Chemical discharge into water has contaminated various locations globally, endangering humans and aquatic life. Industries, farms, wastewater treatment plants, and stormwater overflows release chemicals. The European Union has set pollutant concentration criteria in drinking, surface, and groundwater to reduce water pollution. To comply with these limits, analytical detection methods must be rapid, reliable, and able to identify even minute levels of chemicals. Agriculture uses pesticides to keep crops safe from illnesses, insects, and weeds. Few chemicals work, while the remainder sink into the soil and damage ground and surface water. Due to the growing emphasis on scene analytes over chromatographic approaches, new pesticide evaluation methods have been prioritized. This report summarises various electrochemical pesticide detection studies in a simple and targeted manner. This study examines the electrochemical detection of carbamates, organophosphorus, organochlorine, pyrethroids, and pyrethrins. Electrochemical diagnostic methods, electrode materials, electrolyte and pH of interesting samples, and sample matrices are examined. This paper will also discuss current advances in the respected study, analytical obstacles, and future opportunities. Many electrochemical investigations and analytical data are summarised in this article, which also describes the linear dynamic range of concentration and limit of detection for electrochemical pesticide sensing. This review discusses electrochemical pesticide sensing advances in the utilization of various nanomaterials.

Tibetan Plateau (TP) is known as the water tower of Asia, and glaciers are solid reservoirs that can regulate the amount of water. Black carbon (BC), as one of the important factors accelerating glacier melting, is causing evident environmental effects in snow and ice. However, a systematical summary of the potential sources, analytical methods, distributions, and environmental effects of BC in snow and ice on the TP's glaciers is scarce. Therefore, this study drew upon existing research on snow and ice BC on glaciers of the TP to describe the detection methods and uncertainties associated with them to clarify the concentrations of BC in snow and ice and their climatic effects. The primary detection methods are the optical method, the thermal-optical method, the thermochemical method, and the single-particle soot photometer method. However, few studies have systematically compared the results of BC and this study found that concentrations of BC in different types of snow and ice varied by 1-3 orders of magnitude, which drastically affected the regional hydrologic process by potentially accelerating the ablation of glaciers by approximately 15% and reducing the duration of snow accumulation by 3-4 days. In general, results obtained from the various testing methods differ drastically, which limited the systematical discussion. Accordingly, a universal standard for the sampling and measurement should be considered in the future work, which will be beneficial to facilitate the comparison of the spatiotemporal features and to provide scientific data for the model-simulated climatic effects of BC.