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<p>The exchange ratio (ER) between atmospheric <span class="inline-formula">O₂</span> and <span class="inline-formula">CO₂</span> is a useful tracer for better understanding the carbon budget on global and local scales. The variability of ER (in <span class="inline-formula">mol O₂ per mol CO₂</span>) between terrestrial ecosystems is not well known, and there is no consensus on how to derive the ER signal of an ecosystem, as there are different approaches available, either based on concentration (<span class="inline-formula">ER_atmos</span>) or flux measurements (<span class="inline-formula">ER_forest</span>). In this study we measured atmospheric <span class="inline-formula">O₂</span> and <span class="inline-formula">CO₂</span> concentrations at two heights (23 and 125 <span class="inline-formula">m</span>) above the boreal forest in Hyytiälä, Finland. Such measurements of <span class="inline-formula">O₂</span> are unique and enable us to potentially identify which forest carbon loss and production mechanisms dominate over various hours of the day. We found that the <span class="inline-formula">ER_atmos</span> signal at 23 <span class="inline-formula">m</span> not only represents the diurnal cycle of the forest exchange but also includes other factors, including entrainment of air masses in the atmospheric boundary layer before midday, with different thermodynamic and atmospheric composition characteristics. To derive <span class="inline-formula">ER_forest</span>, we infer <span class="inline-formula">O₂</span> fluxes using multiple theoretical and observation-based micro-meteorological formulations to determine the most suitable approach. Our resulting <span class="inline-formula">ER_forest</span> shows a distinct difference in behaviour between daytime (0.92 <span class="inline-formula">±</span> 0.17 <span class="inline-formula">mol mol⁻¹</span>) and nighttime (1.03 <span class="inline-formula">±</span> 0.05 <span class="inline-formula">mol mol⁻¹</span>). These insights demonstrate the diurnal variability of different ER signals above a boreal forest, and we also confirmed that the signals of <span class="inline-formula">ER_atmos</span> and <span class="inline-formula">ER_forest</span> cannot be used interchangeably. Therefore, we recommend measurements on multiple vertical levels to derive <span class="inline-formula">O₂</span> and <span class="inline-formula">CO₂</span> fluxes for the <span class="inline-formula">ER_forest</span> signal instead of a single level time series of the concentrations for the <span class="inline-formula">ER_atmos</span> signal. We show that <span class="inline-formula">ER_forest</span> can be further split into specific signals for respiration (1.03 <span class="inline-formula">±</span> 0.05 <span class="inline-formula">mol mol⁻¹</span>) and photosynthesis (0.96 <span class="inline-formula">±</span> 0.12 <span class="inline-formula">mol mol⁻¹</span>). This estimation allows us to separate the net ecosystem exchange (NEE) into gross primary production (GPP) and total ecosystem respiration (TER), giving comparable results to the more commonly used eddy covariance approach. Our study shows the potential of using atmospheric <span class="inline-formula">O₂</span> as an alternative and complementary method to gain new insights into the different <span class="inline-formula">CO₂</span> signals that contribute to the forest carbon budget.</p>