Στην παρακάτω εργασία εξετάζεται η μεταβλητή ERF (Effective Radiative Forcing) που αφορά την μεταβολή του ισοζυγίου ακτινοβολίας της Γης σε σχέση με την αύξηση ή μείωση ενός ρύπου ή μιας ομάδας ρύπων με αποτέλεσμα να προκληθεί θέρμανση ή ψύξη. Οι εξεταζόμενοι ρύποι είναι το μεθάνιο που είναι ένας αέριος υδρογονάνθρακας, το σύνολο των αερίων του θερμοκηπίου που αποτελούν βασική ομάδα ρύπων για την θερμοκρασία του πλανήτη μιας και σε αυτούς οφείλεται το φαινόμενο του θερμοκηπίου, τους αλογονάνθρακες στους οποίους συμπεριλαμβάνονται οι πολυσυζητημένοι χλωροφθοράνθρακες, το υποξείδιο του αζώτου που παράγεται κατά κύριο λόγο στο έδαφος και το όζον που αποτελεί ευεργετικό ρύπο στην στρατόσφαιρα και βλαβερό στην τροπόσφαιρα. Τα δεδομένα προέρχονται από το κλιματικό μοντέλο UKESM1 του προγράμματος CMIP6 (Coupled Model Interpolation Project 6) . Η ανάλυση των δεδομένων για την εξαγωγή των αποτελεσμάτων γίνεται με τη χρήση της γλώσσας προγραμματισμού R στο RStudio ενώ μέσω αυτού παράγονται και χάρτες που δείχνουν την κατάσταση του ERF σε σχέση με κάθε ρύπο ή ομάδα ρύπων κάνοντας ξεκάθαρη την ύπαρξη θέρμανσης ή ψύξης. Τέλος, παρουσιάζεται και μία σύγκριση με άλλα μοντέλα και εργασίες. Όπως αποκαλύπτεται από τα αποτελέσματα και από τη σύγκριση υπάρχουν τιμές του ERF που συμφωνούν με άλλα μοντέλα και εργασίες αλλά και κάποιες που αποκλίνουν.

In the following project, the variable ERF (Effective Radiative Forcing) is examined. ERF is a variable which concerns the change in the Earth's radiation balance in relation to the increase or decrease of a pollutant or a group of pollutants, resulting in warming or cooling. The pollutants examined are methane which is a gaseous hydrocarbon, greenhouse gases which are a basic group of pollutants for the temperature of the planet since they are responsible for the greenhouse effect, halocarbons which include the much-discussed chlorofluorocarbons, nitrous oxide which is mainly produced in the soil and ozone which is a beneficial pollutant in the stratosphere and a harmful one in the troposphere. The data stem from the UKESM1 climatic model of the CMIP6 (Coupled Model Interpolation Project 6). The analysis of the data, to extract the results is done using the R programming language in RStudio, while through it maps are also produced that show the state of the ERF in relation to each pollutant or group of pollutants making clear the existence of heating or cooling. In the end a comparison with other models and projects is being presented. As it is revealed by the results and the comparison there are some ERF values that agree with other models and projects and some others that diverge.

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