We demonstrate the experimental feasibility of probing the fully nonperturbative regime of quantum electrodynamics with a 100 GeV-class particle collider. By using tightly compressed and focused electron beams, beamstrahlung radiation losses can be mitigated, allowing the particles to experience extreme electromagnetic fields. Three-dimensional particle-in-cell simulations confirm the viability of this approach. The experimental forefront envisaged has the potential to establish a novel research field and to stimulate the development of a new theoretical methodology for this yet unexplored regime of strong-field quantum electrodynamics.The interaction of light and matter is governed by quantum electrodynamics (QED), which is the most successfully tested theory in physics. According to the present understanding of QED, the properties of matter change qualitatively in the presence of strong electromagnetic fields. The importance of strong-field quantum effects is determined by the Lorentz invariant parameter χ = E * /E cr [1, 2] (also called beamstrahlung parameter in the context of particle colliders), which compares the electromagnetic field in the electron/positron rest frame E * with the QED critical field E cr = m 2 c 3 /(e ) ≈ 1.32×10 18 V/m. Here, m and e are the electron/positron mass and charge, c is speed of light, and is reduced Planck constant, respectively. Whereas classical electrodynamics is valid if χ 1, quantum effects like the recoil of emitted photons (quantum radiation reaction) and the creation of matter from pure light become important in the regime χ 1. Eventually, the interaction between light and matter becomes fully nonperturbative if χ 1. The behavior of matter near QED critical field strengths (i.e., the regime χ ∼ 1) is important in astrophysics (e.g., gamma-ray bursts, pulsar magnetosphere, supernova explosions) [3][4][5], at the interaction point of future linear particle colliders [6][7][8][9][10][11][12][13], and in upcoming high energy density physics experiments, where laserplasma interactions will probe quantum effects [14]. Experimental investigations of strong-field QED have just approached χ 1, e.g., by combining highly energetic particles with intense optical laser fields. This experimental scheme, first realized in the SLAC E-144 experiment [15,16], has been recently revisited [17,18]. Notable alternatives are x-ray free electron lasers [19], highly charged ions [20], heavy-ion collisions [21], and strong crystalline fields [22]. The success of QED in the regime χ 1 is based on the smallness of the fine-structure *
