Electroencephalogram (EEG) is one of the most important tools for exploring brain activity. Switching EEG from time domain to frequency domain can help us to understand how the brain works and how it behaves at different frequencies. Spectrogram and spectrum are the two manifestations of EEG in frequency domain. The key difference between a spectrogram and a spectrum is that a spectrogram includes time information. This allows it to show how the power of different frequencies in the brain changes over successive time points. If the different frequency intensities at a single time point are considered as a spectral microstate, we can obtain the change in the spectral microstate over time through a spectrogram. In this study, we evaluated spectrogram as potential biomarker of chronic stress and anxiety. Under the dual impact of efficiency and high-pressure environment, mental health has become a major priority. Stress has many effects on our brains. In addition to helping us cope with unexpected situations, it also has a memory-enhancing effect on stressful or emotionally stimulating events, which helps us remember important information. However, long-term exposure to stress can have a negative impact on our physical, mental, and spiritual aspects. In addition, anxiety also has a serious impact on our daily routines, resulting in inability to concentrate and leading to serious mental health problems. In this study, LEMON dataset was used in the study of chronic stress, which first converted the resting state EEG data collected from subjects into spectrogram and spectrum, and then used to train Convolutional Neural Network (CNN), to predict the result of Perceived Stress Questionnaire (PSQ). The anxiety study uses another dataset, test-retest dataset, and the follow-up treatment process is the same as that of chronic stress to predict the result of Self-rating Anxiety Scale (SAS). Results showed that CNN performed well in using spectrogram and spectrum as training materials on both datasets. In addition to the excellent performance of the classification results, this study found that, overall, the model performed better on spectrogram than on spectrum in both datasets, indicating that temporal information helps improve model performance. Furthermore, based on the effectiveness of temporal information, this study attempted to understand the critical role played by temporal information in spectrogram, i.e., the role of spectral microstates in spectrogram. Therefore, we used another deep learning model that also performs strongly with temporal information, Long Short-Term Memory (LSTM) network for comparison with CNN. The results showed that CNN's performance on spectrogram was superior to LSTM's performance on spectrogram. This suggests that although temporal information helps improve model performance, it is not primarily due to the long- and short-term relationships between spectral microstates brought about by temporal information (LSTM). Instead, the superior performance is due to CNN's ability to simultaneously capture the internal information of spectral microstates at each time point. In summary, the differences in spectral microstates between healthy subjects and patients can serve as effective biomarkers, and the combination of CNN and spectrogram is a suitable, effective, and powerful classification tool.