Singlet oxygen (O2) is known to play an indispensible role in the photodynamic therapy (PDT) treatment of cancer, and is an important oxidant for hydroperoxidation of olefins in organic synthesis. Singlet O2 is conventionally formed by sensitization by organic photosensitizers, such as Rose Bengal, silicon phthalocyanine, etc. These organic or organometallic dyes are, however, prone to photoinduced degradation and enzymatic degradation, which becomes problematic in PDT treatments, and reduces the efficiency of the generation of singlet O2. [5,8] It is, therefore, important to search for photosensitizers with highly efficient singlet O2 generation and large absorption coefficients that are photochemically more stable and less prone to enzymatic degradation. Previously, it was reported that the yield of singlet oxygen production by a photosensitizer, namely, Rose Bengal, was enhanced by a silver island film through the metal-enhanced absorption of photosensitizer. It was also reported that a gold nanodisk could enhance the phosphorescence decay rate of singlet oxygen, leading to a larger characteristic phosphorescence emission band of singlet oxygen at 1270 nm. In another two studies, it was observed that the quantum yield of singlet O2 formation generated by phthalocyanine photosensitizers can be enhanced by the presence of gold nanoparticles. Herein we report an unprecedented observation that singlet oxygen can be formed through direct sensitization by metal nanoparticles (M NPs, M=Ag, Pt, and Au) without the presence of any organic photosensitizers. Unambiguous experimental evidence includes direct observation of singlet oxygen emission at roughly 1268 nm, hydroperoxidation of cyclohexene, green fluorescence from a selective singlet oxygen fluorescent sensor, namely, Singlet Oxygen Sensor Green (SOSG, Molecular Probe), and quenching of singlet oxygen phosphorescence by sodium azide. As shown in Figure 1, photoexcitation of M NPs at the surface plasmon resonance absorption bands of Ag (d= 55, 42 nm), Pt (10 nm), and Au (22 nm) in D2O results in characteristic singlet oxygen emission at 1264 and 1268 nm, respectively. Control experiments show that in the absence of metal nanoparticles, photoexcitation of poly(vinyl pyrrolidone (PVP) in D2O using either 254 or 508 nm light did not result in any detectable singlet O2 emission signal (see the