When an ultrarelativistic electron beam collides with a sufficiently intense laser pulse, radiationreaction effects can strongly alter the beam dynamics. In the realm of classical electrodynamics, radiation reaction has a beneficial effect on the electron beam as it tends to reduce its energy spread. Here, we show that when quantum effects become important, radiation reaction induces the opposite effect, i.e., the electron beam spreads out after interacting with the laser pulse. We identify the physical origin of this opposite tendency in the intrinsic stochasticity of photon emission, which becomes substantial in the full quantum regime. Our numerical simulations indicated that the predicted effects of the stochasticity can be measured already with presently available lasers and electron accelerators.PACS numbers: 12.20. Ds, A deep understanding of the dynamics of electric charges driven by electromagnetic fields is one of the most fundamental problems in physics, as it has implications in different fields, including accelerator, radiation and high-energy physics. Apart from its impact on practical issues, as the construction of new experimental devices (e.g., quantum x-free electron lasers [1]), the investigation of the dynamics of electric charges (electrons, for definiteness) is also of pure theoretical interest, as it involves in general a coupled dynamics of the electrons and of their own electromagnetic field.In the realm of classical electrodynamics, radiationreaction (RR) effects stem from the back reaction on the electron dynamics of the electromagnetic field generated by the electron itself while being accelerated by a background electromagnetic field [2,3]. The LandauLifshitz (LL) equation has been recently identified as the classical equation of motion of an electron, with mass m and charge e < 0, which includes RR effects selfconsistently [2][3][4][5][6][7], although alternative models have been suggested [8,9]. The analytical solution of the LL equation in a plane-wave field [10] shows that if an electron impinges with initial four-momentum p µ 0 onto a planewave field (electric-field amplitude E 0 , central angular frequency ω 0 and propagating along the direction n), RR effects substantially affect the electron dynamics, if the parameter R c = αχ 0 ξ 0 is of the order of unity (see also [11]). Here, α = e 2 is the fine-structure constant, χ 0 = ((np 0 )/m)E 0 /E cr is the so-called quantum nonlinearity parameter, with n µ = (1, n) and E cr = m 2 /|e| = 1.3 × 10 16 V/cm , and ξ 0 = |e|E 0 /mω 0 is the classical nonlinearity or relativistic parameter (units with = c = 1 are used throughout). It is worth noting that, although χ 0 is much smaller than unity in the realm of classical electrodynamics [2], the parameter R c can be of the order of unity [4,10,11]. The parameter R c represents the average energy radiated by the electron in one laser period in units of the initial electron energy, and for an ultrarelativistic electron initially counterpropagating with respect to the laser field with en-, ...
