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gsloid: global sea level and oxygen isotope data

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The goal of gsloid is to make available raw data for sea level curves and 18O curves for the Holocene and most of the Pleistocene.

Installation

You can install gsloid from CRAN with:

inistall.pacakges("gsloid")

Or you can install the development version of gsloid from github with:

# install.packages("devtools")
devtools::install_github("benmarwick/gsloid")

Overview

This package includes commonly used datasets in palaeoecology and archaeology:

There are many possible sources for these kinds of data, this package includes data from:

Dataset Source
lisiecki2005 Lisiecki, L.E. and M.E. Raymo. 2005. A Pliocene-Pleistocene stack of 57 globally distributed benthic D18O records. Paleoceanography, Vol. 20, PA1003, https://doi.org/10.1029/2004PA001071
spratt2016 Spratt, Rachel M. and Lorraine E. Lisiecki 2016. A Late Pleistocene sea level stack. Climate of the Past. Vol. 12, 1079-1092, https://doi.org/10.5194/cp-12-1-2016

You must cite those sources in the table above if you use the data in this package.

Here’s the structure of the main data sets:

library(gsloid)
str(lisiecki2005)
#> 'data.frame':    2115 obs. of  3 variables:
#>  $ Time : num  0 1 2 3 4 5 6 7 8 9 ...
#>  $ d18O : num  3.23 3.23 3.18 3.29 3.3 3.26 3.33 3.37 3.42 3.38 ...
#>  $ Error: num  0.03 0.04 0.03 0.03 0.03 0.03 0.04 0.04 0.03 0.04 ...
str(spratt2016)
#> 'data.frame':    799 obs. of  9 variables:
#>  $ age_calkaBP            : num  0 1 2 3 4 5 6 7 8 9 ...
#>  $ SeaLev_shortPC1        : num  8.49 7.63 4.01 4.35 3.13 ...
#>  $ SeaLev_shortPC1_err_sig: num  5.23 4.87 4.83 4.72 4.74 4.57 5.04 5.9 6.79 8.3 ...
#>  $ SeaLev_shortPC1_err_lo : num  -1.72 -2.9 -4.51 -6.93 -10.43 ...
#>  $ SeaLev_shortPC1_err_up : num  17.93 16.39 13.59 12.08 8.41 ...
#>  $ SeaLev_longPC1         : num  8.96 7.72 5.96 3.54 1.88 0 -2 -5.38 -7.12 -11.6 ...
#>  $ SeaLev_longPC1_err_sig : num  5.72 5.13 4.69 4.42 4.39 ...
#>  $ SeaLev_longPC1_err_lo  : num  -1.21 -2.77 -5.01 -7.28 -10.54 ...
#>  $ SeaLev_longPC1_err_up  : num  20.38 17.1 14.21 10.9 7.63 ...
str(LR04_MISboundaries)
#> 'data.frame':    232 obs. of  7 variables:
#>  $ MIS_Boundary     : chr  "1/2" "2/3" "3/4" "4/5" ...
#>  $ start_MIS        : chr  "1" "2" "3" "4" ...
#>  $ end_MIS          : chr  "2" "3" "4" "5" ...
#>  $ label_MIS        : chr  "1" "2" "3" "4" ...
#>  $ LR04_Age_ka_start: num  14 29 57 71 82 87 96 109 123 130 ...
#>  $ LR04_Age_ka_end  : num  0 14 29 57 71 82 87 96 109 123 ...
#>  $ LR04_Age_ka_mid  : num  7 21.5 43 64 76.5 ...

Detailed descriptions of the variables are avaliable in the data documentation, run ?lisiecki2005, ?spratt2016 and ?LR04_MISboundaries for more information.

Usage

Atlhough these data are suitable for many kinds of analyses, the primary reason that I made this package is so I can easily make my own plots of these data. Here’s how I typically start with plotting the oxygen isotope data. I have set limits on the x-axis so it only shows 0-250 ka because that’s what I’m interested in:

library(ggplot2)


ggplot(lisiecki2005, 
       aes(Time,
           d18O)) +
  geom_line() +
  scale_x_continuous(limits = c(0, 250),
                     name = "x 1000 years ago") +
  scale_y_reverse(name = bquote(delta^18*O)) +
  theme_bw()

And here’s how I start to plot the sea level data:

ggplot(spratt2016, 
       aes(age_calkaBP,
           SeaLev_shortPC1)) +
  geom_line() +
  scale_x_continuous(limits = c(0, 250),
                     name = "x 1000 years ago") +
  scale_y_continuous(name = "Sea Level, meters above present day") +
  theme_bw()

Often we want to see the Marine istope stages on these plots also. This package includes the dataset LR04_MISboundaries of start and end dates for each stage, so we can draw these stages easily. I obtained these data from Lorraine Lisiecki’s web page: http://lorraine-lisiecki.com/LR04_MISboundaries.txt

Some care is required to get the MIS numbers positions in easy-to-read locations. Here I use rep() and seq() to help position the numbers.

# subset the MIS data for the last 250 ka years
mis_last_250ka <- LR04_MISboundaries[LR04_MISboundaries$LR04_Age_ka_start <= 250, ]

# plot the oxygen istope data line on top of the MIS lines
ggplot() +
  geom_vline(data = mis_last_250ka,          # add MIS lines
             aes(xintercept = LR04_Age_ka_start),
             colour = "blue") +
  annotate("text", 
           label = mis_last_250ka$label_MIS, 
           x = mis_last_250ka$LR04_Age_ka_mid,
           y = c(rep(3.0, 4), 
                 seq(3.2, 2.7, length.out = 6), 
                 rep(3.0, 2)),
           size = 3) +
  geom_line(data = lisiecki2005,                # add d18O line
            aes(Time,
                d18O)) +  
  scale_x_continuous(limits = c(0, 250),
                     name = "x 1000 years ago") +
  scale_y_reverse(name = bquote(delta^18*O)) +
  theme_bw()

Sometimes we prefer to indicate the MIS by horizontal lines. Once again we have to carefully place the line segments and labels so they are clear to read:

ggplot() +
  geom_segment(data = mis_last_250ka, # add MIS lines
               aes(x =    LR04_Age_ka_end,
                   xend = LR04_Age_ka_start,
                   y =    seq(3, 2.5, length.out = nrow(mis_last_250ka)),
                   yend = seq(3, 2.5, length.out = nrow(mis_last_250ka))),
               colour = "blue",
               size = 1) +
  annotate("text", 
           label = mis_last_250ka$label_MIS, 
           x =     mis_last_250ka$LR04_Age_ka_mid,
           y = c(seq(2.9, 2.7, length.out = 4), 
                 seq(3.1, 2.8, length.out = 5),
                 seq(2.4, 2.3, length.out = 3)),
           size = 3) +
  geom_line(data = lisiecki2005,                # add d18O line
            aes(Time,
                d18O)) +  
  scale_x_continuous(limits = c(0, 250),
                     name = "x 1000 years ago") +
  scale_y_reverse(name = bquote(delta^18*O)) +
  theme_bw()

And sometimes we might want shaded rectangles to indicate the MIS:

ggplot() +
  annotate("rect", 
           xmin = mis_last_250ka$LR04_Age_ka_end, 
           xmax = mis_last_250ka$LR04_Age_ka_start, 
           ymin = -Inf, 
           ymax = Inf,
        alpha = .2,
        fill = rep(c("grey70", "white"), 
                   nrow(mis_last_250ka)/2)) +
  annotate("text", 
           label = mis_last_250ka$label_MIS, 
           x =     mis_last_250ka$LR04_Age_ka_mid,
           y = c(rep(3, 4), 
                 seq(3.1, 2.8, length.out = 5),
                 rep(3, 3)),
           size = 3) +
  geom_line(data = lisiecki2005,                # add d18O line
            aes(Time,
                d18O)) +  
  scale_x_continuous(limits = c(0, 250),
                     name = "x 1000 years ago") +
  scale_y_reverse(name = bquote(delta^18*O)) +
  theme_bw()

Maybe we want the MIS regions by themselves so we can plot some other time series besides the ones includes here. We need to adjust the y values in the annotate() function to ensure that the MIS labels show in a readble way. Here I show an imaginary variable that might have a maximum value of about 10. So I adjust the y values in the annotate() function to position the MIS labels just below 10 on the y axis.

ggplot() +
  annotate("rect", 
           xmin = mis_last_250ka$LR04_Age_ka_end , 
           xmax = mis_last_250ka$LR04_Age_ka_start, 
           ymin = -Inf, 
           ymax = Inf,
        alpha = .2,
        fill = rep(c("grey70", "white"), 
                   nrow(mis_last_250ka)/2)) +
  annotate("text", 
           label = mis_last_250ka$label_MIS, 
           x =     mis_last_250ka$LR04_Age_ka_mid, 
           y = c(rep(9, 4), 
                 seq(8.1, 9.9, length.out = 5),
                 rep(9, 3)),
           size = 3) +
  # add in other geoms here...
  scale_x_continuous(limits = c(0, 250),
                     name = "x 1000 years ago") +
  scale_y_continuous(limits = c(0, 10),
                  name = "Some other variable (units)") +
  theme_bw()

Please note that this project is released with a Contributor Code of Conduct. By participating in this project you agree to abide by its terms.

These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.