Acid-base and redox reactions are important mechanisms that affect the optical properties of fluorescent probes. Fluorescent carbon nanoparticles which possess tailored surface functionality enable a prompt response to regional stimuli, offering a useful platform for detection, sensing and imaging. In this study, carbon nanoparticle (CNP) was developed as a novel nanoprobe (quantum yield = 10%) for detection of pH and hypochlorite. In the design of CNP, m-phenylenediamine was chosen as the major component of CNP for pH responsiveness, while ascorbic acid which possesses many oxygen-containing groups was incorporated to generate favorable functionalities for improved water solubility and additional response toward redox reactions. Thus, the CNP could serve as a pH probe and a turn-off sensor toward hypochlorite at neutral pH through fluorescence change. The as-prepared CNP exhibited a linear fluorescence response over the pH ranges from pH 5.5 to 8.5 (R2 = 0.989), and over the concentration range of 0.125–1.25 μM for hypochlorite. Meanwhile, the detection limit (LOD) of hypochlorite was calculated to be 0.029 μM at neutral pH. In addition, the CPN was further applied to the cell imaging. The positively charged surface and nanoscale dimension of the CNP caused the efficient cellular delivery of the CNP. The CNP was successfully used to cell imaging and sensitive detection of hypochlorite as well as pH changes in biological system. Given these desirable performances, the as-synthesized fluorescent CNP shows great potential as an optical nanoprobe for cellular sensing of pH values and hypochlorite concentration in the future.