Bolometer, a device for infrared (IR) thermal imaging, has been developed a lot in recent years. Electrical resistance of a bolometer varies rapidly due to the change in temperature caused by the absorption of IR radiation, so the temperature coefficient of resistance (TCR) is a vital parameter for characterizing the performances of bolometers. Here, based on the thin film of shear exfoliated two-dimensional (2D) materials confined in the polydimethylsiloxane (PDMS) substrate, we demonstrate the bolometric performances of the graphene films in different dimensions, and report a low-cost, transparent molybdenum disulfide (MoS2) bolometer with outstanding sensitivity, whose normalized current responsivity is up to -7.7 × 105 %W-1 and TCR achieves 133 %K-1. Its extremely tiny active area as pixel length facilitates high spatial resolution thermal imaging. In addition, we produce a graphene-contact MoS2 photodetector and a MoS2- doped graphene photodetector in the similar structure. These results not only present the properties of the low cost and high transparency of the 2D material films confined in the polymer structure but also imply the optoelectronics applications of thin films arranged in another dimension.