We have designed four multifunctional high-transition-temperature directly-coupled superconducting-quantum-interference-device (SQUID) magnetometers on a 10 mm × 10 mm SrTiO 3 bicrystal substrate. Each magnetometer is composed of two serial bare SQUIDs. These magnetometers can be connected to four kinds of first-order electronic planar gradiometers or two kinds of second-order electronic planar gradiometers by using analog subtracting electronic circuits. The performance and noise spectra of each magnetometer, two first-order electronic planar gradiometers and a second-order planar gradiometer were measured. We measured the small magnetic signal generated from a double D coil to show that this design could supplement the deficiency of a magnetometer.A superconducting quantum interference device (SQUID) magnetometer is the most sensitive magnetic sensor in the world. It has been widely applied in many different territories, such as solid state physics, biology, geography, astronomy 1 , etc. After the discovery of high-transition temperature superconducting (HTS) material, many HTS SQUID systems have been constructed and applied to different applications such as nondestructive evaluation (NDE), scanning SQUID microscope (SSM), and magnetocardiography (MCG) 1 , etc. For practical applications, a multi-channel system 2-3 is more useful and powerful, especially in bio-magnetic research. A multi-channel system could perform a large area measurement and reduce measuring time. Alternatively, a multi-channel system offers the possibility for the measurement of the gradient of magnetic field.Referring to the concept of a multi-channel system, we have developed a multi-functional design of HTS dc SQUID magnetometers on a chip to increase the flexibility of applications. In our design, four dc SQUID magnetometers are fabricated on a 10 mm × 10 mm SrTiO 3 bicrystal substrate. Each magnetometer is composed of two serial bare SQUIDs, with 3 μm wide Josephson junctions, and of a 4 mm × 4 mm pick up loop with a width of 200 μm. As a result, we are able to create at most four magnetometers in one fabricating process. Though it is unlikely that the performances of each magnetometer will be the same, we can choose the best one for practical applications.Furthermore, these four magnetometers can be used to construct four kinds of first-order electronic planar gradiometers or two kinds of second-order electronic planar gradiometers by using analog subtracting electronic circuits. Hence, the magnetic field, B z , the first-order spatial derivatives of the magnetic field, ∂B z /∂x and ∂B z /∂y, and the second-order spatial derivative of the magnetic field, ∂ 2 B z /∂x∂y and ∂ 2 B z /∂y∂x, can be measured at the same time. For those applications working in unshielded environment, reducing the influence from the external noise is very important. Gradiometers have been shown to reduce the noise from the external environment 4 . We will show that the electronic planar gradiometer based on our design could work well under the unshielded env...
