Introduction: In radiotherapy, the new techniques have some difficulties such as: beam dosimetry, geo- metric characterization and the use of small radiation fields(1). In some cases, the fields sizes are reduced due to the very small lesions, the simulations of the treat- ment in the planning have a very important role, there- fore, they must be provided with data referring to these small fields. Dosimetry becomes quite complex, as the precision becomes quite contestable, especially when small fields are being used in low density regions(2). Due to the absence of lateral electronic balance, de- termining the dose in the target volume in small field cases is quite difficult. Another problem for this type of dosimetry is the sharp dose gradient at the edges of the field. However, this fact requires that the choice of the radiation detector must be of a relevant size in the dosimetry of small fields, taking into account some parameters such as: high spatial resolution, density equivalent to water, linearity, reproducibility, regard- less of energy and rate of dose(3). Material and method: For this analysis LiF:Mg;Ti (3,15 mm in diameter, 0,9 mm in thickness) and ??LiF:Mg;Ti (1 mm x 1 mm) dosimeters produced by Harshaw were used. The irradiation system was the Varian Clinac 6 EX with photon energies of 6MV, with the collimator Multi-leaf Brainlab M3 belonging to the Hospital das Cl??nicas de S??o Paulo - HC. In addition, for measurements solid water plates (SW) of 30x30x1cm?? dimension were used. The studied field sizes were 9,8x9,8cm2, 5x5cm2, 4x4cm2, 3x3cm2, 2x2cm2, 1x1cm2 and 05x05 cm2. . Results: The dosimeters were selected with TL sensitivity between ??3%. The TL response presented non-significant variation. The dose response curves to photon beams of 6MV presented a linear behavior in the dose range studied (2Gy to 10Gy). Results obtained in simulated irradiations demonstrated the viability of using ??LiF:Mg;Ti as dosimeter to dose evaluation of small photon fields with relatively low uncertainties for this type of application. Table 1 presents the result of TL response of the dosimeters for the studied fields. Conclusions: The dosimetry of small fields is very complex and difficult due to the dimensions of the fields, however the LiF:Mg;Ti and ??LiF dosimeters demonstrated an excellent viability for this type of application due to their dimensions being minimal and showing uncertainties below 3%.Funda????o de Amparo ?? Pesquisa do Estado de S??o Paulo (FAPESP)Conselho Nacional de Desenvolvimento Cient??fico e Tecnol??gico (CNPq)FAPESP: 18/05982-0CNPq: 426513/2018-5