Looking na pwedeng gawin research sa Analytical Chemistry.

1. Analysis of water contaminants: This research can focus on developing new analytical techniques to detect and quantify various pollutants in water, such as heavy metals, pesticides, pharmaceuticals, and personal care products.

2. Water quality assessment: This research can involve the development of analytical methods to evaluate the overall quality of water sources. This can include analyzing key parameters like pH, total dissolved solids, turbidity, conductivity, and various ions.

3. Determination of waterborne pathogens: This research can aim to develop sensitive and selective methods to detect and identify pathogenic microorganisms in water samples, such as bacteria (E. coli, Salmonella) and viruses (norovirus, rotavirus).

4. Monitoring emerging contaminants in water: With the increasing presence of emerging contaminants like microplastics, endocrine-disrupting compounds, and nanomaterials in water, this research can focus on developing robust analytical techniques to identify and quantify these substances.

5. Analysis of drinking water disinfection by-products: Drinking water treatment involves disinfection, which can lead to the formation of disinfection by-products (DBPs) like trihalomethanes (THMs) and haloacetic acids (HAAs). Research in this area can involve developing analytical methods to assess the levels of DBPs and their potential health risks.

6. Analysis of wastewater and industrial effluents: This research can involve the development of analytical techniques to analyze wastewater and industrial effluents for pollution monitoring purposes. It can focus on detecting and quantifying various chemicals and compounds present in these samples that may pose risks to the environment and human health.

7. Characterization of natural organic matter in water: Natural organic matter (NOM) in water sources can lead to various water quality issues, such as taste, odor, and potential formation of disinfection by-products. This research can involve developing analytical methods to characterize NOM, study its behavior, and identify its potential impact on water treatment processes.

8. Development of sensor technology for water analysis: This research can focus on designing and developing new sensor systems for real-time monitoring of various analytes in water. This can include the development of electrochemical, optical, or biosensor-based platforms for rapid and sensitive analysis.

9. Quantitative analysis of trace elements in water: Certain trace elements like arsenic, lead, and mercury can have significant health implications even at low concentrations. This research can involve the development of sensitive techniques to accurately measure and quantify these trace elements in water samples.

10. Analysis of volatile organic compounds (VOCs) in water: VOCs like benzene, toluene, and chloroform can contaminate water sources, mainly through industrial pollution and gasoline leakage. Research in this area can involve developing analytical methods to detect, identify, and quantify VOCs in water samples.