Regarding the latter, for example, the basic issue such as "the identity of optical excitation at room temperature" is still controversial, because there are contradicting evidences for two candidates, free carriers and excitons. [9,10] The key question is the stability of the exciton against thermal ionization of the constituents. The exciton binding energy ϕ X in 3D HPs such as MAPbX 3 (MA = CH 3 NH 3 , X = I, Br, Cl) ranges from 15 meV to 70 meV, [9,11,12] which is indeed comparable to room temperature (≈26 meV), and therefore, an exciton may or may not be stable. However, optical excitation is certainly excitonic at low temperatures, for example, 10 K (≈0.9 meV).Like a hydrogen molecule formed by binding of two hydrogen atoms, two excitons can bind to form an excitonic molecule, typically known as a biexciton. The numerical value for the biexciton binding energy ϕ XX can be roughly estimated by a theoretical model, which predicts its universal dependence on ϕ X and the effective mass ratio σ between the electron and the hole. [13][14][15] According to variational methods, [16,17] the predicted ϕ XX for MAPbBr 3 (ϕ X = 38 meV [9] and σ ≈ 1 [18] ) can range from 1.0 meV to 4.8 meV, which is sufficiently large to ensure the stability of the biexciton at nominal cryogenic temperatures. However, there is no single experimental evidence for their existence in the 3D HPs, which is quite surprising because biexcitons are well established in conventional semiconductors like Si and Ge with similar and even much smaller values of ϕ XX = 1.5 meV [19] and 0.3 meV, [20] respectively.Here, we demonstrate that biexcitons do exist in 3D MAPbBr 3 single crystals at low temperatures (T < 30 K). However, biexcitons are unstable at the crystal exposed to ambient, explaining their elusive nature when probing as-grown crystals with typical photoluminescence (PL) spectroscopy. Therefore, the freshcut pristine quality of the crystal should be established for the stable biexciton formation. The evidence of the biexcitonic phase is very clear from the rapidly growing PL peak having an inverted Boltzmann shape, reflecting the kinetic energy distribution of the biexcitons. [21,22] We show that a cold biexciton can be directly generated using giant resonant two-photon absorption (2PA) with polarization control aided by the nanoscale surface flatness of the crystal with fine-scale photoluminescence Halide perovskites (HPs) are fascinating materials whose optoelectronic properties are arguably excitonic. In the HP family, biexcitons are known to exist only in low dimensions where exciton-exciton binding is strongly enhanced by quantum and dielectric confinements. In this paper, however, it is shown that they indeed do exist in 3D bulk CH 3 NH 3 PbBr 3 (MAPbBr 3 ) single crystals if the pristine crystal quality is ensured for subtle binding of two excitons. The existence of biexcitons is clearly evidenced below 30 K with a binding energy of ≈3.9 ± 0.3 meV according to i) exciton-biexciton population dynamics, ii) giant resonant two-photon ex...
