Add to ORKGWe generalize the Cottingham formula at finite (T\neq 0) temperature by using the imaginary time formalism. The Cottingham formula gives the theoretical framework to compute the electromagnetic mass differences of the hadrons using a dispersion relation approach. It can be also used in other contexts, such as non leptonic weak decays, and its generalization to finite temperature might be useful in evaluating thermal effects in these processes. As an application we compute the \pi^+-\pi^0 mass difference at T\neq 0; at small T we reproduce the behaviour found by other authors: \delta m^2(T)= \delta m^2(0)+\mathcal{O}(\alpha T^2), while for moderate T, near the deconfinement temperature, we observe deviations from this behaviour
We present a systematic examination of finite temperature effects in quantum electrodynamics at one ...
We present a systematic examination of finite temperature effects in quantum electrodynamics at one ...
In this work we study strongly interacting matter at finite temperature. We consider Quantum Chromod...
We investigate the charged-neutral difference in the pion self-energy at finite temperature T. Withi...
We compute low temperature corrections to the electromagnetic mass difference of pious in the chiral...
Using the Cottingham formula, we give an estimate of the electromagnetic mass splitting of pseudosca...
We use the Cottingham method to calculate the pion and kaon electromagnetic mass differences with as...
We use the Cottingham method to calculate the pion and kaon electromagnetic mass differences with as...
We present a systematic examination of finite temperature effects in quantum electrodynamics at one ...
The QED effective action at finite temperature and density is calculated to all orders in an externa...
We compute the one-loop dispersion relations at finite temperature for quarks, charged leptons and n...
This paper is devoted to the evaluation of the pionic scalar density at finite temperature and baryo...
The nucleon mass shift is calculated using chiral counting arguments and a virial expansion, without...
Bibliography: p. 89-92.The temperature corrections to the current algebra Gell-Mann, Oakes and Renne...
Radiative corrections to the decay rate of charged fermions caused by the presence of a thermal bath...
We present a systematic examination of finite temperature effects in quantum electrodynamics at one ...
We present a systematic examination of finite temperature effects in quantum electrodynamics at one ...
In this work we study strongly interacting matter at finite temperature. We consider Quantum Chromod...
We investigate the charged-neutral difference in the pion self-energy at finite temperature T. Withi...
We compute low temperature corrections to the electromagnetic mass difference of pious in the chiral...
Using the Cottingham formula, we give an estimate of the electromagnetic mass splitting of pseudosca...
We use the Cottingham method to calculate the pion and kaon electromagnetic mass differences with as...
We use the Cottingham method to calculate the pion and kaon electromagnetic mass differences with as...
We present a systematic examination of finite temperature effects in quantum electrodynamics at one ...
The QED effective action at finite temperature and density is calculated to all orders in an externa...
We compute the one-loop dispersion relations at finite temperature for quarks, charged leptons and n...
This paper is devoted to the evaluation of the pionic scalar density at finite temperature and baryo...
The nucleon mass shift is calculated using chiral counting arguments and a virial expansion, without...
Bibliography: p. 89-92.The temperature corrections to the current algebra Gell-Mann, Oakes and Renne...
Radiative corrections to the decay rate of charged fermions caused by the presence of a thermal bath...
We present a systematic examination of finite temperature effects in quantum electrodynamics at one ...
We present a systematic examination of finite temperature effects in quantum electrodynamics at one ...
In this work we study strongly interacting matter at finite temperature. We consider Quantum Chromod...