Last updated: 2021-02-18
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Knit directory: BloomSail/
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library(tidyverse)
library(patchwork)
library(seacarb)
library(marelac)
library(metR)
library(scico)
library(lubridate)
library(zoo)
library(tibbletime)
library(sp)
library(kableExtra)
library(LakeMetabolizer)
library(rgdal)
library(ggnewscale)
library(ggsn)
Profile data are prepared by:
Please note that:
tm <-
read_csv(
here::here(
"data/intermediate/_merged_data_files/response_time",
"tm_RT_all.csv"
),
col_types = cols(
ID = col_character(),
pCO2_analog = col_double(),
pCO2_corr = col_double(),
Zero = col_character(),
Flush = col_character(),
mixing = col_character(),
Zero_counter = col_integer(),
deployment = col_integer(),
lon = col_double(),
lat = col_double(),
pCO2 = col_double()
)
)
# Filter relevant rows and columns
tm_profiles <- tm %>%
filter(type == "P",
Flush == "0",
Zero == "0",
!ID %in% parameters$dates_out,
!(station %in% c("PX1", "PX2"))) %>%
select(date_time,
ID,
station,
lat,
lon,
dep,
sal,
tem,
pCO2_corr,
pCO2,
duration)
#calculate mean location of stations
stations <- tm_profiles %>%
group_by(station) %>%
summarise(lat = mean(lat),
lon = mean(lon)) %>%
ungroup() %>%
mutate(station = str_sub(station, 2, 3))
# Assign meta information
tm_profiles <- tm_profiles %>%
group_by(ID, station) %>%
mutate(duration = as.numeric(date_time - min(date_time))) %>%
arrange(date_time) %>%
ungroup()
meta <- read_csv(here::here("data/input/TinaV/Sensor",
"Sensor_meta.csv"),
col_types = cols(ID = col_character()))
meta <- meta %>%
filter(!ID %in% parameters$dates_out)
tm_profiles <- full_join(tm_profiles, meta)
rm(meta)
# creating descriptive variables
tm_profiles <- tm_profiles %>%
mutate(phase = "standby",
phase = if_else(duration >= start & duration < down & !is.na(down) & !is.na(start),
"down", phase),
phase = if_else(duration >= down & duration < lift & !is.na(lift) & !is.na(down ),
"low", phase),
phase = if_else(duration >= lift & duration < up & !is.na(up ) & !is.na(lift ),
"mid", phase),
phase = if_else(duration >= up & duration < end & !is.na(end ) & !is.na(up ),
"up", phase))
tm_profiles <- tm_profiles %>%
select(-c(start, down, lift, up, end, comment, p_type, duration))
# select downcast profiles only
tm_profiles <- tm_profiles %>%
filter(phase %in% parameters$phases_in)
# grid observation to 1m depth intervals
tm_profiles <- tm_profiles %>%
mutate(dep_grid = as.numeric(as.character(cut(
dep, seq(0, 40, 1), seq(0.5, 39.5, 1)
)))) %>%
group_by(ID, station, dep_grid, phase) %>%
summarise_all("mean", na.rm = TRUE) %>%
ungroup() %>%
select(-dep, dep = dep_grid)
# Remove zero pCO2 data
tm_profiles <- tm_profiles %>%
filter(pCO2 >= 0)
# subset complete profiles of stations not included in analysis
profiles_stations_out <- tm_profiles %>%
filter(station %in% c("P14", "P13", "P01"))
profiles_stations_out_in <- profiles_stations_out %>%
filter(dep < parameters$max_dep_gap,
phase == "down") %>%
group_by(ID, station) %>%
summarise(nr_na = parameters$max_dep_gap/parameters$dep_grid - n()) %>%
mutate(select = if_else(nr_na < parameters$max_gap,
"in", "out")) %>%
select(-nr_na) %>%
ungroup()
tm_profiles_stations_out <- full_join(profiles_stations_out_in, profiles_stations_out)
rm(profiles_stations_out, profiles_stations_out_in)
# subset complete profiles of stations included in analysis
tm_profiles <- tm_profiles %>%
filter(!(station %in% c("P14", "P13", "P01")))
profiles_in <- tm_profiles %>%
filter(dep < parameters$max_dep_gap,
phase == "down") %>%
group_by(ID, station) %>%
summarise(nr_na = parameters$max_dep_gap/parameters$dep_grid - n()) %>%
mutate(select = if_else(nr_na < parameters$max_gap,
"in", "out")) %>%
select(-nr_na) %>%
ungroup()
tm_profiles <- full_join(tm_profiles, profiles_in)
tm_profiles <- tm_profiles %>%
mutate(select = if_else(is.na(select) | select == "out",
"out",
"in"))
rm(profiles_in)
tm_profiles %>%
arrange(date_time) %>%
ggplot(aes(pCO2, dep, col = select, linetype = phase)) +
geom_hline(yintercept = 25) +
geom_path() +
scale_y_reverse() +
scale_x_continuous(breaks = c(0, 600), labels = c(0, 600)) +
scale_color_brewer(palette = "Set1", direction = -1) +
coord_cartesian(xlim = c(0, 600)) +
facet_grid(ID ~ station)
tm_profiles %>%
group_by(select) %>%
summarise(nr = n_distinct(ID, station)) %>%
ungroup()
# A tibble: 2 x 2
select nr
<chr> <int>
1 in 78
2 out 8
tm_profiles <- tm_profiles %>%
filter(select == "in",
phase == "down") %>%
select(-c(select, phase)) %>%
filter(dep < parameters$max_dep)
# assign mean date_time stamp
cruise_dates <- tm_profiles %>%
group_by(ID) %>%
summarise(date_time_ID = mean(date_time),
date_ID = format(as.Date(date_time_ID), "%b %d")) %>%
ungroup()
# join profiles and mean date
tm_profiles <- inner_join(cruise_dates, tm_profiles)
cruise_dates %>%
write_csv(here::here("data/intermediate/_summarized_data_files",
"cruise_date.csv"))
# read file
fm <-
read_csv(here::here("data/intermediate/_summarized_data_files",
"fm.csv"))
# filter data inside map
fm <- fm %>%
filter(
lat <= parameters$map_lat_hi,
lat >= parameters$map_lat_lo,
lon >= parameters$map_lon_lo
)
# tag data inside study area to be analyzed
fm <- fm %>%
mutate(
Area = point.in.polygon(
point.x = lon,
point.y = lat,
pol.x = parameters$fm_box_lon,
pol.y = parameters$fm_box_lat
),
Area = as.character(Area),
Area = if_else(Area == "1", "utilized", "sampled")
)
# write tagged data to be analyzed in NCP reconstruction
fm %>%
filter(Area == "utilized") %>%
select(-Area) %>%
write_csv(here::here(
"data/intermediate/_summarized_data_files",
"fm_bloomsail.csv"
))
# handling of the satellite image was inspired by this website:
# https://shekeine.github.io/visualization/2014/09/27/sfcc_rgb_in_R
# https://www.neonscience.org/resources/learning-hub/tutorials/dc-multiband-rasters-r
# read raster file manually downloaded from:
# https://worldview.earthdata.nasa.gov/
EGS <-
raster::stack(here::here("data/input/Maps",
"MODIS_2018_07_26_EGS.tiff"))
# convert to tibble
EGS <- raster::as.data.frame(EGS, xy = T)
EGS <- as_tibble(EGS)
# rename coordinates and subset region
EGS <- EGS %>%
rename(lat = y,
lon = x) %>%
filter(lat >= 56.4, lat <= 58.3)
# stretch histograms of each band and convert to RGB color
EGS <- EGS %>%
mutate(
MODIS_2018_07_26_EGS.1_s = MODIS_2018_07_26_EGS.1 * 2.5,
MODIS_2018_07_26_EGS.2_s = MODIS_2018_07_26_EGS.2 * 2.5,
MODIS_2018_07_26_EGS.3_s = MODIS_2018_07_26_EGS.3 * 2.5
) %>%
mutate(
MODIS_2018_07_26_EGS.1_s =
if_else(MODIS_2018_07_26_EGS.1_s > 255,
255,
MODIS_2018_07_26_EGS.1_s),
MODIS_2018_07_26_EGS.2_s =
if_else(MODIS_2018_07_26_EGS.2_s > 255,
255,
MODIS_2018_07_26_EGS.2_s),
MODIS_2018_07_26_EGS.3_s =
if_else(MODIS_2018_07_26_EGS.3_s > 255,
255,
MODIS_2018_07_26_EGS.3_s)) %>%
mutate(
RGB = rgb(
MODIS_2018_07_26_EGS.1_s,
MODIS_2018_07_26_EGS.2_s,
MODIS_2018_07_26_EGS.3_s,
maxColorValue = 255
)
)
# select relevant columns
EGS <- EGS %>%
select(-c(
MODIS_2018_07_26_EGS.1,
MODIS_2018_07_26_EGS.2,
MODIS_2018_07_26_EGS.3
)) %>%
select(-c(
MODIS_2018_07_26_EGS.1_s,
MODIS_2018_07_26_EGS.2_s,
MODIS_2018_07_26_EGS.3_s
))
# plot map
EGS <- EGS %>%
rename(long = lon)
p_MODIS <-
ggplot(data = EGS,
aes(long, lat, fill = RGB)) +
coord_quickmap(expand = 0) +
geom_raster() +
scale_fill_identity() +
annotate(
"rect",
ymax = parameters$map_lat_hi,
ymin = parameters$map_lat_lo,
xmax = parameters$map_lon_hi,
xmin = parameters$map_lon_lo,
fill = NA,
color = "orangered",
size = 1.5
) +
scale_x_continuous(breaks = seq(10, 30, 1)) +
labs(x = "Longitude (°E)", y = "Latitude (°N)") +
scalebar(
EGS,
transform = TRUE,
model = "WGS84",
dist_unit = "nm",
dist = 25,
location = "bottomleft",
anchor = c(x = 17, y = 56.6),
st.dist = 0.05,
st.size = geom_text_size,
st.color = "white",
box.color = "white",
border.size = 0.3
)
# read file
map <-
read_csv(here::here("data/input/Maps", "Bathymetry_Gotland_east_small.csv"))
# filter region for plot
map <- map %>%
filter(
lat < parameters$map_lat_hi,
lat > parameters$map_lat_lo,
lon < parameters$map_lon_hi,
lon > parameters$map_lon_lo
)
# adjust resolution
map_low_res <- map %>%
mutate(
lat = cut(
lat,
breaks = seq(57, 58, 0.01),
labels = seq(57.005, 57.995, 0.01)
),
lon = cut(
lon,
breaks = seq(18, 22, 0.01),
labels = seq(18.005, 21.995, 0.01)
)
) %>%
group_by(lat, lon) %>%
summarise_all(mean, na.rm = TRUE) %>%
ungroup() %>%
mutate(lat = as.numeric(as.character(lat)),
lon = as.numeric(as.character(lon))) %>%
rename(long = lon)
# downsize track data for plot
tm_track <- tm %>%
arrange(date_time) %>%
slice(which(row_number() %% 10 == 1))
# plot map
p_map <-
ggplot() +
geom_contour_fill(
data = map_low_res,
aes(x = long, y = lat, z = -elev),
na.fill = TRUE,
breaks = seq(0, 300, 30)
) +
geom_raster(data = map %>% filter(is.na(elev)),
aes(lon, lat),
fill = "darkgrey") +
geom_path(data = tm_track, aes(lon, lat, group = ID, col = "Data\nused")) +
scale_color_manual(values = c("orangered"),
name = "") +
new_scale_color() +
geom_path(data = tm_track, aes(lon, lat, group = ID, col = "sampled")) +
geom_path(data = fm, aes(lon, lat, group = ID, col = Area)) +
geom_label(
data = stations %>% filter(!(station %in% c("14", "13", "01"))),
aes(lon, lat, label = station, col = "utilized"),
size = geom_text_size
) +
geom_label(
data = stations %>% filter(station %in% c("14", "13", "01")),
aes(lon, lat, label = station, col = "sampled_station"),
size = geom_text_size
) +
geom_point(aes(parameters$herrvik_lon, parameters$herrvik_lat)) +
geom_text(
aes(parameters$herrvik_lon, parameters$herrvik_lat, label = "Herrvik"),
nudge_x = -0.05,
nudge_y = -0.01,
size = geom_text_size
) +
geom_point(aes(parameters$ostergarn_lon, parameters$ostergarn_lat)) +
geom_text(
aes(parameters$ostergarn_lon, parameters$ostergarn_lat,
label = "Östergarnsholm\nFlux tower"),
nudge_x = -0.07,
nudge_y = 0.03,
size = geom_text_size
) +
geom_text(aes(19.26, 57.57, label = "SOOP Finnmaid"),
col = "white",
size = geom_text_size) +
geom_text(aes(19.54, 57.29, label = "SV Tina V"),
col = "white",
size = geom_text_size) +
coord_quickmap(
expand = 0,
ylim = c(parameters$map_lat_lo + 0.01, parameters$map_lat_hi - 0.01)
) +
scale_x_continuous(breaks = seq(10, 30, 0.1)) +
labs(x = "Longitude (°E)", y = "Latitude (°N)") +
scale_fill_gradient(
low = "lightsteelblue1",
high = "dodgerblue4",
name = "Depth (m)\n",
breaks = seq(30, 150, 30),
limits = c(0, 180),
guide = "colorstrip"
) +
guides(
fill = guide_colorsteps(
barheight = unit(35, "mm"),
barwidth = unit(5, "mm"),
show.limits = TRUE,
frame.colour = "black",
ticks = TRUE,
ticks.colour = "black"
)
) +
scale_color_manual(values = c("white", "darkgrey", "orangered"),
guide = FALSE) +
scalebar(
map_low_res,
transform = TRUE,
model = "WGS84",
dist_unit = "nm",
dist = 2.5,
location = "bottomleft",
anchor = c(x = 18.65, y = 57.3),
st.dist = 0.05,
st.size = geom_text_size,
border.size = 0.3
)
p_MODIS + p_map +
plot_layout(ncol = 1) +
plot_annotation(tag_levels = 'a')
ggsave(
here::here("output/Plots/Figures_publication/article",
"Fig_1.pdf"),
width = 175,
height = 200,
dpi = 300,
units = "mm"
)
ggsave(
here::here("output/Plots/Figures_publication/article",
"Fig_1.png"),
width = 160,
height = 170,
dpi = 300,
units = "mm"
)
rm(map, map_low_res, p_map, p_MODIS,
fm, tm_track, tm, EGS)
# calculate mean samppling dates per station
cover <- tm_profiles %>%
group_by(ID, station) %>%
summarise(date = mean(date_time),
date_time_ID = mean(date_time_ID)) %>%
ungroup() %>%
mutate(station = str_sub(station, 2, 3))
# create coverage plot
cover %>%
ggplot(aes(date, station, fill = ID)) +
geom_vline(aes(xintercept = date_time_ID, col = ID)) +
geom_point(shape = 21) +
scale_fill_viridis_d(labels = cruise_dates$date_ID,
name = "Mean\ncruise date") +
scale_color_viridis_d(labels = cruise_dates$date_ID,
name = "Mean\ncruise date") +
scale_x_datetime(date_breaks = "week",
date_labels = "%b %d") +
labs(y = "Station") +
theme(axis.title.x = element_blank())
ggsave(
here::here(
"output/Plots/Figures_publication/article",
"Fig_2.pdf"
),
width = 100,
height = 65,
dpi = 300,
units = "mm"
)
ggsave(
here::here(
"output/Plots/Figures_publication/article",
"Fig_2.png"
),
width = 100,
height = 65,
dpi = 300,
units = "mm"
)
rm(cover)
At stations P07 and P10 discrete samples for lab measurments of CT and AT were collected. Please note that - in contrast to the pCO2 profiles - samples were taken on June 16, but removed here for harmonization of results.
# read files
tb <-
read_csv(
here::here("data/intermediate/_summarized_data_files", "tb.csv"),
col_types = cols(ID = col_character())
)
# select stations, harmonize depth range and date ID
tb <- tb %>%
filter(station %in% c("P07", "P10"),
dep <= parameters$max_dep) %>%
mutate(ID = if_else(ID == "180722", "180723", ID))
# join with mean cruise dates
tb <- inner_join(tb, cruise_dates)
In order to derive CT from measured pCO2 profiles, the alkalinity mean + sd in the upper 25m and both stations was calculated as:
# AT mean calculation
AT_mean <- tb %>%
filter(dep <= parameters$max_dep) %>%
summarise(AT = mean(AT, na.rm = TRUE)) %>%
pull()
AT_mean
[1] 1719.706
# AT SD calculation
AT_sd <- tb %>%
filter(dep <= parameters$max_dep) %>%
summarise(AT = sd(AT, na.rm = TRUE)) %>%
pull()
AT_sd
[1] 26.95771
Likewise, the mean salinity amounts to:
# Sal mean calculation
sal_mean <- tb %>%
filter(dep <= parameters$max_dep) %>%
summarise(sal = mean(sal, na.rm = TRUE)) %>%
pull()
sal_mean
[1] 6.908356
tb_fix <- bind_cols(start = min(tm_profiles$date_time),
end = max(tm_profiles$date_time),
AT = AT_mean,
AT_sd = AT_sd,
sal = sal_mean)
tb_fix %>%
write_csv(here::here("data/intermediate/_summarized_data_files", "tb_fix.csv"))
The alkalinity-normalized CT, CT*, was calculated for discrete samples.
# calculate CT*, referred to as CT_star in the code
tb <- tb %>%
mutate(CT_star = CT/AT * AT_mean)
tb_long <- tb %>%
pivot_longer(c(sal:AT, CT_star), names_to = "var", values_to = "value")
tb_long %>%
ggplot(aes(value, dep)) +
geom_path(aes(col = ID)) +
geom_point(aes(fill = ID), shape = 21) +
scale_y_reverse() +
scale_fill_viridis_d(labels = cruise_dates$date_ID) +
scale_color_viridis_d(labels = cruise_dates$date_ID) +
facet_grid(station ~ var, scales = "free_x") +
theme(legend.position = "bottom",
legend.title = element_blank())
# grid data into 5 m intervals
# because some samples were not taken at exact 5m depth intervals
# and calculate cruise mean value within each depth interval
tb_long_mean <- tb_long %>%
mutate(dep_grid = as.numeric(as.character(cut(
dep,
breaks = seq(-2.5, 30, 5),
labels = seq(0, 25, 5)
)))) %>%
group_by(ID, date_time_ID, date_ID, dep_grid, var) %>%
summarise(value = mean(value, na.rm = TRUE)) %>%
ungroup()
p_AT <- tb_long_mean %>%
filter(dep_grid < parameters$max_dep, var == "AT") %>%
ggplot(aes(value, dep_grid)) +
annotate(
"rect",
xmin = AT_mean - AT_sd,
xmax = AT_mean + AT_sd,
ymin = -Inf,
ymax = Inf,
alpha = 0.3
) +
geom_vline(data = tb_fix, aes(xintercept = AT), linetype = 2) +
geom_path(aes(col = ID)) +
geom_point(aes(fill = ID), shape = 21) +
scale_y_reverse(sec.axis = dup_axis()) +
labs(x = expression(A[T] ~ (µmol ~ kg ^ {
-1
})),
y = "Depth (m)") +
scale_fill_viridis_d(guide = FALSE) +
scale_color_viridis_d(guide = FALSE) +
theme(axis.text.y.right = element_blank(),
axis.title.y.right = element_blank())
p_CT <- tb_long_mean %>%
filter(dep_grid < parameters$max_dep, var == "CT") %>%
ggplot(aes(value, dep_grid)) +
geom_path(aes(col = ID)) +
geom_point(aes(fill = ID), shape = 21) +
scale_y_reverse(sec.axis = dup_axis()) +
labs(x = expression(C[T] ~ (µmol ~ kg ^ {
-1
})),
y = "Depth (m)") +
scale_fill_viridis_d(guide = FALSE) +
scale_color_viridis_d(guide = FALSE) +
theme(axis.text.y = element_blank(),
axis.title.y = element_blank())
p_CT_star <- tb_long_mean %>%
filter(dep_grid < parameters$max_dep, var == "CT_star") %>%
ggplot(aes(value, dep_grid)) +
geom_path(aes(col = ID)) +
geom_point(aes(fill = ID), shape = 21) +
scale_y_reverse(sec.axis = dup_axis()) +
labs(x = expression(paste(C[T], "*", ~ (µmol ~ kg ^ {-1}))),
y = "Depth (m)") +
scale_fill_viridis_d(labels = cruise_dates$date_ID,
name = "Mean\ncruise date") +
scale_color_viridis_d(labels = cruise_dates$date_ID,
name = "Mean\ncruise date") +
theme(
axis.text.y = element_blank(),
axis.title.y = element_blank()
)
p_AT + p_CT + p_CT_star +
plot_annotation(tag_levels = 'a')
ggsave(
here::here(
"output/Plots/Figures_publication/appendix",
"Fig_B1.pdf"
),
width = 150,
height = 80,
dpi = 300,
units = "mm"
)
ggsave(
here::here(
"output/Plots/Figures_publication/appendix",
"Fig_B1.png"
),
width = 150,
height = 80,
dpi = 300,
units = "mm"
)
rm(tb_long_mean, p_AT, p_CT, p_CT_star, tb_fix)
# surface time series per station
tb_surface <- tb_long %>%
filter(dep < parameters$surface_dep) %>%
group_by(ID, date_time_ID, var, station) %>%
summarise(value = mean(value, na.rm = TRUE)) %>%
ungroup()
# mean surface time series across stations
tb_surface_station_mean <- tb_long %>%
filter(dep < parameters$surface_dep) %>%
group_by(ID, date_time_ID, var) %>%
summarise(value_mean = mean(value, na.rm = TRUE),
value_sd = sd(value, na.rm = TRUE)) %>%
ungroup()
# create time series plot
tb_long %>%
filter(dep <= 10) %>%
ggplot() +
geom_line(data = tb_surface, aes(date_time_ID, value, col = "Individual")) +
geom_line(data = tb_surface_station_mean, aes(date_time_ID, value_mean, col =
"Both (mean)")) +
geom_point(aes(date_time_ID, value, fill = dep), shape = 21) +
scale_fill_scico(palette = "oslo",
direction = -1,
name = "Depth (m)") +
scale_color_brewer(palette = "Set1", name = "Station surface mean") +
scale_x_datetime(breaks = "week", date_labels = "%d %b") +
facet_grid(var ~ station, scales = "free_y") +
labs(x = "Mean transect date")
rm(tb_long, tb_surface, tb)
Note:
Alkalinity normalized CT (CT*) profiles were calculated from sensor pCO2 and T profiles, and constant mean salinity and mean alkalinity values. Note that the impact of fixed vs. measured salinity has only a negligible impact on CT profiles.
# calculate CT_star for included profiles
tm_profiles <- tm_profiles %>%
mutate(
CT_star = carb(
24,
var1 = pCO2,
var2 = AT_mean * 1e-6,
S = sal_mean,
T = tem,
P = dep / 10,
k1k2 = "m10",
kf = "dg",
ks = "d",
gas = "insitu"
)[, 16] * 1e6
)
# calculate CT_star for excluded profiles
tm_profiles_stations_out <- tm_profiles_stations_out %>%
drop_na() %>%
mutate(
CT_star = carb(
24,
var1 = pCO2,
var2 = AT_mean * 1e-6,
S = sal_mean,
T = tem,
P = dep / 10,
k1k2 = "m10",
kf = "dg",
ks = "d",
gas = "insitu"
)[, 16] * 1e6
)
# write CT_star profiles file
tm_profiles %>%
write_csv(
here::here(
"data/intermediate/_merged_data_files/CT_dynamics",
"tm_profiles.csv"
)
)
# calculate CT_star test profiles for higher mean alkalinity
tm_profiles <- tm_profiles %>%
mutate(
CT_star_test = carb(
24,
var1 = pCO2,
var2 = (AT_mean + 2*AT_sd) * 1e-6,
S = sal_mean,
T = tem,
P = dep / 10,
k1k2 = "m10",
kf = "dg",
ks = "d",
gas = "insitu"
)[, 16] * 1e6
)
# arrange by date (oldest first)
tm_profiles <- tm_profiles %>%
arrange(date_time_ID)
# create temperature profiles plots
p_tem <-
tm_profiles %>%
ggplot(aes(tem, dep, col = ID, group = interaction(station, ID))) +
geom_path() +
scale_y_reverse(expand = c(0, 0)) +
labs(x = "Temperature (\u00B0C)",
y = "Depth (m)") +
scale_color_viridis_d(guide = FALSE)
# create pCO2 profiles plots
p_pCO2 <-
tm_profiles %>%
ggplot(aes(pCO2, dep, col = ID, group = interaction(station, ID))) +
geom_path() +
scale_y_reverse(expand = c(0, 0)) +
labs(x = expression(italic(p)*CO[2] ~ (µatm))) +
scale_color_viridis_d(guide = FALSE) +
theme(
axis.text.y = element_blank(),
axis.title.y = element_blank(),
axis.ticks.y = element_blank()
)
# create CT* profiles plots
p_CT_star <-
tm_profiles %>%
ggplot(aes(CT_star, dep, col = ID, group = interaction(station, ID))) +
geom_path() +
scale_y_reverse(expand = c(0, 0)) +
labs(x = expression(paste(C[T], "*", ~ (µmol ~ kg ^ {-1})))) +
scale_color_viridis_d(labels = cruise_dates$date_ID,
name = "Mean\ncruise date") +
theme(
axis.text.y = element_blank(),
axis.ticks.y = element_blank(),
axis.title.y = element_blank()
)
# Combine and safe plots to file
p_tem + p_pCO2 + p_CT_star +
plot_annotation(tag_levels = 'a')
ggsave(
here::here(
"output/Plots/Figures_publication/article",
"Fig_3.pdf"
),
width = 150,
height = 80,
dpi = 300,
units = "mm"
)
ggsave(
here::here(
"output/Plots/Figures_publication/article",
"Fig_3.png"
),
width = 150,
height = 80,
dpi = 300,
units = "mm"
)
rm(p_tem, p_pCO2, p_CT_star)
Mean vertical profiles were calculated for each cruise day (ID).
tm_profiles_ID_mean <- tm_profiles %>%
select(-c(station, lat, lon, pCO2_corr, date_time)) %>%
group_by(ID, date_time_ID, dep) %>%
summarise_all(list(mean), na.rm = TRUE) %>%
ungroup()
tm_profiles_ID_sd <- tm_profiles %>%
select(-c(station, lat, lon, pCO2_corr, date_time)) %>%
group_by(ID, date_time_ID, dep) %>%
summarise_all(list(sd), na.rm = TRUE) %>%
ungroup()
tm_profiles_ID_sd_long <- tm_profiles_ID_sd %>%
pivot_longer(sal:CT_star_test, names_to = "var", values_to = "sd")
tm_profiles_ID_mean_long <- tm_profiles_ID_mean %>%
pivot_longer(sal:CT_star_test, names_to = "var", values_to = "value")
tm_profiles_ID_long_test <-
inner_join(tm_profiles_ID_mean_long, tm_profiles_ID_sd_long)
tm_profiles_ID_long <- tm_profiles_ID_long_test %>%
filter(var != "CT_star_test")
tm_profiles_ID_mean_test <- tm_profiles_ID_mean
tm_profiles_ID_mean_test <- tm_profiles_ID_mean_test %>%
mutate(CT_star_delta = CT_star - CT_star_test)
tm_profiles_ID_mean <- tm_profiles_ID_mean %>%
select(-CT_star_test)
tm_profiles <- tm_profiles %>%
select(-CT_star_test)
tm_profiles_ID_mean %>%
write_csv(here::here("data/intermediate/_merged_data_files/CT_dynamics", "tm_profiles_ID.csv"))
rm(
tm_profiles_ID_sd_long,
tm_profiles_ID_sd,
tm_profiles_ID_mean_long
)
tm_profiles_ID_long %>%
ggplot(aes(value, dep, col = ID)) +
geom_point() +
geom_path() +
scale_y_reverse() +
scale_color_viridis_d() +
facet_wrap( ~ var, scales = "free_x")
tm_profiles_ID_mean_test %>%
ggplot(aes(CT_star_delta - mean(CT_star_delta), dep, col = ID)) +
geom_point() +
geom_path() +
scale_y_reverse() +
scale_color_viridis_d()
profiles_min_max <- tm_profiles %>%
group_by(dep) %>%
summarise(max_CT = max(CT_star),
min_CT = min(CT_star),
max_tem = max(tem),
min_tem = min(tem)) %>%
ungroup()
p_CT_star <-
tm_profiles %>%
ggplot() +
geom_ribbon(data = profiles_min_max,
aes(xmin = min_CT,
xmax = max_CT,
y = dep),
alpha = 0.2) +
geom_path(aes(CT_star, dep, col = station)) +
scale_y_reverse() +
facet_grid(ID ~ .) +
labs(x = expression(paste(C[T], "*", ~ (µmol ~ kg ^ {-1}))),
y = "Depth (m)") +
theme(strip.background = element_blank(),
strip.text = element_blank(),
legend.position = "none")
cruise_labels <- c(
`180705` = cruise_dates$date_ID[1],
`180709` = cruise_dates$date_ID[2],
`180718` = cruise_dates$date_ID[3],
`180723` = cruise_dates$date_ID[4],
`180730` = cruise_dates$date_ID[5],
`180802` = cruise_dates$date_ID[6],
`180806` = cruise_dates$date_ID[7],
`180815` = cruise_dates$date_ID[8]
)
p_tem <-
tm_profiles %>%
ggplot() +
geom_ribbon(data = profiles_min_max,
aes(xmin = min_tem,
xmax = max_tem,
y = dep,
fill = "Min/Max"),
alpha = 0.2) +
geom_path(aes(tem, dep, col = station)) +
scale_y_reverse() +
scale_fill_manual(values = "black", name = "") +
scale_color_discrete(name = "Station") +
guides(color = guide_legend(order = 1)) +
facet_grid(ID ~ .,
labeller = labeller(ID = cruise_labels)) +
labs(x = "Temperature (\u00B0C)",
y = "Depth (m)") +
theme(axis.title.y = element_blank(),
axis.text.y = element_blank())
p_CT_star | p_tem
ggsave(
here::here(
"output/Plots/Figures_publication/appendix",
"Fig_C3.pdf"
),
width = 120,
height = 180,
dpi = 300,
units = "mm"
)
ggsave(
here::here(
"output/Plots/Figures_publication/appendix",
"Fig_C3.png"
),
width = 120,
height = 180,
dpi = 300,
units = "mm"
)
rm(p_CT_star, p_tem, cruise_labels, profiles_min_max)
Important notes:
CT, pCO2, S, and T profiles were plotted individually pdf here and grouped by ID pdf here. The later gives an idea of the differences between stations at one point in time.
# create pdf file
pdf(file=here::here("output/Plots/NCP_best_guess",
"tm_profiles_pCO2_tem_sal_CT.pdf"), onefile = TRUE, width = 9, height = 5)
# loop across all stations and cruise days and create profile plots
for(i_ID in unique(tm_profiles$ID)){
for(i_station in unique(tm_profiles$station)){
if (nrow(tm_profiles %>% filter(ID == i_ID, station == i_station)) > 0){
# i_ID <- unique(tm_profiles$ID)[1]
# i_station <- unique(tm_profiles$station)[1]
p_pCO2 <-
tm_profiles %>%
arrange(date_time) %>%
filter(ID == i_ID,
station == i_station) %>%
ggplot(aes(pCO2, dep, col="grid_RT"))+
geom_point(aes(pCO2_corr, dep, col="grid"))+
geom_point()+
geom_path()+
scale_y_reverse()+
scale_color_brewer(palette = "Set1")+
labs(y="Depth [m]", x="pCO2 [µatm]", title = str_c(i_ID," | ",i_station))+
coord_cartesian(xlim = c(0,200), ylim = c(30,0))+
theme_bw()+
theme(legend.position = "left")
p_tem <-
tm_profiles %>%
arrange(date_time) %>%
filter(ID == i_ID,
station == i_station) %>%
ggplot(aes(tem, dep))+
geom_point()+
geom_path()+
scale_y_reverse()+
labs(y="Depth [m]", x="Tem [°C]")+
coord_cartesian(xlim = c(14,26), ylim = c(30,0))+
theme_bw()
p_sal <-
tm_profiles %>%
arrange(date_time) %>%
filter(ID == i_ID,
station == i_station) %>%
ggplot(aes(sal, dep))+
geom_point()+
geom_path()+
scale_y_reverse()+
labs(y="Depth [m]", x="Tem [°C]")+
coord_cartesian(xlim = c(6.5,7.5), ylim = c(30,0))+
theme_bw()
p_CT_star <-
tm_profiles %>%
arrange(date_time) %>%
filter(ID == i_ID,
station == i_station) %>%
ggplot(aes(CT_star, dep))+
geom_point()+
geom_path()+
scale_y_reverse()+
labs(y="Depth [m]", x="CT_star* [µmol/kg]")+
coord_cartesian(xlim = c(1400,1700), ylim = c(30,0))+
theme_bw()
print(
p_pCO2 + p_tem + p_sal + p_CT_star
)
rm(p_pCO2, p_sal, p_tem, p_CT_star)
}
}
}
dev.off()
rm(i_ID, i_station)
# convert data to long format
tm_profiles_long <- tm_profiles %>%
select(-c(lat, lon, pCO2_corr)) %>%
pivot_longer(sal:CT_star, values_to = "value", names_to = "var")
# create pdf file
pdf(file=here::here("output/Plots/NCP_best_guess",
"tm_profiles_ID_pCO2_tem_sal_CT.pdf"), onefile = TRUE, width = 9, height = 5)
# loop across all cruise days and create profile plots
for(i_ID in unique(tm_profiles$ID)){
#i_ID <- unique(tm_profiles$ID)[1]
sub_tm_profiles_long <- tm_profiles_long %>%
arrange(date_time) %>%
filter(ID == i_ID)
print(
sub_tm_profiles_long %>%
ggplot()+
geom_path(data = tm_profiles_long,
aes(value, dep, group=interaction(station, ID)), col="grey")+
geom_path(aes(value, dep, col=station))+
scale_y_reverse()+
labs(y="Depth [m]", title = str_c("ID: ", i_ID))+
theme_bw()+
facet_wrap(~var, scales = "free_x")
)
rm(sub_tm_profiles_long)
}
dev.off()
rm(i_ID, tm_profiles_long)
# calculate overall min/max profiles from included stations
profiles_min_max <- tm_profiles %>%
group_by(dep, ID) %>%
summarise(max_CT = max(CT_star),
min_CT = min(CT_star),
max_tem = max(tem),
min_tem = min(tem)) %>%
ungroup()
# calculate overall mean +/- SD profiles from included stations
profiles_sd <- tm_profiles %>%
group_by(dep, ID) %>%
summarise(max_CT = mean(CT_star) + sd(CT_star),
min_CT = mean(CT_star) - sd(CT_star),
max_tem = mean(tem) + sd(tem),
min_tem = mean(tem) - sd(tem)) %>%
ungroup()
# filter downcast from relevant excluded stations
tm_profiles_stations_out <- tm_profiles_stations_out %>%
filter(ID %in% unique(tm_profiles$ID),
phase == "down")
# plot profiles
p_CT <-
tm_profiles_stations_out %>%
ggplot() +
geom_ribbon(data = profiles_min_max,
aes(xmin = min_CT,
xmax = max_CT,
y = dep,
fill = "Min/Max"),
alpha = 0.2) +
geom_ribbon(data = profiles_sd,
aes(xmin = min_CT,
xmax = max_CT,
y = dep,
fill = "SD"),
alpha = 0.2) +
scale_fill_manual(values = c("black", "purple"), name = "") +
geom_path(aes(CT_star, dep, col = station)) +
scale_y_reverse() +
facet_grid(ID ~ .) +
labs(x = expression(paste(C[T], "*", ~ (µmol ~ kg ^ {
-1
}))),
y = "Depth (m)") +
theme(
strip.background = element_blank(),
strip.text = element_blank(),
legend.position = "none"
)
cruise_labels <- c(
`180705` = cruise_dates$date_ID[1],
`180709` = cruise_dates$date_ID[2],
`180718` = cruise_dates$date_ID[3],
`180723` = cruise_dates$date_ID[4],
`180730` = cruise_dates$date_ID[5],
`180802` = cruise_dates$date_ID[6],
`180806` = cruise_dates$date_ID[7],
`180815` = cruise_dates$date_ID[8]
)
p_tem <-
tm_profiles_stations_out %>%
ggplot() +
geom_ribbon(data = profiles_min_max,
aes(xmin = min_tem,
xmax = max_tem,
y = dep,
fill = "Min/Max"),
alpha = 0.2) +
geom_ribbon(data = profiles_sd,
aes(xmin = min_tem,
xmax = max_tem,
y = dep,
fill = "SD"),
alpha = 0.2) +
geom_path(aes(tem, dep, col = station)) +
scale_y_reverse() +
scale_fill_manual(values = c("black", "purple"), name = "") +
scale_color_discrete(name = "Station") +
guides(color = guide_legend(order = 1)) +
facet_grid(ID ~ .,
labeller = labeller(ID = cruise_labels)) +
labs(x = "Temperature (\u00B0C)",
y = "Depth (m)") +
theme(axis.title.y = element_blank(),
axis.text.y = element_blank())
p_CT | p_tem
rm(p_CT_star, p_tem, cruise_labels, profiles_min_max,
profiles_sd, p_CT)
Changes of seawater variables at each depth are calculated from one cruise day to the next and divided by the number of days inbetween.
tm_profiles_ID_long <- tm_profiles_ID_long %>%
group_by(var, dep) %>%
arrange(date_time_ID) %>%
mutate(
date_time_ID_diff = as.numeric(date_time_ID - lag(date_time_ID)),
date_time_ID_ref = date_time_ID - (date_time_ID - lag(date_time_ID)) /
2,
value_diff = value - lag(value, default = first(value)),
value_diff_daily = value_diff / date_time_ID_diff,
value_cum = cumsum(value_diff)
) %>%
ungroup()
tm_profiles_ID_long %>%
arrange(dep) %>%
ggplot(aes(value_diff_daily, dep, col = ID)) +
geom_vline(xintercept = 0) +
geom_point() +
geom_path() +
scale_y_reverse() +
scale_color_viridis_d() +
facet_wrap( ~ var, scales = "free_x") +
labs(x = "Change of value inbetween cruises per day")
Cumulative changes of seawater vars were calculated at each depth relative to the first cruise day on July 5.
tm_profiles_ID_long %>%
arrange(dep) %>%
ggplot(aes(value_cum, dep, col = ID)) +
geom_vline(xintercept = 0) +
geom_point() +
geom_path() +
scale_y_reverse() +
scale_color_viridis_d() +
facet_wrap( ~ var, scales = "free_x") +
labs(x = "Cumulative change of value")
Important notes:
Cumulative positive and negative changes of seawater vars were calculated separately at each depth relative to the first cruise day on July 5.
tm_profiles_ID_long <- tm_profiles_ID_long %>%
mutate(sign = if_else(value_diff < 0, "neg", "pos")) %>%
group_by(var, dep, sign) %>%
arrange(date_time_ID) %>%
mutate(value_cum_sign = cumsum(value_diff)) %>%
ungroup()
tm_profiles_ID_long %>%
arrange(dep) %>%
ggplot(aes(value_cum_sign, dep, col = ID)) +
geom_vline(xintercept = 0) +
geom_point() +
geom_path() +
scale_y_reverse() +
scale_color_viridis_d() +
scale_fill_viridis_d() +
facet_wrap( ~ interaction(sign, var), scales = "free_x", ncol = 4) +
labs(x = "Cumulative directional change of value")
Mean seawater parameters were calculated for 5m depth intervals.
# cut into 5m depth intervals
tm_profiles_ID_long_grid <- tm_profiles_ID_long %>%
mutate(dep = cut(dep, seq(0, 30, 5))) %>%
group_by(ID, date_time_ID, dep, var) %>%
summarise_all(list(mean), na.rm = TRUE) %>%
ungroup()
tm_profiles_ID_long_grid %>%
ggplot(aes(date_time_ID, value, col = as.factor(dep))) +
geom_path() +
geom_point() +
scale_color_viridis_d(name = "Depth (m)") +
scale_x_datetime(breaks = "week", date_labels = "%d %b") +
facet_wrap( ~ var, scales = "free_y", ncol = 1) +
theme(axis.title.x = element_blank())
tm_profiles_ID_long_grid %>%
mutate(value = round(value, 1),
date_ID = as.Date(date_time_ID)) %>%
select(date_ID, dep, var, value) %>%
pivot_wider(values_from = value, names_from = var) %>%
kable() %>%
add_header_above() %>%
kable_styling(full_width = FALSE) %>%
scroll_box(height = "400px")
date_ID | dep | CT_star | pCO2 | sal | tem |
---|---|---|---|---|---|
2018-07-06 | (0,5] | 1528.4 | 98.3 | 6.9 | 15.4 |
2018-07-06 | (5,10] | 1541.9 | 106.0 | 6.9 | 14.7 |
2018-07-06 | (10,15] | 1562.9 | 123.3 | 6.9 | 14.1 |
2018-07-06 | (15,20] | 1575.0 | 136.5 | 7.0 | 13.9 |
2018-07-06 | (20,25] | 1589.1 | 153.5 | 7.0 | 13.7 |
2018-07-10 | (0,5] | 1500.3 | 86.1 | 6.9 | 17.0 |
2018-07-10 | (5,10] | 1517.0 | 93.4 | 6.9 | 15.9 |
2018-07-10 | (10,15] | 1561.0 | 124.6 | 6.9 | 14.4 |
2018-07-10 | (15,20] | 1584.4 | 148.5 | 6.9 | 14.0 |
2018-07-10 | (20,25] | 1596.1 | 163.8 | 7.0 | 13.5 |
2018-07-19 | (0,5] | 1466.8 | 79.1 | 6.9 | 20.5 |
2018-07-19 | (5,10] | 1479.3 | 81.5 | 7.0 | 19.0 |
2018-07-19 | (10,15] | 1553.9 | 124.4 | 7.0 | 15.5 |
2018-07-19 | (15,20] | 1586.9 | 155.0 | 7.1 | 14.4 |
2018-07-19 | (20,25] | 1597.8 | 168.3 | 7.2 | 13.9 |
2018-07-24 | (0,5] | 1439.9 | 69.0 | 7.0 | 21.5 |
2018-07-24 | (5,10] | 1453.4 | 73.2 | 7.0 | 20.7 |
2018-07-24 | (10,15] | 1565.5 | 141.8 | 7.0 | 15.8 |
2018-07-24 | (15,20] | 1609.3 | 190.8 | 7.1 | 14.3 |
2018-07-24 | (20,25] | 1618.7 | 206.1 | 7.1 | 13.6 |
2018-07-31 | (0,5] | 1474.7 | 100.3 | 6.8 | 24.3 |
2018-07-31 | (5,10] | 1484.4 | 99.2 | 6.8 | 22.3 |
2018-07-31 | (10,15] | 1582.6 | 165.6 | 6.9 | 16.0 |
2018-07-31 | (15,20] | 1626.7 | 226.6 | 7.0 | 14.0 |
2018-07-31 | (20,25] | 1645.5 | 277.0 | 7.1 | 13.0 |
2018-08-03 | (0,5] | 1458.2 | 91.1 | 6.9 | 24.9 |
2018-08-03 | (5,10] | 1471.5 | 93.4 | 6.9 | 23.2 |
2018-08-03 | (10,15] | 1590.1 | 177.3 | 6.9 | 15.9 |
2018-08-03 | (15,20] | 1634.9 | 246.1 | 6.9 | 13.9 |
2018-08-03 | (20,25] | 1651.5 | 290.6 | 7.0 | 12.8 |
2018-08-07 | (0,5] | 1473.1 | 92.1 | 6.9 | 23.0 |
2018-08-07 | (5,10] | 1483.4 | 98.6 | 6.9 | 22.5 |
2018-08-07 | (10,15] | 1605.2 | 200.1 | 6.9 | 15.5 |
2018-08-07 | (15,20] | 1638.8 | 257.3 | 7.0 | 14.0 |
2018-08-07 | (20,25] | 1650.7 | 291.8 | 7.1 | 12.8 |
2018-08-16 | (0,5] | 1555.9 | 140.6 | 7.0 | 18.6 |
2018-08-16 | (5,10] | 1561.3 | 146.8 | 7.0 | 18.5 |
2018-08-16 | (10,15] | 1581.8 | 173.5 | 7.0 | 17.7 |
2018-08-16 | (15,20] | 1638.9 | 276.9 | 7.0 | 14.8 |
2018-08-16 | (20,25] | 1679.2 | 404.0 | 7.1 | 11.6 |
rm(tm_profiles_ID_long_grid)
Mean seawater CT* were calculated for 5m depth intervals, based on two AT values (regular mean + 2 SD). Relative changes of CT* do not differ much, despite a large bias in mean AT.
# cut into 5m depth intervals
tm_profiles_ID_long_grid <- tm_profiles_ID_long_test %>%
mutate(dep = cut(dep, seq(0, 30, 5))) %>%
group_by(ID, date_time_ID, dep, var) %>%
summarise_all(list(mean), na.rm = TRUE)
tm_profiles_ID_long_grid %>%
filter(var %in% c("CT_star", "CT_star_test")) %>%
ggplot(aes(date_time_ID, value, col = as.factor(dep))) +
geom_path() +
geom_point() +
scale_color_viridis_d(name = "Depth (m)") +
scale_x_datetime(breaks = "week", date_labels = "%d %b") +
facet_wrap( ~ var, scales = "free_y", ncol = 1) +
theme(axis.title.x = element_blank())
rm(tm_profiles_ID_long_grid, tm_profiles_ID_long_test)
To further illustrate the robustness of CT* to errors in mean AT, we calculate CT* changes for range of AT errors and the conditions encountered during the field campaign in 2018.
# prepare data set with peak values of cyano bloom
CT_star_sens <- tm_profiles %>%
filter(dep < parameters$surface_dep,
date_ID %in% c("Jul 06", "Jul 24")) %>%
select(date_ID, tem, pCO2) %>%
group_by(date_ID) %>%
summarise_all(mean, na.rm = TRUE) %>%
ungroup()
# create range of AT values spanning +/- 3 SD
CT_star_sens <- expand_grid(CT_star_sens, factor = seq(-3, 3, 0.2))
CT_star_sens <- CT_star_sens %>%
mutate(AT = (AT_mean + factor * AT_sd) * 1e-6)
# calculate C* for range of AT values
CT_star_sens <- CT_star_sens %>%
mutate(
CT_star = carb(
24,
var1 = pCO2,
var2 = AT,
S = sal_mean,
T = tem,
k1k2 = "m10",
kf = "dg",
ks = "d",
gas = "insitu"
)[, 16] * 1e6
)
# calculate change of CT* for various AT values
CT_star_sens <- CT_star_sens %>%
mutate(AT = AT * 1e6) %>%
select(date_ID, factor, AT, CT_star) %>%
pivot_wider(names_from = "date_ID",
values_from = c("CT_star"))
CT_star_sens <- CT_star_sens %>%
mutate(CT_star_delta = `Jul 24` - `Jul 06`) %>%
select(factor, AT, CT_star_delta)
CT_star_delta_mean <- CT_star_sens %>%
filter(factor == 0) %>%
pull(CT_star_delta)
CT_star_sens <- CT_star_sens %>%
mutate(
CT_star_delta_offset = CT_star_delta - CT_star_delta_mean,
CT_star_delta_offset_rel = CT_star_delta / CT_star_delta_mean * 100,
AT_offset = AT - AT_mean
)
CT_star_delta_sd <- CT_star_sens %>%
filter(factor == 1) %>%
pull(CT_star_delta_offset)
CT_star_sens %>%
ggplot(aes(AT_offset, CT_star_delta_offset)) +
annotate(
"rect",
xmin = -AT_sd,
xmax = +AT_sd,
ymin = -Inf,
ymax = Inf,
alpha = 0.3
) +
annotate(
"rect",
xmin = -Inf,
xmax = Inf,
ymin = -CT_star_delta_sd,
ymax = +CT_star_delta_sd,
alpha = 0.3
) +
geom_vline(xintercept = 0, linetype = 2) +
geom_hline(yintercept = 0, linetype = 2) +
geom_line(col = "red") +
scale_y_continuous(
expression(paste(
"Absolute bias ", Delta ~ C[T], "*", ~ (µmol ~ kg ^ {
-1
})
)),
sec.axis = sec_axis(
~ . / CT_star_delta_mean * 100,
name = expression(paste("Relative bias ", Delta ~ C[T], "* (%)")),
breaks = seq(-10, 10, 1)
)
) +
scale_x_continuous(expression(paste("Absolute bias ", A[T] ~ (µmol ~ kg ^ {
-1
}))),
sec.axis = sec_axis(
~ . / AT_mean * 100,
name = expression(paste("Relative bias ", A[T], " (%)")),
breaks = seq(-10, 10, 1)
))
ggsave(
here::here("output/Plots/Figures_publication/appendix",
"Fig_C1.pdf"),
width = 83,
height = 60,
dpi = 300,
units = "mm"
)
ggsave(
here::here("output/Plots/Figures_publication/appendix",
"Fig_C1.png"),
width = 83,
height = 60,
dpi = 300,
units = "mm"
)
rm(CT_star_delta_mean, CT_star_delta_sd,
CT_star_sens)
bin_CT_star <- 30
p_CT_star_hov <- tm_profiles_ID_long %>%
filter(var == "CT_star") %>%
ggplot() +
geom_contour_fill(aes(x = date_time_ID, y = dep, z = value),
breaks = MakeBreaks(bin_CT_star),
col = "black",
size = 0.1) +
geom_vline(aes(xintercept = date_time_ID),
col = "white",
linetype = "1f") +
scale_fill_scico(
breaks = MakeBreaks(bin_CT_star),
guide = "colorstrip",
name = expression(paste(C[T],"*")~(µmol ~ kg ^ {-1})~" "),
palette = "davos",
direction = -1
) +
guides(fill = guide_colorsteps(barheight = unit(3, "mm"),
barwidth = unit(65, "mm"),
frame.colour = "black",
ticks = TRUE,
ticks.colour = "black")) +
scale_y_reverse(sec.axis = dup_axis()) +
scale_x_datetime(breaks = "week",
date_labels = "%b %d") +
labs(y = "Depth (m)") +
coord_cartesian(expand = 0) +
theme(
axis.title.x = element_blank(),
axis.title.y.right = element_blank(),
axis.text.y.right = element_blank(),
legend.position = "bottom",
legend.margin = margin(0, 0, 0, 0),
legend.box.margin = margin(0, 0, 0, 0)
)
bin_Tem <- 2
p_tem_hov <- tm_profiles_ID_long %>%
filter(var == "tem") %>%
ggplot() +
geom_contour_fill(aes(x = date_time_ID, y = dep, z = value),
breaks = MakeBreaks(bin_Tem),
col = "black",
size = 0.1) +
geom_vline(aes(xintercept = date_time_ID),
col = "white",
linetype = "1f") +
scale_fill_viridis_c(
breaks = MakeBreaks(bin_Tem),
guide = "colorstrip",
name = expression(Temperature~("\u00B0" * C)),
option = "inferno"
) +
guides(fill = guide_colorsteps(barheight = unit(3, "mm"),
barwidth = unit(55, "mm"),
frame.colour = "black",
ticks = TRUE,
ticks.colour = "black")) +
scale_y_reverse(sec.axis = dup_axis()) +
scale_x_datetime(breaks = "week",
date_labels = "%b %d") +
labs(y = "Depth (m)") +
coord_cartesian(expand = 0) +
theme(
axis.title.x = element_blank(),
axis.title.y.right = element_blank(),
axis.text.y.right = element_blank(),
legend.position = "top",
legend.margin = margin(0, 0, 0, 0),
legend.box.margin = margin(0, 0, 0, 0)
)
p_CT_star_ID_cum <-
tm_profiles_ID_long %>%
filter(var == "CT_star") %>%
ggplot(aes(value_cum, dep, col = ID, fill = ID)) +
geom_hline(yintercept = 12, col = "red") +
geom_path() +
geom_point(shape = 21, col = "black") +
scale_y_reverse(expand = c(0, 0),
position = "right",
sec.axis = dup_axis()) +
labs(x = expression(paste(C[T],"*", ~ cum. ~ changes ~ (µmol ~ kg ^ {
-1
}))),
y = "Depth (m)") +
scale_color_viridis_d(labels = cruise_dates$date_ID, guide = FALSE) +
scale_fill_viridis_d(labels = cruise_dates$date_ID, guide = FALSE) +
theme(axis.title.y.left = element_blank(),
axis.text.y.left = element_blank())
p_tem_ID_cum <-
tm_profiles_ID_long %>%
filter(var == "tem") %>%
ggplot(aes(value_cum, dep, col = ID, fill = ID)) +
geom_hline(yintercept = 12, col = "red") +
geom_path() +
geom_point(shape = 21, col = "black") +
scale_y_reverse(expand = c(0, 0),
position = "right",
sec.axis = dup_axis()) +
labs(x = "Temperature cum. changes (\u00B0C)",
y = "Depth (m)") +
scale_color_viridis_d(labels = cruise_dates$date_ID) +
scale_fill_viridis_d(labels = cruise_dates$date_ID) +
theme(
legend.position = "top",
axis.title.y.left = element_blank(),
axis.text.y.left = element_blank(),
legend.title = element_blank(),
legend.key.size = unit(4, "mm"),
legend.key.width = unit(4,"mm")
)
((p_tem_hov | p_tem_ID_cum ) + plot_layout(tag_level = 'new', widths = c(2.3, 1))) /
((p_CT_star_hov | p_CT_star_ID_cum ) + plot_layout(tag_level = 'new', widths = c(2.3, 1))) +
plot_annotation(tag_levels = c('a', '1'))
ggsave(
here::here(
"output/Plots/Figures_publication/article",
"Fig_4.pdf"
),
width = 175,
height = 150,
dpi = 300,
units = "mm"
)
ggsave(
here::here(
"output/Plots/Figures_publication/article",
"Fig_4.png"
),
width = 175,
height = 140,
dpi = 300,
units = "mm"
)
rm(p_CT_star_hov, bin_CT_star, p_tem_hov, bin_Tem, p_CT_star_ID_cum, p_tem_ID_cum)
bin_CT_star <- 2.5
CT_star_hov <- tm_profiles_ID_long %>%
filter(var == "CT_star") %>%
ggplot() +
geom_contour_fill(
aes(x = date_time_ID_ref, y = dep, z = value_diff_daily),
breaks = MakeBreaks(bin_CT_star),
col = "black"
) +
geom_point(
aes(x = date_time_ID, y = c(24.5)),
size = 3, shape = 24, fill = "white"
) +
scale_fill_divergent(breaks = MakeBreaks(bin_CT_star),
guide = "colorstrip",
name = "CT_star") +
scale_y_reverse() +
scale_x_datetime(breaks = "week", date_labels = "%d %b") +
coord_cartesian(expand = 0) +
theme(axis.title.x = element_blank(),
axis.text.x = element_blank())
bin_Tem <- 0.1
Tem_hov <- tm_profiles_ID_long %>%
filter(var == "tem") %>%
ggplot() +
geom_contour_fill(
aes(x = date_time_ID_ref, y = dep, z = value_diff_daily),
breaks = MakeBreaks(bin_Tem),
col = "black"
) +
geom_point(
aes(x = date_time_ID, y = c(24.5)),
size = 3, shape = 24, fill = "white"
) +
scale_fill_divergent(breaks = MakeBreaks(bin_Tem),
guide = "colorstrip",
name = "tem") +
scale_y_reverse() +
scale_x_datetime(breaks = "week", date_labels = "%d %b") +
coord_cartesian(expand = 0) +
theme(axis.title.x = element_blank())
CT_star_hov / Tem_hov
rm(CT_star_hov, bin_CT_star, Tem_hov, bin_Tem)
bin_CT_star <- 20
CT_star_hov <- tm_profiles_ID_long %>%
filter(var == "CT_star") %>%
ggplot() +
geom_contour_fill(
aes(x = date_time_ID, y = dep, z = value_cum),
breaks = MakeBreaks(bin_CT_star),
col = "black"
) +
geom_point(
aes(x = date_time_ID, y = c(24.5)),
size = 3,
shape = 24,
fill = "white"
) +
scale_fill_divergent(breaks = MakeBreaks(bin_CT_star),
guide = "colorstrip",
name = "CT_star") +
scale_y_reverse() +
scale_x_datetime(breaks = "week", date_labels = "%d %b") +
coord_cartesian(expand = 0) +
theme(axis.title.x = element_blank(),
axis.text.x = element_blank())
bin_Tem <- 2
Tem_hov <- tm_profiles_ID_long %>%
filter(var == "tem") %>%
ggplot() +
geom_contour_fill(
aes(x = date_time_ID, y = dep, z = value_cum),
breaks = MakeBreaks(bin_Tem),
col = "black"
) +
geom_point(
aes(x = date_time_ID, y = c(24.5)),
size = 3,
shape = 24,
fill = "white"
) +
scale_fill_divergent(breaks = MakeBreaks(bin_Tem),
guide = "colorstrip",
name = "tem") +
scale_y_reverse() +
scale_x_datetime(breaks = "week", date_labels = "%d %b") +
coord_cartesian(expand = 0) +
theme(axis.title.x = element_blank())
CT_star_hov / Tem_hov
rm(CT_star_hov, bin_CT_star, Tem_hov, bin_Tem)
A critical first step for the determination of net community production (NCP) is the integration of observed changes in CT* over depth. Two approaches were tested:
Both approaches deliver depth-integrated, incremental changes of CT* ( iCT* ) between cruise dates. Those were summed up to derive a trajectory of cumulative integrated CT* changes.
Incremental and cumulative CT* changes between cruise dates were integrated across the water columns down to predefined depth limits. This was done separately for observed positive/negative changes in CT*, as well as for the total observed changes.
Predefined integration depth levels in meters are: 9, 10, 11, 12, 13
# create time series grid data frames
iCT_star_grid_sign <- tm_profiles_ID_long %>%
select(ID, date_time_ID, date_time_ID_ref) %>%
unique() %>%
expand_grid(sign = c("pos", "neg"))
iCT_star_grid_total <- tm_profiles_ID_long %>%
select(ID, date_time_ID, date_time_ID_ref) %>%
unique() %>%
expand_grid(sign = c("total"))
# calculate integrated CT* time series for each fixed integration depth
for (i_dep in parameters$fixed_integration_depths) {
# calculations for pos/neg changes separately
# integrate (ie sum up) across depth
iCT_star_sign_temp <- tm_profiles_ID_long %>%
filter(var == "CT_star", dep < i_dep) %>%
mutate(sign = if_else(ID == "180705" &
dep == 0.5, "neg", sign)) %>%
group_by(ID, date_time_ID, date_time_ID_ref, sign) %>%
summarise(CT_star_i_diff = sum(value_diff) / 1000) %>%
ungroup()
# calculate cumulative values
iCT_star_sign_temp <- iCT_star_sign_temp %>%
group_by(sign) %>%
arrange(date_time_ID) %>%
mutate(CT_star_i_cum = cumsum(CT_star_i_diff)) %>%
ungroup()
# fill empty values
iCT_star_sign_temp <-
full_join(iCT_star_sign_temp, iCT_star_grid_sign) %>%
arrange(sign, date_time_ID) %>%
fill(CT_star_i_cum)
# calculations for total changes
# integrate (ie sum up) across depth
iCT_star_total_temp <- tm_profiles_ID_long %>%
filter(var == "CT_star", dep < i_dep) %>%
group_by(ID, date_time_ID, date_time_ID_ref) %>%
summarise(CT_star_i_diff = sum(value_diff) / 1000) %>%
ungroup()
# calculate cumulative values
iCT_star_total_temp <- iCT_star_total_temp %>%
arrange(date_time_ID) %>%
mutate(CT_star_i_cum = cumsum(CT_star_i_diff)) %>%
ungroup() %>%
mutate(sign = "total")
# fill empty values
iCT_star_total_temp <-
full_join(iCT_star_total_temp, iCT_star_grid_total) %>%
arrange(sign, date_time_ID) %>%
fill(CT_star_i_cum)
# join data frames
iCT_star_temp <-
bind_rows(iCT_star_sign_temp, iCT_star_total_temp) %>%
mutate(i_dep = i_dep)
# bind data for various integration depths
if (exists("iCT_star")) {
iCT_star <- bind_rows(iCT_star, iCT_star_temp)
} else {
iCT_star <- iCT_star_temp
}
rm(iCT_star_temp, iCT_star_sign_temp, iCT_star_total_temp)
}
rm(iCT_star_grid_sign, iCT_star_grid_total)
iCT_star <- iCT_star %>%
mutate(i_dep = as.factor(i_dep))
iCT_star_fixed_dep <- iCT_star
rm(iCT_star, i_dep)
As the bulk changes of CT* occur in the surface water, the choice of the exact fixed integration depth has only minor impact on the derived depth integrated time series.
iCT_star_fixed_dep %>%
ggplot() +
geom_point(data = cruise_dates, aes(date_time_ID, 0), shape = 21) +
geom_col(
aes(date_time_ID_ref, CT_star_i_diff, fill = i_dep),
position = "dodge",
alpha = 0.3
) +
geom_line(aes(date_time_ID, CT_star_i_cum, col = i_dep)) +
scale_color_viridis_d() +
scale_fill_viridis_d() +
scale_x_datetime(breaks = "week", date_labels = "%d %b") +
facet_grid(sign ~ ., scales = "free_y", space = "free_y") +
theme_bw()
As an alternative to fixed depth levels, vertical integration as low as the mixed layer depth was tested.
Seawater density Rho was determined from S, T, and p according to TEOS-10.
tm_profiles <- tm_profiles %>%
mutate(rho = swSigma(
salinity = sal,
temperature = tem,
pressure = dep / 10
))
# hydrographical profiles cruise mean
tm_profiles_ID_mean_hydro <- tm_profiles %>%
select(-c(station, lat, lon, pCO2_corr, pCO2, CT_star, date_time)) %>%
group_by(ID, date_time_ID, date_ID, dep) %>%
summarise_all(list(mean), na.rm = TRUE) %>%
ungroup()
# hydrographical profiles cruise SD
tm_profiles_ID_sd_hydro <- tm_profiles %>%
select(-c(station, lat, lon, pCO2_corr, pCO2, CT_star, date_time)) %>%
group_by(ID, date_time_ID, date_ID, dep) %>%
summarise_all(list(sd), na.rm = TRUE) %>%
ungroup()
# convert to long format
tm_profiles_ID_sd_hydro_long <- tm_profiles_ID_sd_hydro %>%
pivot_longer(sal:rho, names_to = "var", values_to = "sd")
# convert to long format
tm_profiles_ID_mean_hydro_long <- tm_profiles_ID_mean_hydro %>%
pivot_longer(sal:rho, names_to = "var", values_to = "value")
# join data frames
tm_profiles_ID_hydro_long <-
inner_join(tm_profiles_ID_mean_hydro_long,
tm_profiles_ID_sd_hydro_long)
tm_profiles_ID_hydro <- tm_profiles_ID_mean_hydro
rm(
tm_profiles_ID_mean_hydro_long,
tm_profiles_ID_mean_hydro,
tm_profiles_ID_sd_hydro_long,
tm_profiles_ID_sd_hydro
)
tm_profiles_ID_hydro_long %>%
ggplot(aes(value, dep, col = ID)) +
geom_point() +
geom_path() +
scale_y_reverse() +
scale_color_viridis_d() +
facet_wrap( ~ var, scales = "free_x")
Mixed layer depth (MLD) was determined based on the difference between density at the surface and at depth, for a range of density criteria: 0.1, 0.2, 0.5
tm_profiles_ID_hydro <-
expand_grid(tm_profiles_ID_hydro,
rho_lim = parameters$rho_lim_integration_depths)
# calculate MLD for each rho threshold
MLD <- tm_profiles_ID_hydro %>%
arrange(dep) %>%
group_by(ID, date_time_ID, rho_lim) %>%
mutate(d_rho = rho - first(rho)) %>%
filter(d_rho > rho_lim) %>%
summarise(MLD = min(dep)) %>%
ungroup()
tm_profiles_ID_hydro <-
full_join(tm_profiles_ID_hydro, MLD) %>%
mutate(rho_lim = as.factor(rho_lim))
tm_profiles_ID_hydro %>%
arrange(dep) %>%
ggplot(aes(rho, dep)) +
geom_hline(aes(yintercept = MLD, col = rho_lim)) +
geom_path() +
scale_y_reverse() +
scale_color_brewer(palette = "Set1") +
facet_wrap( ~ ID) +
theme_bw()
MLD <- MLD %>%
mutate(rho_lim = as.factor(rho_lim))
MLD %>%
ggplot(aes(date_time_ID, MLD, col = rho_lim)) +
geom_hline(yintercept = 0) +
geom_point() +
geom_path() +
scale_color_brewer(palette = "Set1") +
scale_y_reverse() +
scale_x_datetime(breaks = "week", date_labels = "%d %b") +
labs(x = "")
iCT_star <- tm_profiles_ID_long %>%
filter(var == "CT_star")
# join CT and MLD data frame
iCT_star <- full_join(iCT_star, MLD)
# filter data at depth below MLD
iCT_star <- iCT_star %>%
filter(dep <= MLD)
# calculate incremental changes
iCT_star <- iCT_star %>%
group_by(ID, date_time_ID, date_time_ID_ref, rho_lim) %>%
summarise(CT_star_i_diff = sum(value_diff)/1000) %>%
ungroup()
# calculate cumulative changes
iCT_star <- iCT_star %>%
group_by(rho_lim) %>%
arrange(date_time_ID) %>%
mutate(CT_star_i_cum = cumsum(CT_star_i_diff)) %>%
ungroup()
iCT_star_MLD <- iCT_star
rm(iCT_star, MLD, tm_profiles_ID_hydro, tm_profiles_ID_hydro_long)
iCT_star_MLD %>%
ggplot() +
geom_point(data = cruise_dates, aes(date_time_ID, 0), shape = 21) +
geom_col(
aes(date_time_ID_ref, CT_star_i_diff, fill = rho_lim),
position = "dodge",
alpha = 0.3
) +
geom_line(aes(date_time_ID, CT_star_i_cum, col = rho_lim)) +
scale_color_viridis_d() +
scale_fill_viridis_d() +
scale_x_datetime(breaks = "week", date_labels = "%d %b") +
theme_bw()
In the following, all cumulative iCT* trajectories are displayed. Highlighted are those obtained for the fixed depth approach with 12 m limit, and the MLD approach with a standard density threshold of 0.1 kg/m3.
# join data frames with MLD and fixed integration depth
iCT_star <- full_join(iCT_star_fixed_dep, iCT_star_MLD)
# change column types
iCT_star <- iCT_star %>%
mutate(group = paste(
as.character(sign),
as.character(i_dep),
as.character(rho_lim)
))
iCT_star %>%
arrange(date_time_ID) %>%
ggplot() +
geom_hline(yintercept = 0) +
geom_line(aes(date_time_ID, CT_star_i_cum,
group = group), col = "grey") +
geom_line(
data = iCT_star_fixed_dep %>% filter(i_dep == 12, sign == "total"),
aes(date_time_ID, CT_star_i_cum, col = "12m - total")
) +
geom_line(data = iCT_star_MLD %>% filter(rho_lim == 0.1),
aes(date_time_ID, CT_star_i_cum, col = "MLD - 0.1")) +
scale_color_brewer(palette = "Set1", name = "Integration depth") +
geom_point(data = cruise_dates, aes(date_time_ID, 0), shape = 21) +
scale_x_datetime(breaks = "week", date_labels = "%d %b")
rm(iCT_star, iCT_star_MLD)
In order to derive an estimate of the net community production NCP (which is equivalent to the formed organic matter that can be exported from the investigated surface layer), two steps are required:
decision about the most appropiate iCT trajectory
correction of quantifyable CO2 fluxes in and out of the investigated water volume during the period of interest, this includes:
To determine the optimum depth for the CT* integration we investigated the vertical distribution of cumulative temperature and CT* changes on the peak of the productivity signal on June 23:
# subset data from bloom peak
tm_profiles_ID_long_180723 <- tm_profiles_ID_long %>%
filter(ID == 180723,
var == "CT_star")
p_tm_profiles_ID_long <- tm_profiles_ID_long_180723 %>%
arrange(dep) %>%
ggplot(aes(value_cum, dep)) +
geom_vline(xintercept = 0) +
geom_hline(yintercept = 12, col = "red") +
geom_point() +
geom_path() +
scale_y_reverse() +
labs(x = "Cumulative change of CT_star on July 23 (180723)") +
theme(legend.position = "left")
# calculate column integral
tm_profiles_ID_long_180723_dep <- tm_profiles_ID_long_180723 %>%
select(dep, value_cum) %>%
filter(value_cum < 0) %>%
arrange(dep) %>%
mutate(
value_cum_i = sum(value_cum),
value_cum_dep = cumsum(value_cum),
value_cum_i_rel = value_cum_dep / value_cum_i * 100
)
p_tm_profiles_ID_long_rel <- tm_profiles_ID_long_180723_dep %>%
ggplot(aes(value_cum_i_rel, dep)) +
geom_hline(yintercept = 12, col = "red") +
geom_vline(xintercept = 90) +
geom_point() +
geom_line() +
scale_y_reverse(limits = c(25, 0)) +
scale_x_continuous(breaks = seq(0, 100, 10)) +
labs(y = "Depth (m)", x = "Relative contribution on July 23") +
theme_bw()
p_tm_profiles_ID_long + p_tm_profiles_ID_long_rel
rm(
tm_profiles_ID_long_180723,
tm_profiles_ID_long_180723_dep,
p_tm_profiles_ID_long,
p_tm_profiles_ID_long_rel
)
# subset data from bloom peak
tm_profiles_ID_long_180723 <- tm_profiles_ID_long %>%
filter(ID == 180723,
var == "tem")
p_tm_profiles_ID_long <- tm_profiles_ID_long_180723 %>%
arrange(dep) %>%
ggplot(aes(value_cum, dep)) +
geom_vline(xintercept = 0) +
geom_hline(yintercept = 12, col = "red") +
geom_point() +
geom_path() +
scale_y_reverse() +
labs(x = "Cumulative change of Temp on July 23") +
theme(legend.position = "left")
# calculate column integral
tm_profiles_ID_long_180723_dep <- tm_profiles_ID_long_180723 %>%
select(dep, value_cum) %>%
filter(value_cum > 0) %>%
arrange(dep) %>%
mutate(
value_cum_i = sum(value_cum),
value_cum_dep = cumsum(value_cum),
value_cum_i_rel = value_cum_dep / value_cum_i * 100
)
p_tm_profiles_ID_long_rel <- tm_profiles_ID_long_180723_dep %>%
ggplot(aes(value_cum_i_rel, dep)) +
geom_hline(yintercept = 12, col = "red") +
geom_vline(xintercept = 90) +
geom_point() +
geom_line() +
scale_y_reverse(limits = c(25, 0)) +
scale_x_continuous(breaks = seq(0, 100, 10)) +
labs(y = "Depth (m)", x = "Relative contribution on July 23") +
theme_bw()
p_tm_profiles_ID_long + p_tm_profiles_ID_long_rel
rm(
tm_profiles_ID_long_180723,
tm_profiles_ID_long_180723_dep,
p_tm_profiles_ID_long,
p_tm_profiles_ID_long_rel
)
The cummulative iCT* trajectory determined by integration of CT* to a fixed water depth of 12 m was used for NCP calculation for the following reasons:
During the first productivity pulse that lasted until July 23:
MLD were too shallow to cover all observed negative CT* changes
The mean pCO2 of each cruise recorded in profiling-mode (stations only) and depths < 6`m was used for gas exchange calculations.
# surface time series data in long format
tm_profiles_surface_long <- tm_profiles %>%
filter(dep < parameters$surface_dep) %>%
select(date_time = date_time_ID, ID, tem, pCO2 = pCO2, CT_star) %>%
pivot_longer(tem:CT_star, values_to = "value", names_to = "var")
tm_profiles_surface_long_ID <- tm_profiles_surface_long %>%
group_by(ID, date_time, var) %>%
summarise_all(list( ~ mean(.), ~ sd(.), ~ min(.), ~ max(.))) %>%
ungroup()
rm(tm_profiles_surface_long)
# plot surface time series
p_pCO2_surf <- tm_profiles_surface_long_ID %>%
filter(var == "pCO2") %>%
ggplot(aes(x = date_time)) +
geom_ribbon(aes(ymin = mean - sd, ymax = mean + sd,
fill = "\u00B1 SD"), alpha = 0.2) +
geom_path(aes(y = mean)) +
geom_point(aes(y = mean)) +
scale_color_manual(name = "", values = "black", guide = FALSE) +
scale_fill_manual(name = "", values = "black", guide = FALSE) +
scale_x_datetime(date_breaks = "week",
sec.axis = dup_axis()) +
labs(y = expression(atop(italic(p)*CO[2], (mu * atm)))) +
theme(axis.title.x = element_blank(),
axis.text.x = element_blank(),
legend.title = element_blank(),
plot.margin = margin(0, 0, 0, 0, "cm"))
p_tem_surf <- tm_profiles_surface_long_ID %>%
filter(var == "tem") %>%
ggplot(aes(x = date_time)) +
geom_ribbon(aes(
ymin = mean - sd,
ymax = mean + sd,
fill = "Mean \u00B1 SD"
),
alpha = 0.2) +
geom_path(aes(y = mean, col = "Mean \u00B1 SD")) +
geom_point(aes(y = mean, col = "Mean \u00B1 SD")) +
scale_color_manual(name = "Sensor data", values = "black") +
scale_fill_manual(name = "Sensor data", values = "black") +
scale_x_datetime(date_breaks = "week",
sec.axis = dup_axis()) +
labs(y = expression(atop("SST", "(\u00B0C)"))) +
theme(
axis.title.x = element_blank(),
axis.text.x = element_blank(),
legend.key.height = unit(5, "mm"),
legend.key.width = unit(5,"mm"),
plot.margin = margin(0, 0, 0, 0, "cm")
)
p_CT_star_surf <-
tm_profiles_surface_long_ID %>%
filter(var == "CT_star") %>%
ggplot() +
geom_ribbon(aes(
x = date_time,
ymin = mean - sd,
ymax = mean + sd,
fill = "\u00B1 SD"
),
alpha = 0.2) +
geom_path(aes(x = date_time, y = mean)) +
geom_point(aes(x = date_time, y = mean)) +
scale_color_manual(name = "", values = "black", guide = FALSE) +
scale_fill_manual(name = "", values = "black", guide = FALSE) +
new_scale_color() +
geom_linerange(
data = tb_surface_station_mean %>%
filter(var == "CT_star"),
aes(
x = date_time_ID,
ymin = value_mean - value_sd,
ymax = value_mean + value_sd,
color = "Mean \u00B1 SD"
)
) +
geom_point(
data = tb_surface_station_mean %>%
filter(var == "CT_star"),
aes(x = date_time_ID,
y = value_mean,
color = "Mean \u00B1 SD")
) +
scale_color_manual(name = "Bottle data", values = "red") +
scale_x_datetime(date_breaks = "week",
sec.axis = dup_axis()) +
labs(y = expression(atop(paste(C[T], "*"),
(mu * mol ~ kg ^ {
-1
})))) +
theme(
axis.title.x = element_blank(),
axis.text.x = element_blank(),
legend.key.height = unit(5, "mm"),
legend.key.width = unit(5,"mm"),
plot.margin = margin(0, 0, 0, 0, "cm")
)
p_pCO2_surf + p_tem_surf + p_CT_star_surf +
plot_layout(ncol = 1)
start <- min(tm_profiles_surface_long_ID$date_time)
end <- max(tm_profiles_surface_long_ID$date_time)
The mean values per cruise and regional variability of surface water parameters was:
tm_profiles_surface_long_ID %>%
arrange(var) %>%
kable() %>%
add_header_above() %>%
kable_styling(full_width = FALSE) %>%
scroll_box(height = "400px")
ID | date_time | var | mean | sd | min | max |
---|---|---|---|---|---|---|
180705 | 2018-07-06 11:14:37 | CT_star | 1529.03664 | 8.2860670 | 1511.48597 | 1542.59277 |
180709 | 2018-07-10 08:45:37 | CT_star | 1500.62312 | 15.2681716 | 1471.06090 | 1520.34195 |
180718 | 2018-07-19 10:01:48 | CT_star | 1466.21102 | 11.7110194 | 1447.28435 | 1498.63202 |
180723 | 2018-07-24 07:58:29 | CT_star | 1439.88075 | 8.8623734 | 1415.45985 | 1455.43963 |
180730 | 2018-07-31 03:46:19 | CT_star | 1474.16535 | 25.0604599 | 1439.64329 | 1519.20430 |
180802 | 2018-08-03 05:15:01 | CT_star | 1458.26021 | 20.7150349 | 1433.97552 | 1508.09974 |
180806 | 2018-08-07 09:27:12 | CT_star | 1473.12374 | 13.3837746 | 1447.00957 | 1491.52908 |
180815 | 2018-08-16 00:06:57 | CT_star | 1556.12148 | 8.3924379 | 1540.81503 | 1570.11756 |
180705 | 2018-07-06 11:14:37 | pCO2 | 98.46479 | 6.0783446 | 87.19708 | 110.10829 |
180709 | 2018-07-10 08:45:37 | pCO2 | 86.08577 | 7.5655796 | 72.44860 | 95.54848 |
180718 | 2018-07-19 10:01:48 | pCO2 | 78.58691 | 6.5048160 | 69.81332 | 101.52255 |
180723 | 2018-07-24 07:58:29 | pCO2 | 68.89903 | 3.6761271 | 59.87298 | 75.31606 |
180730 | 2018-07-31 03:46:19 | pCO2 | 99.47526 | 18.7269290 | 79.74149 | 134.65085 |
180802 | 2018-08-03 05:15:01 | pCO2 | 91.10383 | 13.6139306 | 77.85520 | 126.69682 |
180806 | 2018-08-07 09:27:12 | pCO2 | 92.07698 | 7.7401816 | 78.38500 | 103.82752 |
180815 | 2018-08-16 00:06:57 | pCO2 | 140.86604 | 7.9253537 | 126.20428 | 154.87765 |
180705 | 2018-07-06 11:14:37 | tem | 15.33894 | 0.4452327 | 14.56363 | 16.25378 |
180709 | 2018-07-10 08:45:37 | tem | 16.98802 | 0.4766242 | 16.06309 | 17.89843 |
180718 | 2018-07-19 10:01:48 | tem | 20.39920 | 0.4276053 | 19.76884 | 21.24796 |
180723 | 2018-07-24 07:58:29 | tem | 21.42787 | 0.5128097 | 21.00967 | 22.95619 |
180730 | 2018-07-31 03:46:19 | tem | 24.24554 | 0.4607887 | 23.64305 | 25.31485 |
180802 | 2018-08-03 05:15:01 | tem | 24.86365 | 0.1595463 | 24.53541 | 25.17608 |
180806 | 2018-08-07 09:27:12 | tem | 22.96251 | 0.2082844 | 22.60425 | 23.35020 |
180815 | 2018-08-16 00:06:57 | tem | 18.62939 | 0.2737599 | 18.13858 | 19.01634 |
For the time period of the production pulse from July 6 - 24, the regional variability within the study area can be summarized as:
tm_profiles_surface_long_ID %>%
filter(date_time < ymd("2018-07-26")) %>%
group_by(var) %>%
summarise(SD_mean = mean(sd)) %>%
ungroup() %>%
kable() %>%
add_header_above() %>%
kable_styling(full_width = FALSE)
var | SD_mean |
---|---|
CT_star | 11.031908 |
pCO2 | 5.956217 |
tem | 0.465568 |
Meteorological data were recorded on the flux tower located on Östergarnsholm island.
# read data
og <-
read_csv(here::here("data/intermediate/_summarized_data_files",
"og.csv"))
# filter time period of field study
og <- og %>%
filter(date_time > start,
date_time < end)
rm(end, start)
Wind speed was determined at 12 and converted to 10 m above sea level, to be used for gas exchange calculation.
og <- og %>%
mutate(wind = wind.scale.base(wnd = wind, wnd.z = 12))
p_pCO2_atm <- og %>%
ggplot(aes(x = date_time)) +
geom_path(aes(y = pCO2_atm)) +
scale_x_datetime(date_breaks = "week",
sec.axis = dup_axis()) +
labs(y = expression(atop(italic(p)*CO["2,atm"], (mu * atm)))) +
theme(axis.title.x = element_blank(),
axis.text.x = element_blank(),
plot.margin = margin(0, 0, 0, 0, "cm"))
p_wind <- og %>%
ggplot(aes(x = date_time)) +
geom_path(aes(y = wind)) +
scale_x_datetime(date_breaks = "week",
sec.axis = dup_axis()) +
labs(y = expression(atop(U["10"], (m ~ s ^ {
-1
})))) +
theme(
axis.title.x = element_blank(),
axis.text.x = element_blank(),
legend.title = element_blank(),
plot.margin = margin(0, 0, 0, 0, "cm")
)
p_pCO2_atm + p_wind +
plot_layout(ncol = 1) +
plot_layout(guides = 'collect')
Data sets for atmospheric and seawater observations were merged and seawater date were interpolated to the time stamp of atmospheric data.
tm_profiles_surface_ID <- tm_profiles_surface_long_ID %>%
filter(var %in% c("pCO2", "tem")) %>%
select(date_time:mean) %>%
pivot_wider(names_from = "var", values_from = "mean")
rm(tm_profiles_surface_long_ID)
tm_og <- full_join(og, tm_profiles_surface_ID) %>%
arrange(date_time)
tm_og <- tm_og %>%
mutate(
pCO2 = approxfun(date_time, pCO2)(date_time),
tem = approxfun(date_time, tem)(date_time),
wind = approxfun(date_time, wind)(date_time)
) %>%
filter(!is.na(pCO2_atm))
rm(tm_profiles_surface_ID, og)
F = k * dCO2
with
dCO2 = K0 * dpCO2 and
k = coeff * U^2 * (660/Sc)^0.5
Unitm used here are:
dpCO2: µatm
K0: mol atm-1 kg-1
dCO2: µmol kg-1
wind speed U: m s-1
coeff for k calculation (eg 0.251 in W14): cm hr-1 (m s-1)-2
gas transfer velocities k: cm hr-1 (= 60 x 60 x 100 m s-1)
air sea CO2 flux F: mol m–2 d–1
conversion between the unit of k * dCO2 and F requires a factor of 10-5 * 24
# define gas exchange coefficient according to Wanninkhof 2014
Sc_W14 <- function(tem) {
2116.8 - 136.25 * tem + 4.7353 * tem ^ 2 - 0.092307 * tem ^ 3 + 0.0007555 * tem ^
4
}
# Sc_W14(20)
tm_og <- tm_og %>%
mutate(
dpCO2 = pCO2 - pCO2_atm,
dCO2 = dpCO2 * K0(S = 6.92, T = tem),
# W92 = gas_transfer(t = tem, u10 = wind, species = "CO2",
# method = "Wanninkhof1")* 60^2 * 100,
#k_SM18 = 0.24 * wind^2 * ((1943-119.6*tem + 3.488*tem^2 - 0.0417*tem^3) / 660)^(-0.5),
k = 0.251 * wind ^ 2 * (Sc_W14(tem) / 660) ^ (-0.5)
)
# calculate flux F [mol m–2 d–1]
tm_og <- tm_og %>%
mutate(flux = k * dCO2 * 1e-5 * 24)
rm(Sc_W14)
p_flux_daily <- tm_og %>%
ggplot(aes(x = date_time)) +
geom_path(aes(y = flux)) +
scale_x_datetime(date_breaks = "week",
sec.axis = dup_axis()) +
labs(y = expression(atop(F["daily"], (mol ~ m ^ {
-2
} ~ d ^ {
-1
})))) +
theme(
axis.title.x = element_blank(),
axis.text.x = element_blank(),
legend.title = element_blank(),
plot.margin = margin(0, 0, 0, 0, "cm")
)
# scale flux data from daily to 30 min (measurement freuquency)$
# calculate cumulative fluc
tm_og <- tm_og %>%
mutate(scale = 24 * 2) %>%
mutate(flux_scale = flux / scale) %>%
arrange(date_time) %>%
mutate(flux_cum = cumsum(flux_scale)) %>%
ungroup()
p_flux_cum <- tm_og %>%
ggplot(aes(x = date_time)) +
geom_path(aes(y = flux_cum)) +
scale_fill_discrete(guide = FALSE) +
scale_x_datetime(date_breaks = "week",
sec.axis = dup_axis()) +
labs(y = expression(atop(F["cum"],
(mol ~ m ^ {
-2
})))) +
theme(
axis.title.x = element_blank(),
axis.text.x = element_blank(),
plot.margin = margin(0, 0, 0, 0, "cm")
)
p_flux_daily + p_flux_cum +
plot_layout(ncol = 1)
The cumulative integrated CT* (iCT*) time series obtained through integration across the upper 12m of the water column was used for further calculations of NCP.
Correction of iCT* for air-sea CO2 fluxes will be based on estimates derived from observation with 30min measurement interval and calculation according to Wanninkhof (2014).
To derive an integrated NCP estimated, the observed change in iCT* must be corrected for the air-sea flux of CO2. iCT* was determined for the upper 12m of the water column. The MLD was always shallower 12m, except for the last cruise day. Therefore:
During the last cruise, deeper mixing up to 17m water depth was observed, resulting in increased iCT* at 0-12 m and a decrease of iCT* in 12-17m. The loss of CT* in 12-17m can be assumed to be entirely cause by mixing with low CT* surface water. However, some of the observed iCT* loss is balanced through CT* input attributable to the air-sea flux. Therefore, the observed loss, corrected for 5/17 of the air-sea-flux, was added to the iCT* changes in 0-12m.
# extract CT data for fixed depth approach, depth limit 10m
NCP <- iCT_star_fixed_dep %>%
filter(i_dep == parameters$i_dep_lim, sign == "total") %>%
select(-c(sign, i_dep))
rm(iCT_star_fixed_dep)
NCP <- NCP %>%
select(ID, date_time = date_time_ID, date_time_ID_ref, CT_star_i_diff, CT_star_i_cum)
# date of the second last cruise
date_180806 <- unique(NCP$date_time)[7]
# calculate cumulative air-sea fluxes affecting surface water column
tm_og_flux <- tm_og %>%
mutate(
flux_scale = if_else(
date_time > date_180806,
parameters$i_dep_lim / parameters$i_dep_mix_lim * flux_scale,
flux_scale
)
) %>%
arrange(date_time) %>%
mutate(flux_cum = cumsum(flux_scale)) %>%
select(date_time, flux_cum)
# calculate cumulative air-sea fluxes affecting deepened mixed layer
# tm_og_flux_dep <- tm_og %>%
# filter(date_time > date_180806) %>%
# mutate(
# flux_scale =
# (parameters$i_dep_mix_lim - parameters$i_dep_lim) / parameters$i_dep_mix_lim * flux_scale
# ) %>%
# arrange(date_time) %>%
# mutate(flux_cum = cumsum(flux_scale)) %>%
# select(date_time, flux_cum)
NCP_flux <- full_join(NCP, tm_og_flux) %>%
arrange(date_time)
rm(tm_og_flux, NCP, tm_og)
# linear interpolation of cumulative changes to frequency of the flux estimates estimates
NCP_flux <- NCP_flux %>%
mutate(
CT_star_i_cum = approxfun(date_time, CT_star_i_cum)(date_time),
flux_cum = approxfun(date_time, flux_cum)(date_time)
) %>%
fill(flux_cum) %>%
mutate(CT_star_i_flux_cum = CT_star_i_cum + flux_cum)
# calculate cumulative fluxes between cruises
NCP_flux_diff <- NCP_flux %>%
filter(!is.na(date_time_ID_ref)) %>%
mutate(flux_diff = flux_cum - lag(flux_cum, default = 0)) %>%
select(ID, date_time_ID_ref, observed = CT_star_i_diff, flux = flux_diff) %>%
pivot_longer(cols = "observed":"flux",
names_to = "var",
values_to = "value_diff")
The aim is to approximate the CT* entrainment flux between Aug 06 and 15. The relevant profiles are:
# calculate mean volume weighted CT* before micing
CT_mix <- tm_profiles_ID_long %>%
filter(ID == "180806",
var == "CT_star",
dep < parameters$i_dep_mix_lim) %>%
summarise(CT_star_surface = sum(value) / parameters$i_dep_mix_lim) %>%
pull()
# subset CT* profile before mixing
CT_profile <- tm_profiles_ID_mean %>%
filter(ID %in% c("180806"))
p_CT_star <- CT_profile %>%
ggplot() +
geom_rect(
data = CT_profile %>% filter(dep > 12, dep < 17),
aes(
xmax = CT_star,
xmin = CT_mix,
ymax = dep + 0.5,
ymin = dep - 0.5
),
alpha = 0.2
) +
geom_hline(yintercept = c(12, 17)) +
geom_segment(aes(
x = CT_mix,
xend = CT_mix,
y = -Inf,
yend = 17
),
linetype = 2) +
annotate(
"text",
label = as.character(expression(paste(C[T], "*") ~ mix)),
parse = TRUE,
x = 1580,
y = 3,
size = geom_text_size
) +
annotate(
"text",
label = as.character(expression(paste(C[T], "*") ~ flux)),
parse = TRUE,
x = 1580,
y = 14.5,
size = geom_text_size
) +
geom_point(aes(CT_star, dep, fill = ID), shape = 21) +
geom_path(aes(CT_star, dep, col = ID)) +
scale_y_reverse() +
scale_fill_viridis_d() +
scale_color_viridis_d() +
labs(y = "Depth (m)", x = expression(paste(C[T], "*", ~ (µmol ~ kg ^ {
-1
})))) +
theme(
legend.title = element_blank(),
axis.text.y = element_blank(),
axis.ticks.y = element_blank(),
axis.title.y = element_blank(),
legend.position = "none"
)
# subset temperature profiles before and after mixing
tm_profiles_ID_long_temp <-
left_join(
tm_profiles_ID_long %>%
filter(ID %in% c("180806", "180815"),
var %in% c("tem")) %>%
select(-date_ID),
cruise_dates
)
p_tem <- tm_profiles_ID_long_temp %>%
ggplot() +
geom_hline(yintercept = c(12, 17)) +
geom_path(aes(value, dep, col = date_ID)) +
geom_point(aes(value, dep, fill = date_ID), shape = 21) +
scale_y_reverse() +
scale_color_viridis_d(name = "Mean\ncruise date") +
scale_fill_viridis_d(name = "Mean\ncruise date") +
labs(y = "Depth (m)", x = expression(paste(Temperature ~ "(\u00B0C)")))
p_tem + p_CT_star +
plot_layout(guides = 'collect') +
plot_annotation(tag_levels = 'a')
ggsave(
here::here("output/Plots/Figures_publication/appendix",
"Fig_C2.pdf"),
width = 130,
height = 110,
dpi = 300,
units = "mm"
)
ggsave(
here::here("output/Plots/Figures_publication/appendix",
"Fig_C2.png"),
width = 130,
height = 110,
dpi = 300,
units = "mm"
)
rm(p_tem, p_CT_star, CT_profile, tm_profiles_ID_long_temp)
The effect of mixing was derived from the mean concentration difference on Aug 07.
# calculate mixing with deep waters
NCP_mix_deep <- tm_profiles_ID_long %>%
filter(
ID == "180806",
var == "CT_star",
dep < parameters$i_dep_mix_lim,
dep > parameters$i_dep_lim
) %>%
mutate(CT_star_delta_mix = CT_mix - value) %>%
summarise(value_diff = sum(CT_star_delta_mix) / 1000) %>%
mutate(ID = "180815")
# rm(tm_og_flux_dep)
NCP_mix_deep_diff <- NCP_mix_deep %>%
mutate(var = "mixing")
# join flux and mixing correction time series data: incremental
NCP_flux_mix_diff <-
full_join(NCP_flux_diff, NCP_mix_deep_diff) %>%
arrange(ID) %>%
fill(date_time_ID_ref)
NCP_mix_deep <- NCP_mix_deep %>%
rename(mix_cum = value_diff) %>%
select(ID, mix_cum)
# join flux and mixing correction time series data: cumulative
NCP_flux_mix <-
full_join(NCP_flux,
NCP_mix_deep)
rm(NCP_mix_deep,
NCP_mix_deep_diff,
NCP_flux,
NCP_flux_diff,
date_180806)
NCP_flux_mix <- NCP_flux_mix %>%
arrange(date_time) %>%
fill(ID) %>%
mutate(
mix_cum = if_else(ID %in% c("180806", 180815), mix_cum, 0),
mix_cum = na.approx(mix_cum),
CT_star_i_flux_mix_cum = CT_star_i_flux_cum + mix_cum
)
# reorder factors for plotting
NCP_flux_mix_diff <- NCP_flux_mix_diff %>%
mutate(var = factor(var, c("observed", "flux", "mixing")))
NCP_flux_mix_long <- NCP_flux_mix %>%
select(date_time,
CT_star_i_cum,
CT_star_i_flux_cum,
CT_star_i_flux_mix_cum) %>%
pivot_longer(CT_star_i_cum:CT_star_i_flux_mix_cum,
values_to = "value",
names_to = "var") %>%
mutate(
var = fct_recode(
var,
observed = "CT_star_i_cum",
`flux corrected` = "CT_star_i_flux_cum",
`flux + mixing\ncorrected (NCP)` = "CT_star_i_flux_mix_cum"
)
)
p_iCT_star <- NCP_flux_mix_long %>%
arrange(date_time) %>%
ggplot() +
geom_col(
data = NCP_flux_mix_diff,
aes(date_time_ID_ref, value_diff, fill = var),
position = position_dodge2(preserve = "single"),
alpha = 0.5
) +
geom_hline(yintercept = 0) +
geom_point(data = cruise_dates, aes(date_time_ID, 0), shape = 21) +
geom_line(aes(date_time, value, col = var)) +
scale_x_datetime(date_breaks = "week",
date_labels = "%b %d",
sec.axis = dup_axis()) +
scale_fill_brewer(palette = "Dark2", name = "Incremental changes") +
scale_color_brewer(palette = "Dark2", name = "Cumulative changes") +
labs(y = expression(atop(Integrated ~ paste(C[T], "*"), (mol ~ m ^ {
-2
})))) +
guides(fill = guide_legend(order = 2)) +
theme(
axis.title.x = element_blank(),
axis.text.x.top = element_blank(),
legend.key.height = unit(5, "mm"),
legend.key.width = unit(5, "mm"),
plot.margin = margin(0, 0, 0, 0, "cm")
)
p_iCT_star
NCP_flux_mix %>%
write_csv(
here::here(
"data/intermediate/_merged_data_files/CT_dynamics",
"tm_NCP_cum.csv"
)
)
NCP_flux_mix_diff %>%
write_csv(
here::here(
"data/intermediate/_merged_data_files/CT_dynamics",
"tm_NCP_inc.csv"
)
)
sessionInfo()
R version 4.0.3 (2020-10-10)
Platform: x86_64-w64-mingw32/x64 (64-bit)
Running under: Windows 10 x64 (build 18363)
Matrix products: default
locale:
[1] LC_COLLATE=English_Germany.1252 LC_CTYPE=English_Germany.1252
[3] LC_MONETARY=English_Germany.1252 LC_NUMERIC=C
[5] LC_TIME=English_Germany.1252
attached base packages:
[1] grid stats graphics grDevices utils datasets methods
[8] base
other attached packages:
[1] ggsn_0.5.0 ggnewscale_0.4.5 rgdal_1.5-18
[4] LakeMetabolizer_1.5.0 rLakeAnalyzer_1.11.4.1 kableExtra_1.3.1
[7] sp_1.4-4 tibbletime_0.1.6 zoo_1.8-8
[10] lubridate_1.7.9.2 scico_1.2.0 metR_0.9.0
[13] marelac_2.1.10 shape_1.4.5 seacarb_3.2.14
[16] oce_1.2-0 gsw_1.0-5 testthat_3.0.1
[19] patchwork_1.1.1 forcats_0.5.0 stringr_1.4.0
[22] dplyr_1.0.2 purrr_0.3.4 readr_1.4.0
[25] tidyr_1.1.2 tibble_3.0.4 ggplot2_3.3.3
[28] tidyverse_1.3.0 workflowr_1.6.2
loaded via a namespace (and not attached):
[1] colorspace_2.0-0 rjson_0.2.20 ellipsis_0.3.1
[4] class_7.3-17 rprojroot_2.0.2 fs_1.5.0
[7] rstudioapi_0.13 farver_2.0.3 fansi_0.4.1
[10] xml2_1.3.2 codetools_0.2-16 knitr_1.30
[13] jsonlite_1.7.2 broom_0.7.3 dbplyr_2.0.0
[16] png_0.1-7 compiler_4.0.3 httr_1.4.2
[19] backports_1.2.1 assertthat_0.2.1 cli_2.2.0
[22] later_1.1.0.1 htmltools_0.5.0 tools_4.0.3
[25] ggmap_3.0.0 gtable_0.3.0 glue_1.4.2
[28] Rcpp_1.0.5 cellranger_1.1.0 raster_3.4-5
[31] vctrs_0.3.6 xfun_0.19 ps_1.5.0
[34] rvest_0.3.6 lifecycle_0.2.0 scales_1.1.1
[37] hms_0.5.3 promises_1.1.1 RColorBrewer_1.1-2
[40] yaml_2.2.1 stringi_1.5.3 highr_0.8
[43] maptools_1.0-2 e1071_1.7-4 checkmate_2.0.0
[46] RgoogleMaps_1.4.5.3 rlang_0.4.10 pkgconfig_2.0.3
[49] bitops_1.0-6 evaluate_0.14 lattice_0.20-41
[52] sf_0.9-6 labeling_0.4.2 tidyselect_1.1.0
[55] here_1.0.1 plyr_1.8.6 magrittr_2.0.1
[58] R6_2.5.0 generics_0.1.0 DBI_1.1.0
[61] pillar_1.4.7 haven_2.3.1 whisker_0.4
[64] foreign_0.8-80 withr_2.3.0 units_0.6-7
[67] modelr_0.1.8 crayon_1.3.4 KernSmooth_2.23-17
[70] utf8_1.1.4 rmarkdown_2.6 jpeg_0.1-8.1
[73] isoband_0.2.3 readxl_1.3.1 data.table_1.13.6
[76] git2r_0.27.1 reprex_0.3.0 digest_0.6.27
[79] classInt_0.4-3 webshot_0.5.2 httpuv_1.5.4
[82] munsell_0.5.0 viridisLite_0.3.0