Cosmogenic nuclides, such as 14C from tree rings and 10Be and 36Cl from ice cores, are good proxies for past extreme solar energetic particle (SEP) events. After a discovery of the extreme SEP event in 774 CE by cosmogenic nuclide data, several candidates for extreme SEP events have been reported, including ca. 993 CE, 660 BCE, and 7176 BCE. Magnitudes of these SEP events have been estimated to be tens of times larger than the largest SEP event on record (GLE #5 in 1956). Whereas a survey of such extreme SEP events is ongoing, identifying intermediate-sized SEP events that bridge the gap between smaller event detected by modern observations and extreme events detected by cosmogenic nuclides has not progressed sufficiently, primarily due to uncertainties in cosmogenic nuclide data. In this study, we measured 14C concentrations in Alaskan tree samples (Sitka spruce) for the period from 1844 to 1876, to investigate potential 14C increases corresponding to solar events such as the Carrington solar flare/geomagnetic superstorm in 1859 and geomagnetic superstorm in 1872. We analyzed both early and late wood samples to suppress potential seasonal effects on 14C concentrations due to atmospheric transport. Our findings indicate no significant difference in 14C levels between early and late wood in our Alaskan tree samples, suggesting either a shorter wood formation than typical or the use of stored carbon for wood formation. Overall, our measured data show no significant 14C increase throughout the entire measurement period. This result provides an upper limit of annual integrated SEP fluence (F200) during this period as approximately 1 × 109 [/cm2]. These findings have been published in Miyake et al. 2023.