes used are reported in brackets.

Authors

Del Bello, Elisabetta;Istituto Nazionale di Geofisica e Vulcanologia, Rome, Italy
Taddeucci, Jacopo;Istituto Nazionale di Geofisica e Vulcanologia, Rome, Italy
Scarlato, Piergiorgio;Istituto Nazionale di Geofisica e Vulcanologia, Rome, Italy
Giacalone, Emanuele

Contact

Del Bello, Elisabetta (Researcher) ; Isitituto Nazionale di Geofisica e Vulcanologia;

Contributors

HP-HT Laboratory of Experimental Volcanolgy and Geophysics (INGV, Italy)

Keywords

multi-wavelength separation analyser, grain size distribution, phonolite, andesite, EPOS, multi-scale laboratories, rock and melt physical properties, ash_and_lapilli, phonolilte, Grain size distribution, Particle Analyzer, Grain size distribution, Particle Analyzer, andesite, ash_and_lapilli, phonolilte