Implications of the Two-Component Dark Energy Model for Hubble Tension
Abstract
Dark energy plays a crucial role in the evolution of cosmic expansion. In most studies, dark energy is considered a single dynamic component. In fact, multi-component dark energy models may theoretically explain the accelerated expansion of the universe as well. In our previous research, we constructed the wnCDM (n=2, 3, 5) models and conducted numerical research, finding strong observational support when the value of n is small. Based on our results, both the 2 and Akaike information criterion (AIC) favor the w2CDM model more than the w0waCDM model. However, previous studies were limited to two equal-component dark energy models, failing to consider the component proportions as variables. Therefore, we will further explore the w2CDM model. To simplify the model, we fix w = -1 in one component and set the other component to wde2, varying the proportions of both components in the population. Under different wde2, we obtain the one-dimensional distribution of H0 with respect to fde2. Further fitting reveals the evolution of H0 under varying wde2 and fde2. We also perform the same operation on 2. To evaluate the error of fitting, we introduce two indicators, R2adj and MAPE, to quantify the fitting ability of our models. We find that when wde2 is less than -1, H0 increases with the decrease of wde2 and the increase of fde2, effectively alleviating H0 tension. For 2, it still prefers the model, and the w2CDM model will decrease significantly when it approaches the model. The excellent performance of R2adj and MAPE further proves that our model has an outstanding fitting effect and extremely high reliability.
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