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Keithley Model Questions

Improving Low Electrical Current Measurements

Characterizing devices at low current levels requires knowledge, skill, and the right test equipment. Even with all three, achieving accuracy in these measurements can be a challenge because the current level is often at or below the noise level of the test setup. To ensure measurement accuracy, it is important to know the type of test equipment to use, the different sources of measurement error, and the appropriate techniques to minimize these errors. Examining several test examples, such as characterization of a field-effect transistor (FET) and a carbon nanotube, can help in the learning process.

The term low current is relative, of course. A current level considered low for one application, such as 1mA, may be high for a device operating at 10nA. In general, an instrument’s noise level will establish its low-level sensitivity, with low current measurements referring to those made near an instrument’s noise level. Trends in portable and remote electronic devices, along with advances in semiconductors and nanotechnology, are requiring greater use of low current measurements. Small geometry devices, photovoltaic devices, and carbon nanotubes (CNTs) are a few examples of devices designed to operate at extremely low current levels, and all of these devices must be characterized in terms of their current-voltage characteristics (I-V measurements).

A number of instruments are available for low-current measurements, depending on the type of device under test (DUT) and the level of current to be measured. Perhaps the most ubiquitous tool on production lines and in field service is the digital multimeter (DMM), which typically provides capabilities for measuring current, voltage, resistance, and temperature. The range of commercial products is wide, from low-cost units with 3½-digit readout resolution to rack-mount and benchtop high precision laboratory units. The most sensitive DMMs available can measure current levels as low as about 10pA.

When greater precision is needed, various forms of ammeters are available to measure current. These can be as simple as older types that measure current flow from the mechanical deflection of a coil in a magnetic field. More modern digital ammeters use an analog-to-digital converter (ADC) to measure the voltage across a shunt resistor and then determine and display the current from that reading. Newer picoammeters typically use a feedback resistor, which allows more accuracy in current measurements at such low levels. They are available in various configurations, including high-speed models and logarithmic units capable of measuring a wide range of currents. While they are extremely versatile, it is useful to understand the performance limitations of feedback ammeters.

Feedback Ammeter Performance. A simple feedback ammeter can be modeled with a small number of parameters. The current source is modeled as a voltage source in series with a parallel RC circuit, i.e., the source resistance (RS) and parallel source capacitance (CS). The feedback ammeter is modeled as a feedback amplifier with a parallel RC feedback circuit across it (i.e., RF and CF), with the two amplifier inputs being the external current source and the internal voltage noise source, VNOISE. The capacitances in the source and measurement circuits are parasitic elements associated with the resistances and circuit wiring. Using this model and ignoring capacitance, the noise gain of the ammeter circuit can be found from:

Output Voltage Noise = (Input Voltage Noise) x (1 + RF/RS)

As this equation implies, the output of a feedback ammeter circuit is a voltage, which is proportional to the input current. As the source resistance decreases in value, the output noise increases. When RF = RS, the input noise is multiplied by a factor of 2. If the source resistance is too low, it can have a detrimental effect on the noise performance of the measurement system. The optimum source resistance is a function of required measurement range for an ammeter, with a minimum value of 1MegOhm to measure nanoamps of current, compared to a minimum value of 1GigOhm to measure picoamps of current.

However, source capacitance can also affect the noise performance of a low current measurement instrument. In general, as the source capacitance increases, the noise gain also increases. This means that the equation above should be modified by substituting the feedback impedance (ZF) for the feedback resistance (RF) and the source impedance (ZS) for the source resistance (RS).

Additional current measurement instruments include electrometers and source-measure units (SMUs). An electrometer is essentially a voltmeter with a high input impedance (1TOhm and higher) that can be used to measure low current levels. It can be used as an ammeter to measure low current levels even at low voltages, and can also be used as a voltmeter to make voltage measurements with minimal effect on the circuit being measured. As an ammeter, an electrometer can measure currents as low as the instrument’s input offset current, as low as 1fA in some cases. As a voltmeter, an electrometer can measure the voltage on a capacitor without significantly discharging the device, and can measure the potential of piezoelectric crystals and high-impedance pH electrodes.

The SMU is an innovation for making low-current measurements. It combines precision current sources and voltage sources with sensitive detection circuitry for measuring both current and voltage. An SMU can simultaneously provide a source of current and measure voltage or provide a source of voltage and measure current. A well-equipped SMU may include a voltage source, current source, ammeter, voltmeter, and ohmmeter and is also programmable for use in automatic-test-equipment (ATE) systems.

Minimizing External Noise. All of these measuring instruments are effective tools for measuring current, but their sensitivity to low levels of current will be limited mainly by sources of noise, both within and external to the instrument. The DUT also affects the level of current that can be accurately measured with a given instrument, because the DUT’s source resistance (RS) establishes the level of Johnson current noise (IJ), which is low-level noise caused by temperature effects on electrons in a conductor. Johnson noise, which can be expressed in terms of either current or voltage, is essentially the voltage noise of a device divided by the device resistance:

IJ= √(4kTB/RS) / RS,

where                k = Boltzmann’s constant (1.38 × 10–23 J/K),

                        T = Absolute temperature of the source (in ºK),

                        B = the noise bandwidth (in Hz), and

                        RS = the resistance of the source (in ohms).

Both temperature and noise bandwidth affect the Johnson current noise. A reduction in either parameter will also reduce the Johnson current noise. Cryogenic cooling, for example, is often used to reduce noise in amplifiers and other circuits but adds cost and complexity. The noise bandwidth can be reduced by filtering, but this will result in slowing the measurement speed. The Johnson current noise also decreases as the DUT’s source resistance decreases, but this is not often a practical or even possible option.

Ideally, a current measurement would be just that of the DUT source. However, current noise from various unwanted sources can make it difficult to read a low-level DUT source current. One of these unwanted sources is part of the measurement system itself, i.e., the coaxial cables used to interconnect test instruments to each other or to the DUT. Typical test cables can generate as much as tens of nanoamps of current as a result of the triboelectric effect. This occurs when the outer shield of a coaxial test cable rubs against the cable’s insulation when the cable is flexed. As a result, electrons are stripped from the insulation, and added to the current total. In some applications, such as nanotechnology and semiconductor research, the current generated by this effect may exceed the level of current to be measured from the DUT.

Triboelectric effects can be minimized by using low-noise cable, with an inner insulator of polyethylene coated with graphite underneath the outer shield. The graphite reduces friction, and provides a path for the displaced electrons to return to their original locations, eliminating random electron motion and their contribution to the additional noise level. Excess current flow from triboelectric effects can also be minimized by reducing the length of the test cables as much as possible. The test setup should be isolated from vibration to minimize unwanted movement of the test cables, by positioning test cables on top of vibration-absorbing material, such as foam rubber. Test cable movement can also be minimized by taping the cables to a stable surface, such as the test bench.

Piezoelectric effect is another source of error in low-current measurements. It causes spurious current generation due to mechanical stress on susceptible materials. The effect varies by material, although some materials commonly used in electronic systems, such as polytetrafluoroethylene (PTFE) dielectrics, can produce a relatively large amount of current for a given amount of stress and vibration. Ceramic materials are less affected by piezoelectric effects and produce lower current levels. To minimize current generated by this effect, it is critical to minimize mechanical stress on insulators and construct the low-current test system using insulating materials with minimal piezoelectric properties.

Insulators can also degrade low-current measurement accuracy by means of dielectric absorption. This phenomenon occurs when a high-enough voltage across an insulator causes positive and negative charges to polarize. When the voltage is removed from the insulator, it gives up the separated charges as a decaying current, which is added to the total amount measured during a test. The decay time for the current from dielectric absorption to dissipate can be from minutes to hours. The effect can be minimized by applying only low-voltage levels to insulators used for low-current measurements.

Insulators can also degrade low-current measurement accuracy due to contamination from salt, moisture, oil, or even fingerprints on the surface of the insulator. Contamination effects can also plague printed circuit boards in a test fixture or in the test setup when, for example, excessive flux is used when soldering. On an insulator, the contamination acts to form a low-current battery at a sensitive current node within the insulator, generating noise currents that can be on the order of nanoamps. To minimize measurement errors from insulator contamination, an operator should wear gloves when handling insulators or simply avoid touching them. The use of solder should be minimized, and solder areas should be cleaned with an appropriate solvent, such as isopropyl alcohol. A clean cotton swab should be used for every cleaning, and cotton swabs should never be reused or dipped into the cleaning solution after having been used for cleaning.

It is critical to make low-current measurements in the absence of magnetic fields, because such fields can induce current flow in conductors. This is typically due to variations in magnetic field intensity, or motion of a conductor within a magnetic field. Both cases should be avoided to maintain measurement accuracy, which is best accomplished by properly shielding the measuring instrument or system.

Minimizing Instrument Offset Current. An instrument used for low-current measurements should show a zero reading when its input terminals are left in an open-circuit condition. Unfortunately, this is rarely the case due to a small current known as the input offset current. It is caused by bias currents of active devices in measuring instrument circuitry, as well as leakage current through insulators in the instrument or test system. Most instrument manufacturers specify the input offset current on their products’ data sheets for comparison purposes, and this small amount of current must be taken into account in any low-current measurement. In other words, the instrument’s reading is actually the sum of the DUT source current and the instrument’s input offset current.

The input offset current can be found by capping the input connector and selecting the lowest current range available on the measuring instrument. The reading shown by the instrument, after it has properly settled to a stable value, should be within the specification shown on the instrument’s data sheet and can be subtracted from DUT readings. On some instruments, a current-suppression function can partially null input offset current.

Another way to subtract input offset current from a low-current measurement is to use a relative function found on some measuring equipment, such as ammeters. The relative function stores the reading of whatever residual offset current is being measured with the input terminals left in an open-circuit condition; this reading is treated as the zero point for subsequent readings.

Application Examples. Some examples of practical low-current measurements include characterization of field effect transistors (FETs) and CNT devices. A more common FET test involves evaluation of a device’s common-source characteristics. Even at low current levels, the drain current can be studied using a simple test setup with a two-channel SMU, such as the Keithley Series 2600A System SourceMeter instrument. A two-channel SMU has the capability to source current or voltage and measure current or voltage simultaneously. To characterize a FET, it is mounted in a test fixture that allows secure ground and bias connections. One SMU channel supplies a swept gate-source voltage (VGS) to the FET while the other supplies a swept drain-source voltage (VDS) and measures the FET’s drain current (ID). This simple test setup allows the measurement of drain currents as low as 10nA or less.

Electronic materials such as photovoltaic wafers and CNT sheets are typically characterized in terms of their current density—the amount of current they can generate for a given area of material. Researchers from South Korea’s Seoul National University, conduct such tests to evaluate multi-walled carbon nanotube (MWNT) devices fabricated on an arc-discharge CNT substrate using a Keithley Model 6517 electrometer [1]. In these studies, current densities as low as 10–4/cm2 were measured at applied electric fields of 5V/μm and less. Practical analysis of the I-V characteristics of CNT-based electronics can also be performed in a manner similar to that for the FET by using a pair of SMUs to sweep drain and gate voltages while measuring and plotting the drain current as a function of gate voltage.

The required resolution and accuracy of low-current measurements will dictate the type of measurement tool used. When accuracy is less of an issue, a basic DMM may suffice. But for more demanding requirements, a precision electrometer or SMU may be needed. These precision instruments are optimized for low-current measurements, providing measurement resolution as small as 1fA. More techniques and tips on low current measurements are contained in Keithley’s Low Level Measurements Handbook [2].

 References.

1. Joeoong Hahn, Jae-Eun Yoo, Jaeik Han, Hyok Bo Kwon, and Jung Sang Suh, “Field emission from the film of the finely dispersed arc discharge black core material,” Carbon, Vol. 43, 2005, pp. 937-943.

2. Keithley Instruments, Inc., “Low Level Measurements Handbook, 6th Edition”, 2004, available for download at http://gw1.vtrenz.net/?SIP0AWDVFA.

About the Author

Jonathan Tucker is the Lead Industry Consultant for Nanotechnology at Keithley Instruments in Cleveland, Ohio. He is currently involved with measurement solution business development for nanotechnology applications requiring electrical characterization. He has over 19 years of experience in Test & Measurement and is currently supporting development of a standard for electrical measurements on carbon nanotubes and electronic devices that use carbon nanotubes. He holds a Bachelors of Electrical Engineering from Cleveland State University and an MBA from Kent State University.

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