GroMoPo Metadata for Biscayne Bay Saltwater Intrusion Model

Authors:

GroMoPo Daniel Kretschmer

Owners:

gromopo_admin

Type:

Resource

Storage:

The size of this resource is 1.7 KB

Created:

Feb 08, 2023 at 8:28 p.m.

Last updated:

Feb 08, 2023 at 8:28 p.m.

Citation:

See how to cite this resource

Sharing Status:	Public
Views:	666
Downloads:	211
+1 Votes:	Be the first one to this.
Comments:	No comments (yet)

Abstract

Experimental and numerical models can be used to investigate saltwater intrusion (SWI) in coastal aquifers. Sea level rise (SLR) and decline of freshwater heads due to climate change are the two key variables that may affect saltwater intrusion. This study aims to give a better understanding of the impact of increasing seawater levels and decreasing freshwater heads due to climate change and increasing abstraction rates due to overpopulation using experimental and numerical models on SWI. The experimental model was conducted using a flow tank and the SEAWAT code was used for the numerical simulation. Different scenarios were examined to assess the effect of seawater rise and landside groundwater level decline. The experimental and numerical studies were conducted on three scenarios: increasing seawater head by 25%, 50% and 75% from the difference between seawater and freshwater heads, decreasing freshwater head by 75%, 50% and 25% from the difference between seawater and freshwater heads, and a combination of these two scenarios. Good agreement was attained between experimental and numerical results. The results showed that increasing the seawater level and decreasing freshwater head increased saltwater intrusion, but the combination of these two scenarios had a severe effect on saltwater intrusion. The numerical model was then applied to a real case study, the Biscayne aquifer, Florida, USA. The results indicated that the Biscayne aquifer is highly vulnerable to SWI under the possible consequences of climate change. A 25 cm seawater rise and 28% reduction in the freshwater flux would cause a loss of 0.833 million m(3) of freshwater storage per each kilometer width of the Biscayne aquifer. This study provides a better understanding and a quantitative assessment for the impacts of changing water levels' boundaries on intrusion of seawater in coastal aquifers.

Subject Keywords

Coverage

Spatial

Coordinate System/Geographic Projection:

WGS 84 EPSG:4326

Coordinate Units:

Decimal degrees

Place/Area Name:

United States

North Latitude

25.6255°

East Longitude

-80.2936°

South Latitude

25.6005°

West Longitude

-80.3269°

Streets Terrain Satelite

Spatial Extent

Content

Learn more about the BagIt download

Select a file to see file type metadata.

Additional Metadata

Name	Value
DOI	10.3390/w14040631
Depth	33
Scale	Other
Layers	33
Purpose	Salt water intrusion
GroMoPo_ID	413
IsVerified	True
Model Code	SEAWAT
Model Link	https://doi.org/10.3390/w14040631
Model Time
Model Year	2022
Model Authors	Abd-Elhamid, HF; Abdel-Aal, GM; Fahmy, M; Sherif, M; Zelenakova, M; Abd-Elaty, I
Model Country	United States
Data Available	Report/paper only
Developer Email	hany_farhat2003@yahoo.com; drgamal_abdelaal@yahoo.com; maha.rashad55@yahoo.com; msherif@uaeu.ac.ae; martina.zelenakova@tuke.sk; eng_abdelaty2006@yahoo.com
Dominant Geology	Unsure
Developer Country	Egypt; Slovakia; U Arab Emirates
Publication Title	Experimental and Numerical Study to Investigate the Impact of Changing the Boundary Water Levels on Saltwater Intrusion in Coastal Aquifers
Original Developer	No
Additional Information
Integration or Coupling	Solute transport
Evaluation or Calibration	Unsure
Geologic Data Availability	No

How to Cite

GroMoPo, D. Kretschmer (2023). GroMoPo Metadata for Biscayne Bay Saltwater Intrusion Model, HydroShare, http://www.hydroshare.org/resource/ec1ade3a2d084478ade999293d105ef6

This resource is shared under the Creative Commons Attribution CC BY.

http://creativecommons.org/licenses/by/4.0/

Comments

There are currently no comments

	Name:
	Organization:
	Email:
	Address:
	Phone:
	Homepage:
	Author Identifiers: