Dark matter is acknowledged to exist at different scales in the Universe. Cosmological observations strongly suggest that approximately 25% of the overall energy density of the Universe is attributed to dark matter, while roughly 5% is composed of baryonic matter. Since the neutrinos produced in pair-annihilation or decay of weakly interacting massive particles (WIMPs) could be observed by neutrino telescopes, these instruments provide an important complementarity in the quest for detecting dark matter signals. An excess of signal could be observed in regions where dark matter might accumulate, e.g., the Sun. The KM3NeT telescope is composed of two detectors, namely, ARCA (Astroparticle Research with Cosmics in the Abyss) and ORCA (Oscillation Research with
Cosmics in the Abyss). The energy threshold of the latter is ∼ 1 GeV. Given the fact that neutrinos above 1 TeV are typically absorbed before they can escape from the Sun, the energy range of the KM3NeT/ORCA detector is optimal for the search of dark matter signals coming from our star. In this contribution, the search for WIMP annihilation signals coming from the Sun is presented. An
unbinned likelihood method is used to discriminate the signal from the background in a 543-day livetime sample of data collected with the 6 first detection units of the ORCA detector. The limits on the neutrino flux and on the spin-dependent and spin-independent cross sections are given for three different annihilation channels. No evidence for a dark matter signal over the expected
background has been found.