Journal papers issued by now related to the thesis

1- Water Resources Management

Prediction of Water Level using Monthly Lagged Data in Lake Urmia, Iran (Link)

2- Theoretical and Applied Climatology

Structural characteristics of annual precipitation in Lake Urmia basin (Link)

3- European Water

Spatial analysis of large atmospheric oscillations and annual precipitation in lake Urmia basin (Link&PDF)

Abstract of the Thesis

Lake Urmia was the second largest permanent hyper-saline lake in the World and the biggest in Middle East. The alerting situation of the lake pushed the authority such that the United Nations declared it as the wetland of international importance and World’s biosphere reserve. In late 1990’s water level in the lake started to decline with a sharp trend such that a wasteland of salty desert was conceptualized for the lake’s future. Many researchers around the world tried to model, suggest or decode the fact behind the lake’s atrophy mostly accused by miss-management, dam construction, development of agricultural zones, climate change etc. as the main reason for the lake atrophy.

In this study, a lake water budget approach using hydro-meteorological variables; precipitation, evaporation, runoff and groundwater, was considered. For this aim, data from meteorological stations, stream-flow gauging stations and groundwater wells were gathered. Data were analyzed and a data inventory was obtained. The data inventory consists of 253 meteorological stations, 156 stream-flow gauging stations, 593 groundwater wells and 1 lake water level station all scattered over the Lake Urmia basin. Precipitation and evaporation were taken from meteorological stations. In this study, 7 meteorological stations, 18 stream-flow gauging stations and 9 groundwater wells were considered together with the lake water level station. The selected stations and groundwater wells are close to the lake and scatter around it. 

Data in the selected stations and groundwater wells were checked against any missing data periods. Most of the stations were found with missing data. Groundwater wells have particularly long period of time with no data. For getting a common period for the analysis, missing data were reconstructed by a frequency domain analysis using decomposition. With this method, each time series of each station and groundwater well were decomposed into its components; trend, cycle, seasonality and randomness. An additive decomposition method was chosen. Observed time series was divided into calibration and validation parts. The decomposition method was used to fit a model to the calibration time series and to validate it then on the validation time series. Once validated, the model was run to reconstruct the missing data. This procedure was applied on all time series of precipitation, evaporation, runoff and groundwater. The observed and reconstructed precipitation, evaporation, runoff and groundwater time series were used to calculate lake water level. The calculated lake water level was compared with the observed lake water level. They were found in a very good agreement. This has been considered as a further validation of the reconstructed missing data. 

Observed and reconstructed hydro-meteorological data were used together to develop models for forecasting lake water level. In the model, lake water depth was considered instead of lake water level. For this aim, two methods were combined. First, lake water depth was regressed on independent variables; precipitation, evaporation, runoff and groundwater. The second step is the development of stochastic model for each variable. Auto-regressive integrated moving average (ARIMA) models were used. A number of models were tested and finally the best models were determined based on performance criteria for each variable. The number of parameters was kept at minimum for the sake of parsimony. As the final step in the modeling, not hydro-meteorological variables (precipitation, evaporation, runoff and groundwater) but their selected stochastic models were inserted into the regression model developed at the very beginning step. This is defined as regressive-stochastic depth model.

Alternatively, difference in the lake water levels of two subsequent months was taken into account instead of the lake water depth when the regression model is developed in the first step. Because lake water depth can mask change in the lake water level as they have different orders of magnitudes.

From this study it is seen that Lake Urmia is under a serious atrophy problem that should be studied in a long-term interdisciplinary approach. Lake Urmia has a considerably well documented data although record periods without data may become problematic. The frequency domain analysis can be a tool to satisfactorily reconstruct the missing data in the hydro-meteorological time series. Lake water level models can be developed based on either lake water depth or the difference in the lake water level between subsequent months. Due to the order of magnitude difference between the depth and the depth difference, it is clear that depth models can mask the effect of each input variable; precipitation, evaporation, runoff and groundwater, on the lake water level. Therefore, depth difference models should be preferred for the sake of understanding the physical process in the lake water level precisely. Regressive-stochastic models were found successful in calculating the lake water level. In the proposed regressive-stochastic models, only previously observed hydro-meteorological data are needed. This is a good opportunity for one to be able to estimate the next month lake water level. This will help us decision makers to act in advance.

As a future suggestion, the lake and its watershed should be investigated through an interdisciplinary approach. As the change is a continuous process it is suggested that any model proposed should be revised every several years and/or after any major change happens in the basin.

Sum Up with the Thesis

Dear Friends.

I have already finished my thesis. Now days, just looking for publishing some related articles and apply for jobs. Thus, since now I would post some related issues about the publications, outcomes and news.
Hope you would enjoy it.
Regards

Groundwater time series

Hey guys

After being done with Runoff time series, it is inevitable challenge the groundwater time series. As I mentioned before (1, 2, 3), I think coastal aquifers have very significant affect on the lake itself. Their flux to the lake or even the salinity intrusion from lake to the aquifer are the consequences of this interaction.

Most of the researchers used to handle this interaction with Darcy's law (Darcy, 1856), while others try to control it by the chemical components that transfers between lake and aquifer. Such methods are useless for me cause I don't have any observation data on chemical components and/or hydraulic conductivity between lake and aquifers. Thus, I tried to solve it by simplifying the problem.

Figure 1 shows the potential elevation of the aquifer in comparison with lake water level. As a potential depth of influx/drainage it can be used as the potential depth which would affect the lake surface at most correlated wells near the shore line or from underneath.

Fig.1. Schematic of potential influx/outflow between lake and coastal aquifers

For this, in the first place an iso-correlation map between lake and coastal aquifer will be generated. In the next stage an iso-correlation map with different lag times (Cross-correlation) will be investigated also. Then, proper wells (i.e. most correlated ones) will be selected and iso-height maps of water level in aquifers will be recognized. Then the potential depth between lake and aquifer will be calculated by subtracting the Lake water level from wells' water level.

This values could be positive or negative which defines the availability of GW in flux/draining the lake, which would be very handy in my calculation. In addition, I will not loose site of depth while using a semi-water budget or mass balance equation while all variables have dimensions in length.

Please do not hesitate to share your point of view with me

Babak

Interaction of coastal aquifer and lake water level

Hi,

Tomorrow is my 3rd thesis report day. I am now finished with the presentation and I just started to do analysis on groundwater.

In the first place, I started with Pearson correlation coefficient. Result are very interesting, as I mentioned before, there is a strong evidence that groundwater and lake have strong relations. Accounting for a probable cross-correlation lag between lake and ground water, it sounds like interaction between these two are inevitable. AS you can see in Fig.1 Pearson correlation coefficient in West bank of the Lake is negative while positive correlations are observed in the East bank of the lake.

Fig.1. Iso-correlation map of the Lake Urmia, defining the negative correlation coefficient for the West (Left) and positive correlation for the East (Right) bank

This values some how make sense while, the incline of the terrain in the West bank is more rapid and sharp. Fig. 2 shows a schematic representation of geological features in the Lake Urmia. In the West bank of the lake, groundwater elevation changes in reverse order with the lake and decreases when the lake water level increase. On the other hand, in East bank, lake water level and ground water elevation changes in the same way. This could be an evidence to recognize that, salinity intrusion is more severe in the East bank of the lake (East Azerbaijan) while the West bank plays more active role in interaction.

Fig. 2. Schematic of lake Urmia and the possible interaction between lake and coastal aquifer

Please share your comments with me

Thankfully

Babak

Modified Diagram for Depth-Area-Volume of the Lake Urmia

Hi

I was trying to calculate lake Area and Volume time series for further studies, that I found out there are some gaps. It was about some higher values that were not included in the recorded data. So I decided to extrapolate diagrams and make a modified version of the diagram. You can see extrapolation curves and modified diagram for depth-area-volume of the lake bellow.

Fig. 1. Extrapolation curves for Area and Volume

Fig. 2. Modified diagram for depth-area-volume of the Lake Urmia

Thankfully

Babak

Data generation

Hi

Recently, I used to reconstruct some missing data in my runoff and lake water depth time series to fulfill the gaps in the records. For this, I used Frequency Domain Analysis (FDA) combined with Auto Regressive models to catch the remaining information (persistence) in the FDA residual.

• Firstly a primary set of data is considered with at least 100 month length in order to reproduce the main properties of the generated time series, moments of the distribution and time dependency.
• In the second stage, time series of data is transformed to Normal distribution and controlled for stationary. The transformation procedure for runoff time series is done with log-transformation, while lake water level time series is manipulated by means of Box-Cox transformation.
• Then, analysis of spikes in line spectrum (LS) of the model is calculated for catching the main periodicity in the sets. For instance LS of runoff in Simine River is shown in Fig.1.

Fig.1. LLS of Simine River

• Due to statistical inconsistency of spikes in line spectrum function, a Tukey window is used to transform it to power spectrum (PS) and use the statistically significant spikes in the PS (Fig. 2).

Fig. 2. PS of Simine River

• Then residual series of the selected Fourier series is calculated and controlled for being a white noise. If there was a remaining information in the procedure an AR model is used for manipulation. Later a normally distributed random series by mean zero and the same standard deviation with residual series is generated.
• Fig. 3. shows some Fourier series used in Analysis.

Fig. 3. Fourier series used in Analysis of Simine River

•  Then after, estimation time series is calculated using selected Fourier series plus random series and controlled for degree of accuracy in comparison with selected transformed time series.
• Flowingly, selected Fourier series with the most adequate properties is used in manipulations and filling up gaps between data but original data was not disturbed at all.
• At last, generated time series was tested for statistical properties compared to primary time series. Fig. 3 shows some Fourier series of Simine river.
• A competitive results of primary and generated tiem series is shown in Table 1 and Fig. 4. The goal is to catch more information and transfer it to the final time series.

Add caption

Table. 1. Statistics related to primary and generated time series (Fourier and combined Fourier and AR)

• Thus, for this case a combined Fourier and AR model is used for generating data. This issue is also used for other time series of runoff and lake water depth.

Thankfully yours

Babak

Diagram for Height-Area-Volume of the Lake

I recently got some good data about water level, area and volume of the lake. So I now introducing a new diagram named "Height-Area-Volume" for Lake Urmia.
I hope This will help!

Height-Area-Volume diagram of Lake Urmia

Breaking news :)

I have just finished with data generation and construction of rivers.
Take a look at the percentages that I calculated. Values are calculated by average daily in month!!!!
This results will definitely changes everything.

I am so excited!

Precipitation on LUB

Hi guys.

After a long time. I decided to share some stuff with you. Actually I am working on paper about the precipitation of the Lake Urmia Basin (LUB). The early investigations on maximum, minimum etc. properties of the basin shows a strong non-homogeneity. Once comparing with previous literature, other research makers is underlining the strong variation in climate across the LUB. Relying on this studies my own investigations is in complete agreement with the previous researchs. I will share the results as soon as the main paper is published on the journal.

What is more, for people whom live in  Urmia it is  recognizable to see the reducing pattern of precipitation. what is more, for those who travel across the border of the Turkey and Iran specially in the winter and autumn it is surprising that mountains which are  on the border of two country does not share the same hillside conditions. While Turkey side is full of snow and overflowing rivers the hillside which is associated inside the Iranian border does not have any snow cover at all. Considering this I decided to take a look at satellite imagery picture. Here is the result of a  the investigation from LANDSAT 8 which was obtained from USGS earth explorer site (http://earthexplorer.usgs.gov/).

These two images belongs to Feb 13. 2015 which indicates the role of  mountains on prevention of entrancement of  evaporation to the LUB. This subject is one of the pure subjects that is good for investigation but there is some limitations on investigations such phenomena (i.e. Political and International). What is more, in my new research I am studying the properties of rainfall in 53 meteorological stations which at least have 30 years of recorded data (There are stations with more than 40 year records) which the properties of them is exposed in Figure 1 bellow.

Figure 1. Box plot of the annual rainfall

I hope you enjoyed the new details which I shared with you after such a  long time. But I will try to write more posts.

Thankfully yours 

Babak Vaheddoost