Upper Penticton Creek Experimental Watersheds
Description of Data Sets
2021-September-22
1 Version status
This data set is version 1.2; it supercedes all earlier versions. The main change in this version is the use of catchment boundaries derived from the 1-m Lidar DEM for all three catchments. In earlier versions, the catchment boundaries for 240 and 241 Creeks were derived from the Canadian DEM (CDEM). However, further comparison indicated that boundaries based on the Lidar DEM were closer to those based on field surveys for all three catchments.
An important note is that the current stream network layer, based on the Government of Canada CanVec layers, is notably incorrect near the southern boundary of the catchment for 242 Creek. A corrected network based on field surveys is available. This corrected network will be digitized and included in a future update to the repository.
There are further data sets to be added. One is hourly streamflow data, which are in the process of undergoing QA/QC by Water Survey of Canada. Others have not been included because they are still in the process of being written up for publication, including water quality data. These will be added to the data repository upon acceptance of manuscripts based on them.
2 Overview
This document provides descriptions of the data sets collected at the Upper Penticton Creek (UPC) Experimental Watersheds that have been stored in a zenodo repository.
In many cases, contributors provided their data sets in spreadsheets, many of which included metadata in header rows and embedded graphs. The first step in processing the spreadsheets was to create copies of the original spreadsheets, which were then edited. In a number of cases, the data sheets were then formatted to conform to a rectangular structure with variable names in the first row, in general accordance with principles outlined by Broman and Woo (2018).
To minimize the potential for errors associated with manual editing and copy/pasting, compilation of data from individual spreadsheets was accomplished as much as possible by reading data from spreadsheets using the read_xlsx() function from the readxl package in R (Wickham and Bryan 2019), followed by processing using functions from the tidyverse set of packages. In most cases, the final data set was stored as a comma-separated-value (csv) file, accompanied by a metadata file and/or data dictionary, following recommendations by Ellis and Leek (2018).
To facilitate searching through the files, file names begin with a prefix related to data type or source. For example, files associated with groundwater levels begin with gw_, while meteorological data sets begin with met_.
Notes
For spatial data sets, coordinates are provided either as longitude-latitude or as projected to UTM Zone 11 North.
One of the three streams is known as both Dennis Creek and 242 Creek. Here, we use the latter for consistency with the naming scheme for 240 and 241 creeks.
3 Spatial data
The names for all spatial data files begin with the prefix gs_ (for geospatial). The material below describes the data sets available in the repository.
All data processing was conducted via R scripts to ensure reproducibility. Spatial operations were conducted using functions in the raster and sf packages (R. J. Hijmans 2020; E. Pebesma 2018). Sink removal and catchment delineation were conducted by running SAGA GIS functions from within an R script via the RSAGA package (Brenning, Bangs, and Becker 2018).
3.1 File formats
Most of the spatial vector data were received as Esri shapefiles. These have been converted to file formats with open specifications that do not require multiple files per layer. All spatial vector data have been stored in the repository in the following formats:
- GeoJSON
- gml
- gpkg
- kml
When providing file names for the various layers, below, only the kml version is listed for brevity.
The kml files are in geographic (longlat) coordinates (EPSG code 4326). The other file types contain coordinates that have been projected to UTM 11 (EPSG code 32611).
At present, the only raster data are digital elevation models. These have been stored as GeoTIFF files, with the file extension .tif.
3.2 Digital elevation model with 25-m resolution
This DEM is based on the Canadian Digital Elevation Model (CDEM). The elevation data were accessed from Natural Resources Canada via the following link:
The data were downloaded at the highest resolution (0.75 arc-seconds), reprojected to UTM Zone 11 with a resolution of 25 m, and then cropped to the Water Survey of Canada catchment boundaries, with an additional 2 km buffer on all four sides.
The file name in the repository is gs_dem25.tif.
The DEM is presented as a contour map in Figure 3.1, along with catchment boundaries and weir locations for the gauging stations. These will be explained in more detail below.
Figure 3.1: Contour map based on the 25-m DEM from Natural Resources Canada, including catchment boundaries and locations of weirs
3.3 Lidar DEMs
Lidar digital elevation data were acquired during 11 flights between Jul. 24 to Sept. 16, 2016. The point density was 9 m-2, and the models were delivered as GeoTIFF files projected to BC Albers equal area projection with 1-m resolution in both easting and northing. The horizontal accuracy is 0.3 m (two standard deviations) and the vertical accuracy is 0.15 m.
The data were provided as 28 files for an area covering the catchments of 240 and 241 creeks, and 14 files covering the catchment of 242 Creek. The elevation models were read from the individual files, resampled to a common 1-m by 1-m grid, and merged to form two files, one for 240 and 241 creeks, and one for 242 Creek, for each of the bare earth and vegetation height images. The data were then projected to UTM 11, again with 1-m by 1-m resolution.
3.3.1 Bare earth
The bare earth DEMs are in the following files.
gs_be240.tif- covers catchments for 240 and 241 creeksgs_be242.tif- covers catchment for 242 Creek
Figures 3.2 and 3.3 show the Lidar DEMs as hillshade images with contours.
Figure 3.2: Hillshade map of 240 and 241 Creek catchments based on the 1-m-resolution LiDAR bare earth DEM
Figure 3.3: Hillshade map of 242 Creek catchment based on the 1-m-resolution LiDAR bare earth DEM
3.3.2 Vegetation height
The vegetation height data are in the following files.
gs_vh240.tif- covers catchments for 240 and 241 creeksgs_vh242.tif- covers catchment for 242 Creek
Notes
There are some negative values along the boundaries of the individual tiles that were merged for both files. Users of the data may wish to change these to NA or to estimate them from surrounding values using a focal filter.
There are some points with vegetation heights greater than 50 m in the 242 Creek catchment, which are not realistic; these are related to Lidar returns from a wind tower located in the catchment. Users of the data may wish to set these to NA or to replace them with estimates from surrounding data using a focal filter.
There are also some tree heights in excess of 35 m in 241 Creek catchment, which appear unrealistic for the species and ecological zone; the maximum measured tree height is 32 m.
The images are shown in Figures 3.4 and 3.5.
Figure 3.4: Lidar vegetation heights for an area covering the catchments of 240 and 241 Creeks
Figure 3.5: Lidar vegetation heights for an area covering the catchment of 242 Creek.
3.4 Vector data
3.4.1 Catchment boundaries and weir locations
Weir locations were extracted from Water Survey of Canada metadata. Catchment boundaries were originally generated from the CDEM elevation model and were compared to catchment boundaries based on field mapping. All boundaries differed notably from those generated by a field survey, particularly for 242 Creek, where the CDEM-based boundary was substantially smaller than the surveyed boundary.
Revised catchment boundaries for all three creeks were derived from the Lidar bare earth DEM. For both digital elevation models, sinks were removed by deepening the drainage network.
Weir coordinates are available in the file gs_weirs.kml.
Catchment boundaries are available in the file gs_catchments.kml.
Figure 3.6 shows the weir locations and catchments overlaid on contour lines.
Figure 3.6: Topographic map showing catchment boundaries and weir locations.
3.4.2 Streams and water bodies
Layers containing streams and water bodies were downloaded from the CanVec series generated by Natural Resources Canada. A description of the data sets can be found via
The data can be accessed via
Within CanVec, stream networks are contained in the layer named water_linear_flow_1.shp, while lakes, ponds and reservoirs are in the layer named waterbody_2.shp.
The data are available in the files named gs_streams.kml and gs_lakes.kml.
Figure 3.7 shows the stream and water body layers plotted over elevation contours. The large water body is Greyback Reservoir. Many of the stream segments included in the CanVec layer are ephemeral.
An important note is that the stream network near the southern boundary of 242 Creek’s catchment is notably incorrect. A corrected network based on field surveys is available. Once this corrected network is digitized, it will be included in a future update to the repository.
Figure 3.7: Stream network, lakes and reservoirs
3.4.3 Roads
The road network was manually digitized within Google Earth using an image dated July 26, 2020. All roads that entered the study catchments were digitized. Outside the study catchments, only the more major roads were digitized. The manual digitization results in a somewhat simplified representation of the road network. No attempt has been made to ensure the connecting segments meet at a common point.
The data are available in the file named gs_roads.kml.
Notes
This layer is suitable for generating maps, as in Figure 3.8. However, for analyses such as determining the effects of roads on hillslope flow paths, it may be necessary to edit and/or re-digitize the network at a higher resolution, and to ensure that road segments meet at common points.
Figure 3.8: Road network
3.4.4 Clearcut boundaries
The clearcut boundaries were digitized from Google Earth by Stefan Gronsdahl and R.D. Moore. The dates of harvest were assigned to each digitized polygon by visually correlating the polygons with those on a map showing the harvesting schedule.
In the digitizing process, care was taken to follow the clearcut boundaries within the catchment boundaries. However, the extent of the clearcut areas outside the catchment boundaries may not be accurate.
This layer is available in a file named gs_harvest.kml, and is illustrated in Figure 3.9.
Figure 3.9: Clearcut boundaries with date of harvest
3.4.5 Soil units
Mapped soil units are available in a file named gs_soilmap.kml. This data set is described in detail in section 8.1.
3.4.6 Monitoring sites
Locations for all monitoring sites are in all_sites.kml. Figure 3.10 shows a map with all of the sites. For sites that lie within a harvesting unit, the date of harvesting is included, as shown in Table 3.1.
## Reading layer `all_sites' from data source `C:\Research\UPC_papers\upc_data_paper\spatial_data\clean_data\all_sites.GeoJSON' using driver `GeoJSON'
## Simple feature collection with 56 features and 3 fields
## Geometry type: POINT
## Dimension: XY
## Bounding box: xmin: 324878 ymin: 5498463 xmax: 329239.5 ymax: 5505148
## Projected CRS: WGS 84 / UTM zone 11N
Figure 3.10: Locations of monitoring sites
| Site type | Site name | Harvest date |
|---|---|---|
| weir | 240 | NA |
| weir | 241 | Fall 1992 |
| weir | 242 | NA |
| met station | Cheng | NA |
| met station | P0 (Penticton) | NA |
| met station | Dennis | NA |
| met station | P1 | Fall 1992 |
| met station | P3 | NA |
| met station | P5 | NA |
| met station | PB | Winter 98/99 |
| met station | PC | NA |
| met station | PJ | Winter 02/03 |
| met station | PK | Winter 06/07 |
| snow course | UP1 | Fall 1992 |
| snow course | UP2 | NA |
| snow course | UP3 | NA |
| snow course | UP4 | NA |
| snow course | UP5 | NA |
| snow course | UP7 | NA |
| snow course | UP9 | Winter 98/99 |
| snow course | UP10 | NA |
| snow course | UP11 | Winter 98/99 |
| snow course | UP12 | NA |
| snow course | UP13 | Winter 02/03 |
| canopy water balance | P6 | 1999 & 2000 |
| canopy water balance | P7 | NA |
| canopy water balance | PG | Winter 06/07 |
| canopy water balance | Site_D | Winter 95/96 |
| soil moisture | P7 | NA |
| soil moisture | P1 | Fall 1992 |
| soil moisture | A | Winter 06/07 |
| soil moisture | A | Winter 02/03 |
| soil moisture | B | Winter 02/03 |
| soil moisture | B | Winter 02/03 |
| soil moisture | C | Winter 06/07 |
| soil moisture | C | Winter 02/03 |
| soil moisture | D | Winter 95/96 |
| soil moisture | E | Fall 1992 |
| soil piezometer | P1_21154 | Winter 02/03 |
| soil piezometer | P2_21153 | Winter 02/03 |
| soil piezometer | P3_21152 | Winter 02/03 |
| soil piezometer | P4_32001 | Winter 02/03 |
| soil piezometer | P5_23387 | Winter 98/99 |
| soil piezometer | P6_21155 | Winter 98/99 |
| soil piezometer | P7_23391 | Fall 1992 |
| soil piezometer | P8_23388 | Fall 1992 |
| soil piezometer | P9_23392 | Winter 02/03 |
| soil piezometer | P10_23390 | NA |
| soil piezometer | P11_23389 | NA |
| soil piezometer | P12_33006 | NA |
| soil piezometer | P13_20073 | Winter 02/03 |
| soil piezometer | P14_33009 | NA |
| soil piezometer | P15_33000 | NA |
| groundwater well | W1 | Winter 98/99 |
| groundwater well | W2 | Winter 98/99 |
| groundwater well | W3 | Winter 02/03 |
Further details regarding the monitoring sites is provided below.
4 Streamflow data
4.1 Data collection
Streamflow is monitored by Water Survey of Canada (WSC) at weirs installed on 240, 241 and 242 creeks. Detailed information on procedures and protocols followed by WSC can be found in the following documents:
Hydrometric manual : data computations : stage-discharge model development and maintenance / authors: F. Rainville, D. Hutchinson, A. Stead, D. Moncur, D. Elliott. - Catalogue - Federal Science Libraries Network (scitech.gc.ca) https://cat.fsl-bsf.scitech.gc.ca/record=b4095734~S1
Hydrometric field manual : measurement of stage / author: Stephanie Moore. - Catalogue - Federal Science Libraries Network (scitech.gc.ca) https://cat.fsl-bsf.scitech.gc.ca/record=b4095742~S1
Hydrometric field manual : levelling / authors: Stephanie Moore, François Rainville, James Wilcox. - Catalogue - Federal Science Libraries Network (scitech.gc.ca) https://cat.fsl-bsf.scitech.gc.ca/record=b4095730~S1
Hydrometric field manual : measurement of streamflow https://publications.gc.ca/collections/collection_2021/eccc/en37/En37-525-1981-eng.pdf
In Figure 4.1, the weir locations are indicated by inverted blue triangles and the blue lines indicate the drainage divides. The grey-filled polygons indicate clearcuts. Photographs of the weirs are provided in Appendix A.
Figure 4.1: Locations of Water Survey of Canada weirs
Records begin in 1984 for 240 and 241 creeks and in 1985 for 242 Creek. Table 4.1 summarizes key metadata as recorded in the WSC HYDAT data base.
| Station no. | Station name | Longitude (\(^\circ\)) | Latitude (\(^\circ\)) | Drainage area (km\(^2\)) |
|---|---|---|---|---|
| 08NM240 | TWO FORTY CREEK NEAR PENTICTON | -119.4000 | 49.65089 | 4.94 |
| 08NM241 | TWO FORTY-ONE CREEK NEAR PENTICTON | -119.3939 | 49.65004 | 4.50 |
| 08NM242 | DENNIS CREEK NEAR 1780 METRE CONTOUR | -119.3812 | 49.62414 | 3.73 |
All three weirs have rectangular 4-foot-wide cross-sections to accommodate high flows during the snowmelt freshet, and V-notch plates are installed following the freshet to provide greater resolution for the lower flows in late summer and autumn. Tables 4.2 and 4.3 provide details on the instruments used to record stage.
| Instrument type | Make | Model | Accuracy |
|---|---|---|---|
| float-driven chart recorder | Stevens | A-71 or A-35 | ± 2 mm |
| pressure transducer | Tavis | DISI1200 | 0.1% full scale |
| Station | Start | End | Instrumentation | Time resolution | Real time |
|---|---|---|---|---|---|
| 08NM240 | 1/1/1983 | 7/6/2010 | A-35 chart recorder with float | 5 min | FALSE |
| 08NM240 | 7/6/2010 | 3/23/2016 | VEDAS II data logger with TAVIS DISI1210 transducer | 15 min with 24 hour max/min instantaneous readings | FALSE |
| 08NM240 | 3/23/2016 | 9/20/2018 | FTS H2 GOES data logger with TAVIS DISI1210 transducer | 5 min | TRUE |
| 08NM240 | 9/20/2018 | Present | FTS H2 GOES data logger with OTT PLS transducer | 5 min | TRUE |
| 08NM241 | 1/1/1983 | 10/14/2009 | A-35 chart recorder with float | 5 min | FALSE |
| 08NM241 | 10/15/2009 | 8/30/2016 | VEDAS II data logger with GOES with TAVIS DISI1210 transducer | 15 min with 24 hour max/min instantaneous readings | TRUE |
| 08NM241 | 8/30/2016 | 9/20/2018 | FTS H2 GOES data logger with TAVIS DISI1210 transducer | 5 min | TRUE |
| 08NM241 | 9/20/2018 | Present | FTS H2 GOES data logger with OTT PLS transducer | 5 min | TRUE |
| 08NM242 | 1/1/1985 | 5/18/2010 | A-71 chart recorder with float | 5 min | FALSE |
| 08NM242 | 5/18/2010 | 3/23/2016 | VEDAS II data logger with TAVIS DISI1210 transducer | 15 min with 24 hour max/min instantaneous readings | FALSE |
| 08NM242 | 3/23/2016 | 6/6/2019 | FTS H2 GOES data logger with TAVIS DISI1210 transducer | 5 min | TRUE |
| 08NM242 | 6/6/2019 | Present | FTS H2 GOES data logger with OTT PLS transducer | 5 min | TRUE |
4.2 Data access
Because daily mean discharge values are available from the HYDAT archive, either by manual download or programmatically via the tidyhydat package in R, those data are not included in the repository.
Hourly discharge data are not available from the HYDAT archive. However, sub-daily discharge data are being generated for the Upper Penticton Creek catchments via special arrangement with WSC. These data are still undergoing QA/QC, and will be added upon completion of those procedures.
All stations provide real-time data records via telemetry, which can be accessed via the following link:
These data are provisional and subject to revision. There is typically a lag of a year or longer before final, approved data are available.
Final approved data can be retrieved manually via the following link:
They can also be accessed programmatically using functions in the tidyhydat package in the R language (Albers 2017). The following code chunk extracts data for the period of record and generates a “tidy” data set stored in a csv file. By default, the records are sorted by date; the dplyr::arrange() function is applied below to sort the records by station.
## Not run:
upc_stns <- paste0("08NM", 240:242)
upc_data <- hy_daily_flows(upc_stns) %>%
dplyr::filter(Parameter == "Flow") %>%
dplyr::arrange(STATION_NUMBER)
# save data file
write.csv(upc_data, here::here("wsc_data", "clean_data", "wsc_dailyflows.csv"),
row.names = FALSE)
## End (not run)The first six rows of the data frame are printed below to illustrate the structure.
## STATION_NUMBER Date Parameter Value Symbol
## 1 08NM240 1983-11-01 Flow 0.019 A
## 2 08NM240 1983-11-02 Flow 0.024 <NA>
## 3 08NM240 1983-11-03 Flow 0.030 <NA>
## 4 08NM240 1983-11-04 Flow 0.033 <NA>
## 5 08NM240 1983-11-05 Flow 0.027 <NA>
## 6 08NM240 1983-11-06 Flow 0.024 <NA>In each record, Value provides the mean daily discharge in m3 s-1, and Symbol is a data flag that takes the values as shown in Table 4.4.
| Code | Meaning | Explanation |
|---|---|---|
| E | Estimate | The symbol E indicates that there were no measured data available for the day or missing period, and the water level or streamflow value was estimated by an indirect method such as interpolation, extrapolation, comparison with other streams or by correlation with meteorological data. |
| A | Partial Day | The symbol A indicates that the daily mean value of water level or streamflow was estimated despite gaps of more than 120 minutes in the data string or missing data not significant enough to warrant the use of the E symbol. |
| B | Ice conditions | The symbol B indicates that the streamflow value was estimated with consideration for the presence of ice in the stream. Ice conditions alter the open water relationship between water levels and streamflow. |
| D | Dry | The symbol D indicates that the stream or lake is `‘dry’ or that there is no water at the gauge. This symbol is used for water level data only. |
| R | Revised | The symbol R indicates that a revision, correction or addition has been made to the historical discharge database after January 1, 1989. |
See the following link for further information about data published by WSC:
5 Meteorological data
5.1 Citation
To provide credit to the researchers who acquired and processed the data, please cite R. Winkler, Spittlehouse, and Boon (2017) in any work that uses these data sets, in addition to citing this repository.
5.2 Station descriptions
Temperature and precipitation measurements with thermographs and Belfort precipitation gauges began in late 1983 at three clearcut locations located near the study catchments (Cheng, Dennis and Penticton). The station named Penticton is also called P0 to avoid confusion with similarly named regional weather stations operated by Environment and Climate Change Canada. Figure 5.1 shows station locations. Photographs of the weather stations are provided in Appendix B.
Figure 5.1: Locations of meterological stations within and near Upper Penticton Creek Experimental Watersheds
Since August 1991, multiple long-term weather stations used data loggers to record the following variables:
- rainfall
- air temperature and relative humidity
- surface and soil temperature
- incident and reflected solar radiation
- wind speed and direction
- snow depth and temperature
Table 5.1 provides an overview of station locations and characteristics. Where the end date is given as NA, the station is currently active, as of 2021-September-22.
| Station | Latitude | Longitude | Start date | End date | Output interval | Location | Comments |
|---|---|---|---|---|---|---|---|
| Cheng | 49.61333 | 119.4243 | 1983-10-01 | 1991-02-28 | Daily | 1 km south of Greyback Reservoir in small clearcut | |
| P0 | 49.64361 | 119.3654 | 1983-10-01 | 1991-02-26 | Daily | North side of Greyback Mt. | Initially called Penticton |
| Dennis | 49.62548 | 119.3911 | 1983-10-01 | 1991-01-28 | Daily | In young pine plantation, west of Dennis Creek Watershed | Renamed P3 when change to data logger |
| P1 | 49.65167 | 119.3987 | 1993-11-08 | NA | Daily, Hourly data (starting in 1997) | In opening in young pine, southern end of 240 Creek watershed, near trailer | Reflected radiation, snow depth and temperature from P4, Oct 1996 -Aug 2008 |
| P3 | 49.62548 | 119.3911 | 1991-08-21 | 2009-08-18 | Daily | In young pine plantation, west of Dennis Creek Watershed | Initially called Dennis |
| P4 | 49.65167 | 119.3987 | 1996-10-09 | 2009-08-20 | Daily, Hourly data (starting in 1997) | Adjacent to P1 | Provided reflected radiation, snow depth and temperature for P1 record |
| P5 | 49.65806 | 119.4031 | 1996-10-09 | NA | Daily, Hourly data (starting in 1997) | Forest in 240 Creek watershed | |
| P6 | 49.62488 | 119.3764 | 1996-10-09 | 1999-08-30 | Daily, Hourly data (starting in 1997) | Dennis Forest, snow station and summer interception | Interception measurements. Only operated during snow free season |
| P7 | 49.65588 | 119.3999 | 1997-06-26 | 2008-10-16 | Daily, Hourly data (starting in 1997) | 240 Creek forest rainfall interception site | Interception measurements. Only operated during snow free season |
| P9 | 49.62500 | 119.3806 | 1997-10-16 | 1999-06-24 | Daily, Hourly data (starting in 1997) | Clearcut in Dennis Creek | |
| PB | 49.67312 | 119.3788 | 1999-07-22 | NA | Daily, Hourly data (starting in 1997) | Clearcut near the top of 241 Creek watershed | |
| PC | 49.67444 | 119.3769 | 1999-09-01 | NA | Daily, Hourly data (starting in 1997) | Forest near the top of 241 Creek watershed | |
| PG | 49.65917 | 119.3942 | 2004-05-10 | 2006-09-26 | Daily, Hourly data (starting in 1997) | Rainfall interception at TDR forest site A | Interception measurements. Only operated during snow free season |
| PJ | 49.65944 | 119.3928 | 2005-10-22 | NA | Daily, Hourly data (starting in 1997) | Weather station at TDR clearcut site A, road by 241 weir | |
| PK | 49.65465 | 119.3934 | 2017-09-20 | NA | Daily, Hourly data (starting in 1997) | Weather station on road by 241 weir | |
| PL | 49.66923 | 119.3782 | 2018-09-01 | NA | Hourly | Weather station above road close to PB/PC parking |
Table 5.2 below summarizes makes and models of equipment deployed at the weather stations.
| Variable | Maker | Model | Accuracy | Quality.Control |
|---|---|---|---|---|
| Solar radiation - incident | LiCor Inc. | LI200 pyranometer | ± 5% | Comparison with daily clear sky values |
| Solar radiation - reflected | Eppley | B&W pyranometer | ± 3 to 5% (hourly) | Manual review of data |
| Solar radiation - reflected | LiCor Inc. | LI200 pyranometer | ± 5% | Manual review of data |
| Air temperature | Vaisala | HMP35C, HMP45C | ± 0.2 °C | Recalibrated every 5 years |
| Air humidity | Vaisala | HMP35C, HMP45C | ± 2 % (0-90); ± 3 % (90-100) | Recalibrated every 5 years |
| Air temperature | Rotronic | HC-S3 | ± 0.2 °C | Recalibrated every 5 years |
| Air humidity | Rotronic | HC-S3 | ± 1.5 % | Recalibrated every 5 years |
| Rainfall | Sierra Misco | 2401 tipping bucket | ± 1.5% for 0 to 91 mm/hr | Calibration with burette |
| Precipitation | Four Seasons | Stand pipe gauge with Sensotec pressure transducer | ± 0.2 mm | Manual measurement of depth of liquid |
| Snow depth | Campbell Scientific | UDG01, SR50, SR50A | ± 1 cm or 0.4 % | Comparison between sites |
| Wind speed | MetOne | 014A | ± 0.11 m/s or 1.5 %; starting threshold 0.45 m/s | Serviced every 5 years |
| Wind speed | RM Young | Wind Monitor 01503-10 | ±0.3 m/s or 1 %; starting threshold 1 m/s | Serviced every 5 years |
| Wind direction | RM Young | Wind Monitor 01503-10 | ± 3° | Serviced every 5 years |
| Snow temperature | Omega thermocouple wire | Chromel-constantan | ± 0.1°C | Manual review of data |
| Soil temperature | Omega thermocouple wire | Chromel-constantan | ± 0.1°C | Manual review of data |
| Surface temperature | Apogee Instruments | SI-111 | ± 0.2 °C | Manual review of data |
| Net radiation | Kipp and Zonen | CNR1 allwave radiometer | ± 10% | Manual review of data |
Several weather stations were located as forest-clearcut pairs. Stations P5 and P1 were the forest and clearcut stations, respectively, at the low elevation, and PC and PB the forest and clearcut stations at the higher elevation.
A low elevation clearcut station (PJ) was established because of encroachment by regenerating trees around the P1 station. Station PK was recently installed to replace PJ as it becomes influenced by regrowth of trees around it, and PL is a potential replacement for PB.
P3 was a clearcut station adjacent to the 242 Creek watershed at the location of the earlier Dennis station. Other stations ran for 3- to 8-year periods for specific projects such as rainfall interception, soil moisture monitoring and detailed radiation balance measurements.
The daily temperature, precipitation and solar radiation data for UPC were extended back to 1970 using regressions with Environment and Climate Change Canada weather stations that overlapped with UPC measurements. Temperature, precipitation and sunshine hours were available from McCulloch (Climate ID 1124980, 49\(^\circ\) 48’ N, 119\(^\circ\) 12’ W, 1250 m, 1970-1996) about 20 km NE of UPC, and solar radiation from Summerland CDA (Climate ID 112780, 49\(^\circ\) 34’N, 119\(^\circ\) 39’ W, 454 m, 1970-2007), about 17 km SW of UPC. McCulloch was used to gap-fill missing temperature and precipitation data during 1984 to 1991. Sensor accuracy and maintenance procedures are described in Weiler et al. (2010).
The long term UPC station called P1 was designated as the reference station. A record of temperature, precipitation and solar radiation prior to its installation were obtained from the early stations (Cheng, Dennis and P0), P3 and the ECCC stations noted above. Overlapping station records were used to generate regression equations to estimate the missing values.
Encroachment of regenerating forest on P1 necessitated installation of another station (PJ) to represent clearcut temperature and wind speed. Regression equations were developed to adjust temperature, precipitation and wind speed at PJ to P1’s apparent clearcut state. This is the data set called met_dly_p1_reference.xlsx. There is no adjusted hourly data record for P1 in the archive. Daily temperature and precipitation data from Penticton A (Climate ID 1126146, 49 \(^\circ\) 27’47“N, 119 \(^\circ\) 36’08”W, 344 m), about 21 km SW of UPC, were used to check the homogeneity of the extended and measured UPC weather record.
5.3 Data files
5.3.1 Hourly data
Hourly data have been archived as as Excel spreadsheets containing all of each station’s record. The file name structure is met_hrly_px.xlsx, where px is the station name (e.g., p1 refers to station P1).
Each spreadsheet has the following worksheets:
Dataworksheet: Hourly data as measured and gap filled for P1, PB, PJ and PK.Metaworksheet: Measurements, explanation of gap filling and calculations
See the file named met_hrly_readme.txt in the repository for more information.
5.3.2 Daily data
5.3.2.1 met_dly_cdp.xlsx
This file contains daily data as Excel spreadsheets for the stations named Cheng, Dennis, Penticton (temperature and precipitation), McCulloch (temperature, precipitation and solar radiation), and Summerland (solar radiation). The latter two are Environment Canada.
The files contain all of each station’s record from for 1 October 1983 to 31 August 1991, with gap filling of temperature, precipitation and incident solar radiation.
The spreadsheet has the following worksheets:
Dataworksheet: Daily data measured and gap filled where necessary. Monthly pivot table.Monthlyworksheet: Monthly data from pivot tables in Data and calculation of monthly Hargreaves reference evaporation and climatic moisture deficit.
MGraphsworksheet: Graphs of monthly dataMetaworksheet: Site location, measurements, explanation of gap filling and calculations
5.3.2.2 met_dly_px.xlsx
Daily data have been archived as as Excel spreadsheets within files named met_hrly_px.xlsx, where px is the station name (e.g., p1 refers to station P1).
Each spreadsheet has the following worksheets:
- Data worksheet: Daily data gap measured and gap filled where necessary. Monthly and annual pivot tables.
Monthlyworksheet: Monthly data from pivot table in Data and calculation of monthly Hargreaves reference evaporation and climatic moisture deficit.
MGraphsworksheet: Graphs of monthly dataAGraphsworksheet: Graphs of annual dataMetaworksheet: Measurements, explanation of gap filling and calculations
See the file named met_dly_readme.txt in the repository for more information.
6 Snow survey data
6.1 Citation
To provide credit to the investigators who collected the data sets, studies that involve the use of the snow survey data should provide a citation to R. Winkler et al. (2015), in addition to citing the data repository.
6.2 Data collection
6.2.1 Snow survey methods
Snow depths and water equivalents are measured using a standard Federal snow tube, both recorded to the nearest 1 cm. Standard Federal samplers overestimate SWE and density by 10% (Goodison et al., 1987). Recorded values have not been adjusted for this bias.
The snow surveys were initiated as part of Rita Winkler’s PhD research (R. D. Winkler 2001). From 1995 to 1997, snow was sampled at 64 stations, spaced in a 15-m by 15-m grid, at five locations in and near the UPC experimental watersheds. From 1998 to 2019, the number of stations at each location was reduced to 32, and stations at new survey sites were located on a 10-m by 10-m grid. Snow surveys are completed, within a 1-m radius of each station marker, in mid-March, on or near April 1st, and every two weeks until the end of snowmelt.
Each snow survey station is marked by a flagged bamboo pole attached to rebar secured in the ground. Snow samples are collected vertically through the snowpack to the ground using a standard Federal snow tube and weighed with a calibrated spring balance from which water equivalent, in cm, is read directly. Since 1998, some snow courses have been removed, relocated, or added as project specific objectives and forest cover have changed over time. The low and high elevation clearcut:forest pairs provide the longest continuous records at UPC.
6.2.2 Stand inventory measurements and calculations
Forest inventories were completed at each snow survey station in 1996 and 2015. Each snow survey station marker indicated the centre of a 3.99-m-radius plot (0.005 ha) within which all trees \(\geq\) 1 m tall were measured. the following attributes were recorded for each tree in the plot:
- live tree species
- tree condition (live or snag)
- diameter outside bark at breast height (1.3 m above ground)
- height
- height to live crown
- crown radius
The total number of stems were tallied and crown closure measured for each plot. Tree density (stems per hectare), stand basal area, crown length, crown ratio and crown volume were then calculated. Tree species mix reflects general tree form and distribution, stem descriptors represent stand structure, density, and stage of development, and the canopy variables represent the depth, volume, and extent of foliage in the stand.
Tree height (m) of the mature stands was measured using a clinometer and 30-m tape. Heights of the juvenile trees were measured using a height pole. Tree dbh (cm) was measured with a diameter tape. Basal area per tree (m2) was calculated from the dbh assuming trees were circular in cross-section. Crown length (m) was measured using a clinometer in the same way as tree height. Crown length (Lc) (m) was assumed to extend from the top of the tree to the base of the live crown, taken as the lowest whorl of branches with green foliage. Crown ratio (m/m) was calculated as crown length divided by total tree height. Crown radius (m) was measured from the stem to the projected outermost margin of the crown in the four cardinal directions. Crown area (Ac) (m2) was then estimated using the average crown radius and calculating the area of a circle with this radius. Crown volume (Vc) (m3) was estimated assuming that the crown shape approximated that of a cone (Mawson, Thomas, and DeGraaf 1976), and was calculated as:
\[\begin{equation} \tag{6.1} V_c = \frac{A_c L_c}{3} \end{equation}\]Crown length to crown base area ratio was calculated for each tree as an indicator of the amount of snow intercepting surface (Bunnell, McNay, and Shank 1985).
Crown closure over each plot was measured using a “moosehorn,” which is constructed of a short length of 7.5-cm-diameter plastic pipe. The pipe has an eye-piece at the bottom, an internal mirror and a grid of dots at the top. The moosehorn is held up to the eye and the number of dots falling on open spaces counted. The proportion of dots representing either openings, or crown closure, is then calculated. This instrument has been used by other researchers as a simple method of obtaining consistent estimates of crown closure where narrow angles of view are likely to be the most appropriate (Bunnell and Vales 1989). In this study, dots were counted while facing in each of the four main compass bearings around the snow survey station marker. The results were then averaged and crown closure were reported as a percent.
Individual tree measurements were totalled or averaged, depending on the variable, to obtain values for each plot. The characteristics summarized for each plot were: species mix, total stems, total stems by species, total number of live stems, total number of snags, average tree height, average diameter, total basal area of all species, average height to live crown, average crown length, average crown ratio, total crown base area, average height to base ratio, total crown surface area, total crown volume, and crown closure.
In addition to the measurements described above, canopy photos were taken under overcast skies using a Nikon 4500 camera with a FC-E8 fisheye lens converter. The camera was levelled with a bubble level on the lens cap and oriented so that the top of each image was north. Photography and analysis were completed by the same person. Threshold selection for binarizing the blue channel was automated using SideLook 1.1.01 (Nobis and Hunziker, 2005). Bitmap images were compared with the original photo, and contrast in the original image was adjusted in a few cases. Plant area index (needles, branches, and stems) and percent transmittance during snowmelt (April 1 to May 15) were determined using Gap Light Analyser 2.0 (Frazer, Canham & Lertzman., 1999).
6.2.3 Station locations and forest type
Table 6.1 below provides location coordinates and forest type for each snow course.
| Snow course | Latitude (\(^\circ\)) | Longitude (\(^\circ\)) | Forest cover |
|---|---|---|---|
| UP1 | 49.65508 | -119.3969 | CC/YF |
| UP2 | 49.65907 | -119.4024 | MF |
| UP3 | 49.62808 | -119.4072 | CC |
| UP4 | 49.63283 | -119.4052 | MF |
| UP5 | 49.62122 | -119.4072 | YF |
| UP7 | 49.65543 | -119.4004 | MF |
| UP9 | 49.67285 | -119.3794 | CC/YF |
| UP10 | 49.67398 | -119.3769 | MF |
| UP11 | 49.66348 | -119.3812 | CC |
| UP12 | 49.66478 | -119.3825 | MF |
| UP13 | 49.65962 | -119.3928 | CC/YF |
Figure 6.1 shows the locations of the snow courses. Photographs of select sites are provided in Appendix C.
Figure 6.1: Locations of snow courses
Five of the snow courses sample harvested sites. The dates of harvest are shown in Table 6.2.
| Snow course | Harvest date |
|---|---|
| UP1 | Fall 1992 |
| UP3 | Before 1994 |
| UP9 | Winter 98/99 |
| UP11 | Winter 98/99 |
| UP13 | Winter 02/03 |
6.3 Data files
There are four files associated with the snow survey data.
6.3.1 swe_snowcourse_coords.csv
This file contains the nominal latitudes and longitudes for each snow course, as well as the vegetation cover type. The first six lines are shown below.
## Snowcourse Lat Long Cover
## 1 UP1 49.65508 -119.3969 CC/YF
## 2 UP2 49.65907 -119.4024 MF
## 3 UP3 49.62808 -119.4072 CC
## 4 UP4 49.63283 -119.4052 MF
## 5 UP5 49.62122 -119.4072 YF
## 6 UP7 49.65543 -119.4004 MF6.3.2 swe_snowcourse_data.csv
This file contains the actual snow survey measurements at each station. The file is in long format, with each row providing the data for one station on one sampling date. The first six lines are provided below.
## Loc Site Station Cover Year DOY SWE Depth Density
## 1 240Cr UP1 1 CC 1995 4 25 80 31.3
## 2 240Cr UP1 2 CC 1995 4 25 89 28.1
## 3 240Cr UP1 3 CC 1995 4 28 92 30.4
## 4 240Cr UP1 4 CC 1995 4 22 81 27.2
## 5 240Cr UP1 5 CC 1995 4 30 95 31.6
## 6 240Cr UP1 6 CC 1995 4 32 92 34.8Figure 6.2 shows time-series of mean SWE by snow course to illustrate the temporal coverage and general range of variability among snow course sites. Measurements are joined by lines to assist visual interpretation of the temporal patterns.
Figure 6.2: Time series of mean SWE by snow course
6.3.3 swe_tree_data.csv and swe_tree_variables.csv
These files contain the tree measurements for each station. The data are contained in swe_tree_data.csv; the first six lines of the first 10 columns are shown below.
## snow_course station forest_cover leading_species bec_variant elev_m
## 1 UP1 1 CC ESSFdc1 1580
## 2 UP1 2 CC ESSFdc1 1580
## 3 UP1 3 CC ESSFdc1 1580
## 4 UP1 4 CC ESSFdc1 1580
## 5 UP1 5 CC ESSFdc1 1580
## 6 UP1 6 CC ESSFdc1 1580
## year_of_msmt cc_ocular cc_mh total_stems_ha
## 1 1995 0 0 0
## 2 1995 0 0 0
## 3 1995 0 0 0
## 4 1995 0 0 0
## 5 1995 0 0 0
## 6 1995 0 0 0The contents of swe_tree_variables.csv is shown in Table 6.3.
| Variable | Name |
|---|---|
| Snow course | snow_course |
| Station | station |
| Forest cover | forest_cover |
| Leading Species | leading_species |
| BEC variant | bec_variant |
| Elev (m) | elev_m |
| Year of tree meas | year_of_msmt |
| Crown closure ocular (%) | cc_ocular |
| Crown closure moosehorn (%) | cc_mh |
| Total stems per ha (live & dead all sizes) | total_stems_ha |
| Total live stems per ha | live_stems_ha |
| Live stems per ha dom/codom | live_stems_ha_com_codom |
| Live stems per ha interm/sup | live_stems_ha_interm_sup |
| Total dead stems per ha | dead_stems_ha |
| Dead stems per ha dom/codom | dead_stems_ha_dom_codom |
| Dead stems per ha interm/sup | dead_stems_ha_interm_sup |
| Total basal area per ha (live & dead) (m2) | basal_area_m2_ha |
| Basal area live per ha (m2) | live_basal_m2_ha |
| Average DBH (cm) including trees 1-1.3 m tall | dbh_cm_with_100_130_cm |
| Average DBH (cm) not including trees 1-1.3 m tall | dbh_cm_wo_100_130_cm |
| Average DBH (cm) dom/codoms | dbh_com_codom |
| Avg tree height (HT) (m) | tree_height_m |
| Avg ht dom/codoms (m) | tree_height_m_dom_codom |
| Avg ht interm/sup (m) | tree_height_m_interm_sup |
| Height to live crown (m) | height_live_crown_m |
| Crown length (CL) (m) | crown_length_m |
| Crown ratio (CL/HT) | crown_ratio |
7 Canopy water balance
7.1 Data collection
Throughfall and stemflow were measured at four sites as listed in Table 7.1. Site D is located in conjunction with one of the sites at which soil moisture is monitored. Photographs of the sites are provided in Appendix B.
| Site | Longitude (\(^\circ\)) | Latitude (\(^\circ\)) | Elevation (m) | Forest type | Period of record |
|---|---|---|---|---|---|
| P6 | -119.3764 | 49.62488 | 1810 | Engelmann spruce subalpine fir forest in 242 Watershed | 1997-1998 |
| P7 | -119.3999 | 49.65588 | 1637 | Lodgepole pine forest in 240 Watershed | 1997-2008 (no data 2002) |
| PG | -119.3940 | 49.65938 | 1668 | Lodgepole pine with some subalpine fir forest in 241 Watershed | 2004-2006 |
| Site_D | -119.3746 | 49.62570 | 1777 | 25 year-old (in 2004) lodgepole pine stand | 2004-2006 |
Site locations are shown Figure 7.1 as filled red circles.
Figure 7.1: Locations of monitoring sites for the canopy water balance
7.2 Measurements
Measurements started after snowmelt, usually late May, and terminated in September or early October.
Measurements at sites P6, P7 and PG were based on data recorded by data loggers, as described in Table 7.2.
| Measurement | Explanation |
|---|---|
| Rainfall | Tipping bucket (nominally 0.254 mm/tip) monitored by a data logger in a clearcut or opening within 200 m of the throughfall and stemflow site, output every 30 mins |
| Throughfall | Average of 5 troughs, each approximately 6 m long by 0.1 m wide, emptying into tipping buckets (nominally 32 mm/tip) monitored by data logger every 30 mins |
| Stemflow | Average of 5 collars on trees emptying into tipping buckets (nominally 32 mm /tip) monitored by data logger and adjusted for stem density |
| Interception loss | Computed as Rainfall - Throughfall - Stemflow |
The five throughfall troughs all drained into a tipping bucket gauge at a random location in the central part of the plot, from which the troughs radiate out at randomly generated azimuth angles. Stemflow trees were chosen somewhat randomly but with a goal of sampling the range of diameters within the plot. Figures 7.2 and 7.3 illustrate the instrumentation set-up for sites P6 and P7, respectively.
Figure 7.2: Map of P6 site showing instrumentation layout. The squares marked S1 to S5 indicate locations of trees for which stemflow was measured.
Figure 7.3: Map of P7 site showing instrumentation layout. The circles indicate the horizontal projections of the tree crowns.
Data at Site D were based on measurements of throughfall and stemflow as captured by storage gauges (Table 7.3), which were measured manually with a graduated cylinder. Measurements are totals for the period between the current and previous measurement dates.
| Measurement | Explanation |
|---|---|
| Rainfall | Tipping bucket (nominally 0.254 mm/tip) recorded by data logger at the adjacent P3 weather station |
| Throughfall | 28 plastic bottles with 100-mm-diameter funnels as orifices |
| Stemflow | Collars on 5 trees emptying into storage container |
| Interception loss | Computed as Rainfall - Throughfall - Stemflow |
At Site D, the throughfall gauges were arranged in a 4 by 7 regular grid with 5-m spacing. The grid points were generated using a random start point.
7.3 Data files
The data have been aggregated into total rainfall (mm), throughfall (mm) and stemflow (mm) for individual storms, where a storm has been defined by a period of steady rainfall separated by at least two hours with no rain.
There are two files associated with these data, described below.
7.3.1 il_site_info.csv
This file contains coordinates (longitude and latitude) and a brief description of each site, including the forest cover and years of record. The top six rows of the data frame are shown below to illustrate the file structure.
## site long lat elevation
## 1 P6 -119.3764 49.62488 1810
## 2 P7 -119.3999 49.65588 1637
## 3 PG -119.3940 49.65938 1668
## 4 Site_D -119.3746 49.62570 1777
## forest_type
## 1 Engelmann spruce subalpine fir forest in 242 Watershed
## 2 Lodgepole pine forest in 240 Watershed
## 3 Lodgepole pine with some subalpine fir forest in 241 Watershed
## 4 25 year-old (in 2004) lodgepole pine stand
## data_period
## 1 1997-1998
## 2 1997-2008 (no data 2002)
## 3 2004-2006
## 4 2004-20067.3.2 il_data.csv
This file contains the data, and is in long format. The first six rows are shown below to illustrate the file structure.
## site year storm start_dt end_dt drip_dt
## 1 p6 1997 3 1997-08-06 20:00:00 1997-08-06 20:30:00 1997-08-06 21:30:00
## 2 p6 1997 4 1997-08-07 23:30:00 1997-08-08 02:00:00 1997-08-08 03:30:00
## 3 p6 1997 5 1997-08-20 15:30:00 1997-08-20 16:30:00 1997-08-20 19:30:00
## 4 p6 1997 6 1997-08-20 20:30:00 1997-08-21 02:00:00 1997-08-21 18:00:00
## 5 p6 1997 7 1997-08-23 04:00:00 1997-08-23 08:30:00 1997-08-23 10:00:00
## 6 p6 1997 8 1997-08-23 15:30:00 1997-08-23 16:30:00 1997-08-23 17:00:00
## ppt tf sf il comment
## 1 0.80 0.16 0 0.64
## 2 4.01 1.78 0 2.23
## 3 2.94 2.13 0 0.81
## 4 4.81 3.44 0 1.37
## 5 4.00 2.47 0 1.53
## 6 0.80 0.39 0 0.41Table 7.4 provides explanations for the variables in the data set.
| Variable name | Explanation |
|---|---|
| storm | Number of storm in that year |
| start_dt | Start of rainfall |
| end_dt | End of rainfall |
| drip_dt | Time at which canopy drip ceased |
| ppt | Total open-site rainfall (mm) |
| tf | Total below-canopy throughfall (mm) |
| sf | Total stemflow (mm) |
| il | Interception loss (mm) |
| comment | Comment |
For sites P6, P7 and PG, for observations with the same start and end times for a storm, all the precipitation fell within one 30-minute time interval.
For Site D, for which aggregated values were measured between site visits, the value of start_dt was assigned as 12:00:00 on the date of the previous visit, and end_dt was assigned as 12:00:00 on the date of the current visit.
Under comment some observations have a value of “snow,” which indicates that some snow fell during the event, such that the values entail greater uncertainty than others for which all precipitation fell as rain. Figure 7.4 shows the relations between interception loss and gross precipitation. Linear regression fits are shown as blue lines.
Figure 7.4: Relations between interception and gross precipitation at each canopy water balance site.
8 Soil characteristics
8.1 Soil mapping
Dr. Graeme Hope, P.Ag. (Soil Scientist, BC Ministry of Forests, Lands, Natural Research Operations and Rural Development) conducted soil surveys that led to the soils map shown in Figure 8.1. Descriptions of the mapped units are provided in Table 8.1.
The soil unit polygons were originally provided as two shapefiles, one for 240 and 241 creeks, and one for 242 Creek. The files were transformed from BC Albers to UTM 11 and combined into a single simple features object, which included the soil unit descriptions as attributes for each polygon. They were then saved as spatial vector files for inclusion in the data repository.
The data are included in two files, listed below.
gs_soilmaps.kml- contains the polygons along with the soil unit descriptions for each polygonsoil_classes.csv- contains the soil unit descriptions
Note that, as mentioned in section 3.1, spatial data are stored in four formats, not just kml.
Figure 8.1: Soil units as mapped by Graeme Hope
| Class label | Soil class | Slope (%) | Depth (m) | Description |
|---|---|---|---|---|
| 1 | Bedrock | bedrock and isolated pockets of very shallow soil | ||
| 2 | Orthic Humo Ferric Podzol and Dystric Brunisol | 5 - 40 | 2 - 4 | morainal; gravelly, cobbly and stony; sandy loam over loamy sand; well and moderately well drained |
| 2d | Orthic Humo Ferric Podzol and Dystric Brunisol | 5 - 40 | > 4 | morainal; gravelly, cobbly and stony; sandy loam over loamy sand; well and moderately well drained |
| 2s | Orthic Humo Ferric Podzol and Dystric Brunisol | 5 - 40 | 1 - 2 | morainal; gravelly, cobbly and stony; sandy loam over loamy sand; well and moderately well drained |
| 2vs | Orthic Humo Ferric Podzol and Dystric Brunisol | 5 - 40 | 0.1 - 1 | morainal; gravelly, cobbly and stony; sandy loam over loamy sand; well and moderately well drained |
| 2w | Orthic Humo Ferric Podzol and Dystric Brunisol | 0 - 30 | 2 - 4 | imperfectly drained; gleyed |
| 3 | Orthic and Eluviated Dystric Brunisol | 0 - 40 | 2 - 4 | glaciofluvial; gravelly, cobbly and stony: sandy loam over loamy sand and sandy loam; rapidly drained |
| 3d | Orthic and Eluviated Dystric Brunisol | 0 - 40 | > 4 | glaciofluvial; gravelly, cobbly and stony: sandy loam over loamy sand and sandy loam; rapidly drained |
| 3w | Orthic and Eluviated Dystric Brunisol | 0 – 10 | 2 - 4 | moderately well and imperfectly drained; may be gleyed |
| 4 | Gleyed Regosol and Rego Gleysol | 0 - 5 | 2 - 4 | fluvial over glaciofluvial and morainal: gravelly, cobbly and stony; silt loam over sandy loam and loamy sand; imperfectly drained |
| 4d | Gleyed Regosol and Rego Gleysol | 0 - 5 | > 4 | fluvial over glaciofluvial and morainal: gravelly, cobbly and stony; silt loam over sandy loam and loamy sand; imperfectly drained |
| 4w | Gleysol and Mesisol | 0- 5 | 2 - 4 | intermixed fluvial and organic surface layers; some organic horizons; poorly drained |
8.2 Soil properties
Soil pits were dug at the sites that were monitored for the canopy water balance and soil moisture content. Soil water retention characteristics and associated physical properties were based on soil cores approximately 2 cm deep and 5 cm diameter that taken from soil pits and analysed in a laboratory.
There are three data sets, described below.
8.2.1 Soil bulk density
The data set is in a file named soil_bulk_density.csv. The first six rows are shown below.
## site pit sample_id depth_cm horizon fine whole porosity coarse sample_date
## 1 P7 1 F-1-1 3.5-0 LFH NA 0.27 80.6 0.0 summer 1997
## 2 P7 1 F-1-2 0-10 A + B 0.41 0.54 77.8 5.9 summer 1997
## 3 P7 1 F-1-3 10-20 B 0.74 0.90 63.3 8.3 summer 1997
## 4 P7 1 F-1-4 20- 35 B 0.96 1.31 46.3 26.6 summer 1997
## 5 P7 1 F-1-6 35-55 C 1.29 1.66 36.3 26.9 summer 1997
## 6 P7 1 F-1-8 55-75 C 1.37 1.87 28.2 70.0 summer 1997
## comments
## 1 <NA>
## 2 <NA>
## 3 <NA>
## 4 <NA>
## 5 <NA>
## 6 <NA>The variables in the data set are described in Table 8.2.
| Variable | Description |
|---|---|
| site | site name |
| pit | pit number (digit) - most sites have only one, but some have two |
| sample_id | identifier for specific soil sample |
| depth_cm | depth range for sample (cm) |
| horizon | horizon description |
| fine | bulk density (g/cm\(^{3}\)) of fine fraction |
| whole | bulk density (g/cm\(^{3}\)) of total soil volume |
| porosity | porosity as a % of total soil volume |
| coarse | coarse fraction as a % by mass |
| sample_date | date of sample collection |
| comments | any additional information |
8.2.2 Water retention curve characteristics
The data set is in a file named soil_wrc. The first six rows are shown below.
## site pit depth rep sample_id porosity vwc_5 vwc_10 vwc_33
## 1 P7 forest 1 1.5 <NA> F3-2 81.97207 45.37106 39.89719 23.81416
## 2 P7 forest 1 1.5 <NA> F3-3 68.60032 41.59014 34.76191 24.12454
## 3 P7 forest 1 8.5 <NA> F3-10 63.12970 35.77768 30.47310 20.90793
## 4 P7 forest 1 12.5 <NA> F3-4 66.67973 40.85653 33.71792 22.17765
## 5 P7 forest 1 18.5 <NA> F3-5 62.23584 41.08226 34.93120 21.83906
## 6 P7 forest 1 18.5 <NA> F3-6 59.03362 38.68391 31.65817 19.24320
## vwc_100 vwc_300 vwc_1500 particle_density bulk_density k_sat campbell_b
## 1 20.51291 12.217456 8.916204 1785.800 321.9427 54.57970 3.317332
## 2 19.69465 12.414967 9.057283 2303.118 723.1718 42.47832 3.627829
## 3 14.39008 9.734463 7.195038 2493.259 919.2719 12.55041 3.357778
## 4 15.06726 10.609154 7.956865 2460.821 819.9522 27.31632 3.294649
## 5 14.61580 10.129485 7.872218 2510.454 948.0520 20.67777 3.184438
## 6 13.00750 9.141930 6.856448 2503.628 1025.6456 26.12535 3.093873
## air_entry_value aeration_porosity_5 aeration_porosity_10 aws_cap sample_date
## 1 0.7544653 36.60101 42.07488 14.89796 summer 1997
## 2 0.8302286 27.01018 33.83841 15.06726 summer 1997
## 3 0.7701411 27.35203 32.65660 13.71290 summer 1997
## 4 0.9328609 25.82320 32.96180 14.22078 summer 1997
## 5 1.2958314 21.15358 27.30464 13.96684 summer 1997
## 6 1.2245999 20.34971 27.37546 12.38675 summer 1997
## lab comments
## 1 SoilCon Labs, Vancouver <NA>
## 2 SoilCon Labs, Vancouver <NA>
## 3 SoilCon Labs, Vancouver <NA>
## 4 SoilCon Labs, Vancouver <NA>
## 5 SoilCon Labs, Vancouver <NA>
## 6 SoilCon Labs, Vancouver <NA>The variables in the data set are described in Table 8.3.
| Variable | Description |
|---|---|
| site | site name |
| pit | pit number (digit) - most sites have only one, but some have two |
| depth | depth range for sample (cm) |
| rep | identifies replicate samples at a given depth |
| sample_id | identifier for specific soil sample at a given depth |
| porosity | porosity as a % of total soil volume |
| vwc_5 | volumetric water content (%) at a tension of 5 J/kg |
| vwc_10 | volumetric water content (%) at a tension of 10 J/kg |
| vwc_33 | volumetric water content (%) at a tension of 33 J/kg |
| vwc_100 | volumetric water content (%) at a tension of 100 J/kg |
| vwc_300 | volumetric water content (%) at a tension of 300 J/kg |
| vwc_1500 | volumetric water content (%) at a tension of 1500 J/kg |
| particle_density | particle density (g/m\(^3\)) |
| bulk_density | bulk density (g/cm\(^{3}\)) of the coarse fraction |
| k_sat | saturated hydraulic conductivity (cm/hr) |
| campbell_b | Campbell’s b parameter |
| air_entry_value | air entry tension (J/kg) |
| aeration_porosity_5 | aeration porosity (% of soil volume) at a tension of 5 J/kg |
| aeration_porosity_10 | aeration porosity (% of soil volume) at a tension of 10 J/kg |
| aws_cap | difference between field capacity and wilting point (% by volume) |
| sample_date | date sample was taken |
| lab | laboratory that performed the analysis |
| comments | any additional information |
8.2.3 Soil pit description
A soil profile is available from one pit dug at site P7, which was described by Graeme Hope on Oct. 2, 2002. The parent material was described as glacio-fluvial veneer over glacial till. The profile description is provided in Table 8.4.
| Horizon | Depth (cm) | Description |
|---|---|---|
| LF | 2 – 0 | loose, acerose, very few fine roots |
| Bm | 0 – 26 | sandy loam, 20% gravel, 5% cobble; friable, weak subangular blocky structure; abundant medium and plentiful fine and coarse roots |
| Bm2 | 26 – 38 | coarse sandy loam, 30% gravel and 5% cobble; loose, single grained, plentiful medium and fine roots |
| BC | 38 – 61 | loamy sand, 23% gravel and 2% cobble; loose, single grained, few fine and very fine roots |
| IIC | 61 – 71+ | loamy sand, 30% gravel and 5% cobble, slightly compact in situ, very few very fine roots; rooting to 61 cm |
Summary information from soil pits at sites P1, P7, and A to E is provided in the file soil_pit_description.csv. The first six lines are shown below to illustrate the file structure.
## site pit depth description roots texture coarse_fragments
## 1 P7 1 3.5-0 LFH <NA> <NA> NA
## 2 P7 1 0-2 A <NA> <NA> NA
## 3 P7 1 2-30 B Roots to 30 cm <NA> NA
## 4 P7 1 30-75 C <NA> <NA> NA
## 5 P7 1 75+ crushed rock at base <NA> <NA> NA
## 6 P7 2 0.5-0 LFH <NA> <NA> NA
## sample_date comments
## 1 summer 1997 <NA>
## 2 summer 1997 Ah + Ae
## 3 summer 1997 red/orange
## 4 summer 1997 yellow, large stones
## 5 summer 1997 <NA>
## 6 summer 1997 <NA>The variables in the data set are described in Table 8.5.
| Variable | Description |
|---|---|
| site | site name |
| pit | pit number (digit) - most sites have only one, but some have two |
| depth | depth range for sample (cm) |
| description | description of horizon/layer |
| roots | comment related to vertical extent of roots |
| texture | soil textural class |
| coarse_fragments | coarse fraction as % by mass |
| sample_date | date sample was taken |
| comments | any additional information |
9 Soil moisture
9.1 Citation
Anyone using the soil moisture data should cite Spittlehouse (2000) to provide credit to the contributor of the data set.
9.2 Methods
Manual measurements were made using a Moisturepoint MP917 time domain reflectometer. Data are reported as volumetric water content (m3 water per m3 soil). Probes consisted of a pair of 3-mm-diameter stainless steel rods 30 mm apart, which were connected to the MP917 through 0.04 m of two-conductor cable, a shorting diode and 3 m of RG-6 coaxial cable.
Measurements were made from the surface to depths of 150 mm, 300 mm and 500 mm. All sites have measurements for 0-500 mm and some also have the other depths.
At each site, measurements were made at 10 points along a transect, with sample points 5 to 20 m apart depending on site. At sites P1 and P7, measurements from 1997 to 2001 had a pair of measurement points about 2 m apart at each transect point, for a total of 20 points per transect.
9.3 Site characteristics
Site characteristics are summarized in Table 9.1. Their locations are shown in Figure 9.1.
| Site | Type | Start year | End year | Latitude (\(^\circ\)) | Longitude (\(^\circ\)) | Elevation (m) | Year | Stand age (yr) | Comments |
|---|---|---|---|---|---|---|---|---|---|
| P7 | Forest | 1997 | 2006 | 49.65588 | -119.3999 | 1637 | NA | NA | Lodepole pine forest - location of interception measurements - in 240 watershed |
| P1 | Regeneration | 1997 | 2006 | 49.65528 | -119.3977 | 1646 | 1997 | 5 | Regenerating stand (5 years old in 1997) with lodgepole pine and spruce saplings and grasses and shrubs adjacent to 240 watershed |
| A | Forest | 2003 | 2006 | 49.65938 | -119.3940 | 1668 | NA | NA | Lodgepole pine and some subalpine fir, location of PG interception measurements |
| A | Clearcut | 2003 | 2006 | 49.65944 | -119.3928 | 1675 | 2003 | 0 | Clearcut intially bare soil with few shrubs and planted lodgepole pine seedlings |
| B | Forest | 2003 | 2006 | 49.65274 | -119.3820 | 1675 | NA | NA | Lodgepole pine and some subalpine fir and Engelmann spruce in 241 watershed |
| B | Clearcut | 2003 | 2006 | 49.65309 | -119.3819 | 1675 | 2003 | 0 | Clearcut intially bare soil with few shrubs and planted lodgepole pine seedlings in 241 watershed |
| C | Forest | 2003 | 2006 | 49.66110 | -119.3761 | 1720 | NA | NA | Lodgepole pine and some subalpine fir and Engelmann spruce inj 241 watershed |
| C | Clearcut | 2003 | 2006 | 49.66125 | -119.3787 | 1703 | 2003 | 0 | Clearcut intially bare soil with few shrubs and planted lodgepole pine seedlings in 241 watershed |
| D | Forest | 2004 | 2006 | 49.62570 | -119.3746 | 1777 | 2004 | 25 | 25 year-old (in 2004) lodgepole pine stand |
| E | Regeneration | 2005 | 2006 | 49.65119 | -119.3730 | 1628 | 2005 | 10 | Regeneration 10 years old in 2005 with 2-m-tall lodgepole pine and some Engelmann spruce , south eastern edge of 241 Creek watershed. |
Figure 9.1: Locations of monitoring sites for soil moisture
9.4 Data
The data are stored in long format in a csv file. Each row contains the mean value for each combination of site, date and depth range, as seen below.
## year doy date sm site depth type
## 1 1997 176 1997-06-25 0.204 p1 150 regeneration
## 2 1997 189 1997-07-08 0.180 p1 150 regeneration
## 3 1997 196 1997-07-15 0.194 p1 150 regeneration
## 4 1997 202 1997-07-21 0.174 p1 150 regeneration
## 5 1997 212 1997-07-31 0.192 p1 150 regeneration
## 6 1997 216 1997-08-04 0.177 p1 150 regenerationFigure 9.2 illustrates the temporal variability.
Figure 9.2: Time series of measured soil moisture. The strip label indicates site, type and depth range.
9.5 Files
The data and metadata are stored in the repositories in files named sm_data.csv and sm_sites.csv, respectively.
10 Vegetation data
In addition to the LiDAR-derived vegetation height map (section 3.3.2) and the forest stand data measured in conjunction with the snow courses (section 6.3.3), vegetation surveys were conducted at the sites at which canopy water balance and soil moisture content were monitored. There are three data sets.
10.1 Forest characteristics
Basic forest characteristics are provided in the file veg_forest_characteristics.csv, which is shown below.
## site canopy_cover stem_density height
## 1 P1 25 NA 1-2
## 2 P6 45 1470 20-24
## 3 P7 40 720 20-24
## 4 Site A 51 3200 <NA>
## 5 Site B 37 4600 <NA>
## 6 Site C 63 4000 <NA>
## 7 Site D 80 1400 7-11
## 8 Site E NA NA 1-2
## species
## 1 Lodgepole pine with Engleman spruce and subalpine fir
## 2 Engleman spruce with subalpine fir and lodgepole pine
## 3 Lodgepole pine
## 4 Lodgepole pine and few subalpine fir
## 5 Lodgepole pine and few subalpine fir
## 6 Lodgepole pine and few subalpine fir
## 7 Lodgepole pine and few subalpine fir
## 8 Lodgepole pine with Engleman spruceTable 10.1 provides descriptions of the variables. See section 6.2.2 for a description of a moosehorn for measurement of canopy closure.
| Variable name | Description |
|---|---|
| site | site name |
| canopy_cover | canopy closure (%) as measured by a moosehorn |
| stem_density | tree density in stems per ha |
| height | tree height (m) |
| species | tree species |
10.2 Transmissivity and leaf-area index
Transmissivity and leaf-area index were determined from hemispherical photos take at 1 m height in 2004. The data are summarized in Table 10.2. Transmissivities for direct solar radiation were computed for March 21 and June 21, and are given in % of clear-sky radiation for each date.
| Site | Diffuse \(\tau\) | Direct \(\tau\) (Mar. 21) | Direct \(\tau\) (Jun. 21) | Leaf-area index | Number of photographs |
|---|---|---|---|---|---|
| P1 | 89.7 (6) | 81.1 (11.6) | 88.6 (9.9) | 0.5 (0.2) | 7 |
| P6 | NA | NA | NA | NA | NA |
| P7 | 29.2 (2.7) | 13.1 (5.6) | 25.8 (6.8) | 2.4 (0.3) | 18 |
| Site A forest | 23.5 (2.6) | 9.2 (3.3) | 21.7 (4.6) | 2.5 (0.2) | 13 |
| Site B forest | 25.7 (0.9) | 2.8 (1.6) | 19.9 (3.6) | 2.6 (0.1) | 5 |
| Site C forest | 18.8 (1.1) | 5.6 (6.9) | 15.0 (4.6) | 3.0 (0.1) | 7 |
| Site D | 31.0 (7.9) | 17.1 (14.1) | 28.8 (14.3) | 2.6 (0.3) | 16 |
| Site E | NA | NA | NA | NA | NA |
The data have been wrangled into a long format data file with separate columns for the mean, standard deviation and sample size for each variable and site. The file is named veg_tl_data.csv. The first 16 lines are shown below to illustrate the file structure.
## site var_name mean st_dev n
## 1 P1 trans_diff 89.7 6.0 7
## 2 P6 trans_diff NA NA NA
## 3 P7 trans_diff 29.2 2.7 18
## 4 Site A forest trans_diff 23.5 2.6 13
## 5 Site B forest trans_diff 25.7 0.9 5
## 6 Site C forest trans_diff 18.8 1.1 7
## 7 Site D trans_diff 31.0 7.9 16
## 8 Site E trans_diff NA NA NA
## 9 P1 trans_dir_mar21 81.1 11.6 7
## 10 P6 trans_dir_mar21 NA NA NA
## 11 P7 trans_dir_mar21 13.1 5.6 18
## 12 Site A forest trans_dir_mar21 9.2 3.3 13
## 13 Site B forest trans_dir_mar21 2.8 1.6 5
## 14 Site C forest trans_dir_mar21 5.6 6.9 7
## 15 Site D trans_dir_mar21 17.1 14.1 16
## 16 Site E trans_dir_mar21 NA NA NA10.3 Below-canopy cover
Below-canopy vegetation cover was measured in October 2006 along line transects at each monitoring site. The data are in the file named veg_bc_data.csv, shown below
## site cover_shgs cover_ml cover_ls lai
## 1 P1 Regen10 60 10 31 0.8
## 2 P6 Forest NA NA NA NA
## 3 P7 Forest 51 23 26 0.7
## 4 Site A Forest 61 9 29 0.8
## 5 Site B Forest 36 6 58 0.5
## 6 Site C Forest 42 8 50 0.5
## 7 Site A Clearcut 41 3 56 0.4
## 8 Site B Clearcut 32 4 63 0.4
## 9 Site C Clearcut 51 0 48 0.6
## 10 Site D Regen25 26 19 55 0.3
## 11 Site E Regen10 37 10 53 0.5Table 10.3 provides descriptions of the variables.
| Variable name | Description |
|---|---|
| site | site name |
| cover_shgs | % ground covered by shrubs, herbs, grasses, seedlings |
| cover_ml | % ground covered by mosses or lichen |
| cover_ls | % ground covered by litter or mineral soil |
| lai | leaf-area index of below-canopy cover |
11 Groundwater data
Water levels have been recorded in both shallow piezometers within the soil layer, as well as in deeper wells drilled into the bedrock. All wells and piezometers are within the 241 Creek catchment. Photographs of a piezometer and a well site are provided in Appendix D.
11.1 Citation
To provide credit to the investigators who collected the data sets, studies that involve the use of the soil piezometer data should provide a citation to Kuraś, Weiler, and Alila (2008) and Voeckler, Allen, and Alila (2014), in addition to citing the data repository.
Studies that involve the use of data from the drilled wells should cite Voeckler, Allen, and Alila (2014), in addition to citing the data repository.
11.2 Soil piezometer data
11.2.1 Data collection
Nine of the shallow piezometers were originally installed in 2005 as part of a study reported by Kuraś, Weiler, and Alila (2008), and six were added in 2007 (Voeckler, Allen, and Alila 2014). Piezometers extend to depths between 0.70 and 1.3 m below the top of the A horizon, and there is a 0.01-m gap between the bottom of the piezometer and the sensor.
As described by Kuraś (2006), piezometers were constructed from open-ended 32-mm-outside-diameter PVC pipe, with 6.35-mm-diameter holes drilled around the circumference up to a length of 30 cm from the bottom. This perforated portion of the pipe was covered with fine-meshed gauze to inhibit sediment influx. Piezometers were installed prior to the spring snowmelt. Piezometer tubes were installed in hand-augered holes that extended below the pre-melt-season water table. After emplacing the pipe in the hole, the space surrounding the tube was backfilled with fine gravel to a level 10-15 cm below the soil surface. A layer of bentonite clay was then added above the gravel to seal the hole from surface runoff.
Water levels were recorded using Odyssey Capacitance Water Level Probes (Data Flow Systems Pty Ltd, Christchurch, New Zealand), which have a vertical resolution of 0.8 mm resolution. Recording intervals varied from 10 to 30 minutes through the period of record, and were not synchronized among loggers.
Table 11.1 summarizes the coordinates and depths (relative to top of the A horizon) for the soil piezometers. Note that many location coordinates were taken from a handheld GPS. The elevations for those sites may not be sufficiently accurate for many purposes.
| Site | UTM Easting (m) | UTM Northing (m) | Elevation (m asl) | GPS type | Depth (m) |
|---|---|---|---|---|---|
| P1_21154 | 328376.2 | 5504172 | 1752.0 | handheld | 0.715 |
| P2_21153 | 328321.0 | 5504128 | 1721.4 | CDGPS | 0.850 |
| P3_21152 | 328355.0 | 5504152 | 1728.4 | CDGPS | 1.070 |
| P4_32001 | 328305.3 | 5504105 | 1731.0 | handheld | 1.060 |
| P5_23387 | 328017.9 | 5504408 | 1736.4 | handheld | 1.300 |
| P6_21155 | 328039.0 | 5504407 | 1740.0 | CDGPS | 0.710 |
| P7_23391 | 327254.0 | 5502821 | 1595.0 | CDGPS | 0.870 |
| P8_23388 | 327297.3 | 5502750 | 1590.7 | CDGPS | 0.900 |
| P9_23392 | 328021.8 | 5502695 | 1643.5 | CDGPS | 0.865 |
| P10_23390 | 327986.4 | 5502695 | 1638.6 | CDGPS | 0.800 |
| P11_23389 | 327950.9 | 5502703 | 1634.7 | CDGPS | 1.040 |
| P12_33006 | 327439.1 | 5502990 | 1619.0 | handheld | 0.960 |
| P13_20073 | 327410.6 | 5503033 | 1628.0 | handheld | 0.980 |
| P14_33009 | 326998.1 | 5503683 | 1678.0 | handheld | 0.900 |
| P15_33000 | 327017.8 | 5503699 | 1697.0 | handheld | 0.700 |
Figure 11.1 shows the locations of the soil piezometers as filled red circles.
Figure 11.1: Locations of soil piezometers
As can be seen in Figure 11.2, the data for p12_33006 are noisy. The cause is unknown. In addition, the data for p3_21152 have a gap from July 28, 2005, to October 10, 2006.
Figure 11.2: Time series of water levels in soil piezometers
11.2.2 Data files
The data were provided as separate spreadsheets by site. The final result of the editing process is a compiled long-format data file named gw_sp_all.csv, which contains the following columns:
site(format pi_x, where i is site number and x is Odyssey serial number)date_time(yyyy-mm-dd hh:MM:ss format)wl_bel_ahor(water level in m below the top of the A horizon)
Metadata are summarized in a file named wl_sp_metadata.csv. It includes the variables for each piezometer site as shown in Table 11.2.
| Variable name | Explanation |
|---|---|
| site | site number |
| utm_easting | Easting UTM 11N (m) |
| utm_northing | Northing UTM 11N (m) |
| ground_elevation_m | Elevation of top of humus layer (m) |
| gps_type | Type of GPS used to determine site coordinates |
| pvc_length_m | Length of piezometer pipe (m) |
| pvc_length_ab_ahor_m | Pipe length above top of A horizon (m) |
| pvc_length_bel_ahor_m | Pipe length below top of A horizon (m) |
| sensor_depth_bel_ahor_m | Sensor depth below top of A horizon (m) |
| humus_thickness_m | Humus thickness (m) |
| elev_ahor_m | Elevation at top of A horizon |
11.3 Drilled wells
11.3.1 Data collection
Three deep groundwater wells were drilled into the bedrock of the 241 Creek watershed in July 2007. Two adjacent wells (W1 and W2, 46 m and 30 m deep, respectively) were drilled approximately 3 m apart at high elevation. A third well (W3, 30 m deep) was drilled in the valley, downgradient from W1 and W2. The wells have shallow surface casings (~2.5 m for W1 and W2, and 6.4 m for W3), but are completed as open boreholes to their full depths. W3 is situated along a lineament; it intersects a fractured bedrock zone and has artesian flow during the spring freshet.
From July 2007 to August 2010, groundwater levels were monitored at various intervals (first daily, then twice daily, and eventually hourly). Seametrics PT2X vented pressure transducer loggers (measuring daily and twice daily) were initially deployed in July 2007. In August 2008, the data could not be downloaded in the field; therefore, the loggers were removed and sent for repair. It was thought exposure to extreme cold temperatures caused the loggers to malfunction. Ultimately, the data from W1 and W2 could be retrieved but not the data from W3. The data from W1 and W2 over the period July 2007 to August 2008 should be viewed with caution.
Onset HOBO loggers (non-vented) were installed and began logging on November 3, 2008. Note long time gap between the two types of loggers (August 2008 to November 2008).
Atmospheric pressure was measured with a single HOBO logger placed inside the upper well casing at W1. The same barologger data were used for barometric pressure compensation in all wells. All loggers were retrieved in August 2010. Since October 2013, W2 has been included in the BC Observation Well Network (#387 - Penticton Creek Watershed) and records groundwater levels hourly. The data can be accessed via:
Table 11.3 summarizes key characteristics. The well tag number is a unique well identifier in British Columbia.
| Well | UTM Easting (m) | UTM Northing (m) | Elevation - top of casing (m) | Drilled depth (m) | Sensor depth below top of casing (m) | Well tag number |
|---|---|---|---|---|---|---|
| W1 | 328254 | 5504627 | 1805.47 | 45.72 | 15 | WTN 94929 |
| W2 | 328259 | 5504625 | 1805.81 | 30.48 | 15 | WTN 94930 |
| W3 | 327379 | 5503001 | 1624.47 | 30.48 | 20 | WTN 94931 |
Figure 11.3 shows the locations of the wells as red filled circles. Note that the upper two wells are so close together that they cannot be distinguished.
Figure 11.3: Locations of drilled groundwater wells (filled red circles)
11.3.2 Data files
The water level data are contained in three spreadsheet files:
gw_well_1.xlsxgw_well_2.xlsxgw_well_3.xlsx
Each spreadsheet contains two sheets, one containing time-series data and the other containing metadata for the well. The metadata sheet gives the location of the well, the elevation of the top of casing (TOC), the casing height above ground surface, and the depth of the well. The TOC elevation, to which all measurements are referenced, was measured with a handheld GPS. The metadata also defines two logging intervals, specifying the type of logger used (P - Seametrics PT2X; H – Onset HOBO); sensor range; start and end dates; logging interval; and pressure units. The time-series data show the raw data and calculated values with equations linking to parameters in the metadata. Note that for W2, after 12 pm on September 24, 2009 to the July 11, 2020, only the depth to water and the elevation of the water table are included in the file.
Because W3 flowed artesian at times during freshet, the calculated water levels are above the top of the casing (negative numbers). Because the water levels were compensated using a barologger from a high elevation location, the absolute values of groundwater level are likely off by a bit.
11.3.3 Pumping test data
Four pumping tests were conducted:
- A step discharge test in W1
- A constant discharge test in W1, using W2 as an observation well.
- A step discharge test in W3
- A constant discharge test in W3, with no observation wells.
Each constant discharge test was followed by a recovery test, during which rising water levels were monitored.
Files labeled, e.g., gw_W1_Well_Tag_Number_94929.xlsx, summarize the pumping test data, graphs, analysis results and lithology information. The spreadsheet uses the BC Ministry of Environment and Climate Change Strategy template for pumping test data.
Several methods were used to analyze the data, including the Theis, Jacob (or Cooper-Jacob), Neuman, and Theis recovery methods. W3 was also analyzed with a method specific to linear flow (Ramey & Gringarten). The analysis results include transmissivity, storativity (and/or specific yield) and hydraulic conductivity estimated with each method.
12 R packages used
The following R packages were used in the generation of this document: tidyhydat (Albers 2017), pander (Daróczi and Tsegelskyi 2018), bookdown (Xie 2020), metR (Campitelli 2021), raster (Robert J. Hijmans 2020), sf (Edzer Pebesma 2021), ggspatial (Dunnington 2021), knitr (Xie 2021), magrittr (Bache and Wickham 2020), lubridate (Spinu, Grolemund, and Wickham 2021), readxl (Wickham and Bryan 2019), ggplot2 (Wickham et al. 2020), dplyr (Wickham et al. 2021), tidyr (Wickham 2021) and here (Müller 2020).
References
Appendix A - Photographs of streams and weirs
Photographs in these appendices were contributed by several researchers, including Rita Winkler (appendices A and C), Dave Spittlehouse (appendix B) and Diana Allen (appendix D).
Figure A1: Gauging station at 240 Creek during the transition from a float and chart recorder (mounted on top of stilling well) to pressure transducer, data logger and telemetry system (in metal hut) 
Figure A2: Close-up photograph of the v-notch weir at 240 Creek installed mid-summer to monitor post-freshet low flows 
Figure A3: Photograph of 240 Creek during freshet 
Figure A4: Dr. Todd Redding making measurements in 240 Creek, 2016 
Figure A5: Gauging station at 241 Creek during the transition from a float and chart recorder (mounted on top of stilling well) to pressure transducer, data logger and telemetry system (in metal hut) 
Figure A6: Rectangular weir on 241 Creek post-freshet in 2016, prior to installation of the v-notch 
Figure A7: Weir on 241 Creek following break-up, 2013 
Figure A8: Looking upstream toward the weir on 241 Creek during a period of zero flow, summer 2017 
Figure A9: Rectangular weir on 242 Creek post-freshet, prior to installation of the v-notch
Appendix B - Photographs of meteorological sites
Figure B1: Station P0 in late May in the 1980s 
Figure B2: Station P1, August 2012 
Figure B3: Station P3, May 2008 
Figure B4: Station P4, March 2003 
Figure B5: Station P5, June 2016 
Figure B6: Station P5, March 2015 
Figure B7: Station P7, June 1998 
Figure B8: Station PB, April 2005 
Figure B9: Station PB, July 2012 
Figure B10: Station PB, May 2011 
Figure B11: Station PC, March 2015 
Figure B12: Station PC, September 2017 
Figure B13: Station PG, May 2005 