Adequate monitoring and tracking of radiation at department of energy legacy sites requires deployment of highly sensitive detectors. Utilizing the high sensitivity of inorganic scintillation materials usually requires a photomultiplier tube, which increases the cost, size, and power consumption of the detector. A gamma-ray detector consisting of a CMOS-based solid-state photomultiplier (SSPM), which offers low power consumption and a very small form factor, coupled to a variety of scintillation materials has been developed. We have compared the sensitivity of the CMOS SSPM radiation meter with regard to source identification and overall sensitivity as a function of incident gamma-ray energy. Two prototype configurations are compared with respect to homeland security applications: an SSPM spectrometer, with a high resolution scintillation material and many channels of readout, and a low resolution rate-meter with only four channels of energy information. Each device utilizes a 3 mm times 3 mm SSPM with 2024 pixels coupled to a scintillator matched to the size of the SSPM.