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R.C. McDowall is the principle of McDowall Consulting and director of R.D. McDowall Limited, and "Questions of Quality" column editor for LCGC Europe, Spectroscopy's sister magazine.

The need to calibrate and qualify analytical instruments and systems is well recognized in laboratories. However, calibrating and qualifying analytical instruments and systems are seen as discrete tasks. There is an increasing regulatory expectation that a risk-based life cycle approach is necessary to ensure “fitness for purpose” as part of an analytical procedure. The calibration and qualification lifecycle of analytical instruments and systems is a journey and not a sequence of disconnected events.

This article describes the principal stages of the lifecycle in both GXP or ISO/IEC 17025 laboratories that ensure that any analytical instrument and system is “fit for its intended use” as part of an analytical procedure, whether that is calibration or qualification. However, the tasks typically associated with these stages are often seen as discrete activities, but they should be integrated to form a continuum. In other words, the calibration and qualification lifecycle of analytical instruments and systems is a continuous journey, not a sequence of disconnected events. It is timely to consider a lifecycle approach because the United States Pharmacopoeia (USP) proposed a new General Chapter <1220> in September 2020 for analytical procedure lifecycle management (APLM) (1). There are no novel elements in this approach, but there is a structured process linking these activities that is described here.

Our starting point is the U.S. Good Manufacturing Practice (GMP) regulation for equipment design, size, and location in 21 

Equipment used in the manufacture, processing, packing, or holding of a drug product shall be of appropriate design, adequate size, and suitably located to facilitate operations for its intended use and for its cleaning and maintenance (2,3).

What does the phrase “intended use” mean and how should “fitness for intended use or purpose” be demonstrated in a regulated laboratory? Using our analytical instruments for analysis, we reviewed the high level process flow for the analytical procedure lifecycle from the proposed USP <1220> shown in Figure 1 (1). Notice that the key part of the process is stage 1 (Procedure Design, Development and Understanding). Method development is critical to the success of the whole process, and the draft USP <1220> covers an activity that the current International Council on Harmonization (ICH) Q2(R1) does not (4). Consequently, analysts developing methods must ensure that their analytical instruments are qualified and calibrated correctly and that the analytical systems are validated to ensure the smooth development and transfer of methods to the next stage of the lifecycle, which is called procedure performance qualification (PPQ). Qualification and calibration of analytical instruments is particularly important when analytical procedures are developed and validated in Research and Development (R&D) and later transferred to quality control laboratories.

Figure 1 shows that analytical procedure validation is no longer a discrete activity but a journey. As part of that journey, the first aspect of stage 2 PPQ requires qualification and calibration of instruments and systems as a prerequisite.

Analytical Process: Where Does Qualification and Calibration Fit? 

The analytical process, conducted within a pharmaceutical quality management system, provides reliable, traceable, and reportable values that are secure. The basic analytical process is shown in Figure 2 together with the relationship to stage 2 of the APLM highlighted in blue.

If we cannot demonstrate “fitness for purpose” of our instruments and systems, then outputs from our analytical process are unreliable. The current regulatory focus on data integrity and data governance requires us to put in place technical and procedure controls throughout the analytical process to ensure that data and records are trustworthy and reliable, and that quality decisions can be made in confidence.

The data governance and data integrity requirements and controls for a proposed analytical instrument and system (AIS) lifecycle that is defensible from a regulatory and technical perspective in Figure 2 can be mapped to the Foundation and Level 1 of a Data Integrity Model (5-8), shown in Figure S1, online. The Foundation ensures the right culture, ethos, and training for data governance and Level 1 ensures that instruments and computerized systems are calibrated, qualified and where appropriate validated for their intended use.

Analytical Instrument and System Lifecycle

The overall purpose of the AIS lifecycle is to demonstrate that not only is the instrument or system calibrated or qualified, but that any software is suitably validated and is operating in a controlled state. It is only then may we claim that the instrument or system is “fit for intended purpose” so that metrological data integrity is ensured. This article focuses on level 1 in this model concerning metrological integrity. The AIS lifecycle is shown in Figure 3. Data quality is only ensured if all components of data integrity and data governance are in place.

The levels of the AIS, with a specific focus on analytical instruments and systems, are presented at the bottom of Figure 3. Levels 1 and 2 are broken down into four elements each to provide metrological and procedural integrity, respectively. Levels 1 and 2 also overlay the culture and ethos of the foundation level. The quality oversight and some of the foundation level elements of the model are combined under data governance. Together these provide the essential requirements for the right reportable result at level 3 with associated data quality to ensure the correct decision is made.

The top portion of Figure 3 is based on the requirements of USP <1058>, analytical instrument qualification (9)that requires the following:

1) A laboratory user requirements specification (URS) to select the right instrument for the job (design qualification)

2) Following purchase of the instrument, a supplier IQ/OQ is per- formed to demonstrate that the requirements in the laboratory URS have been met. If this is not the case, the laboratory needs to conduct supplementary qualification tests to match the operating ranges specified.

3) Performance qualification (PQ) tests to demonstrate that the laboratory specifications are being met during operation of the instrument must be devised along with a plan for requalification of the instrument both after repair and maintenance but also periodically. 

4) The PQ test performance should be trended to detect any changes as well as maintaining deviation management and change control to demonstrate that the instrument is in a state of control.

The authors have published a risk assessment to help classify analytical instruments and systems into the USP <1058> groups and subtypes and suggest the extent of computerized system validation to be undertaken (10). Combining all the activities shown in Figure 3 ensures that analytical instruments and systems generate data and reportable results with appropriate integrity and quality.

Recently in Pharmacopoeial Forum, a stimulus to the revision process article was published discussing a lifecycle approach to both calibration and qualification (11). However, before we discuss this article, we need to consider the applicable FDA GMP regulations, by going back to the future.

Since the promulgation of the GMP regulations in 1978, approaches to ensuring that analytical instruments are “fit for intended use” have changed along with the terminology. Analytical instruments have changed and software, either in the form of firmware or a separate data system, now comprises a major component of modern analytical instrumentation. However, the wording of the regulations has not changed but the interpretation of them has. In 21 

 211.160(b) there are requirements that any laboratory control mechanisms must be scientifically sound and in 211.160(b)(4) we have the following requirement for calibration (3):

The calibration of instruments, apparatus, gauges, and recording devices at suitable intervals in accordance with an established written program containing specific directions, schedules, limits for accuracy and precision, and provisions for remedial action in the event accuracy and/or precision limits are not met. Instruments, apparatus, gauges, and recording devices not meeting established specifications shall not be used.

The records for such calibrations are defined in 211.194 (d) (3):

Complete records shall be maintained of the periodic calibration of laboratory instruments, apparatus, gauges, and recording devices required by 211.160(b)(4).

The problem is that the U.S. GMP regulations only mention calibration and therefore citations in 483 observations and warning letters will only cite deficiencies in instrument calibration when a qualification lapse could be the cause of the noncompliance, resulting in potential confusion. However, as our understanding of how to demonstrate fitness for intended use has evolved, so has the terminology.

The terms used within this section are one of the sources of great confusion between laboratories. For example, 

 can sometimes be used as a general “descriptive label” or have a specific meaning within the context of use. In addition to calibration, we now have the terms 

 also in common use. USP general chapter <1058> on analytical instrument qualification (9) provides an integrated approach to qualification of the analytical instrument and validation of the software. This general chapter mentions the terms calibration, qualification, verification, and validation. What do these terms mean? Are they linked? And where are we going in the future? All organizations, including regulatory authorities, need a technical glossary. There is no technical glossary that ensures a consistent meaning and use of terms throughout the pharmacopeia and other regulatory documents.

It is generally accepted that calibration forms part of the overall qualification process of an instrument or system. Calibration is all about metrology. Calibration is that part of qualification relating to measurement integrity of the ordinate response and abscissa functions, that is, all measurements from the instrument or system are within defined acceptance limits of a true or certified value.

The foundation for assurance of metrological “fitness for purpose” lies with the correct use of either a certified reference material (CRM) or a reference standard (RS). In the pharmacopeia, calibration is a comparison between a known or accepted value of a CRM or RS with its measured value on a specific laboratory analytical instrument or system being used for a pharmacopeial purpose the difference between these two values is compared with an acceptance criterion that may be an acceptable range or tolerance interval. For example, the measured value of a certified standard value of a wavelength standard must lie within the acceptance criteria of ±2 nm over the spectral range 200 to 400 nm. For some analytical instruments, calibration may all that is required (9).

Qualification is about overall “fitness for purpose” of an instrument or system, not only about good numbers. Hence the pharmacopeias require qualified instruments and systems. 

 <1058> is the only pharmacopoeial general chapter to describe the overall process of analytical instrument qualification (9).

 relates to the “fitness for purpose” of analytical procedures as required by the General Chapter on Verification of Analytical Procedures <1226> (12). However, verification is also used in the American National Standards Institute (ANSI) for software to refer to demonstrating that each individual step is mathematically or procedurally correct. GAMP 5 describes the testing phases of a computerized system lifecycle to demonstrate meeting user specifications (13). Therefore, some aspects of modular calibration (see later section) may be regarded as a verification process. The current version of 

 <1058> on analytical instrument qualification (AIQ) does not use 

Currently, validation relates either to the establishment of analytical procedures as required by General Chapter <1225>, Validation of Analytical Procedures (14) or particularly in General Chapter <1058>, Analytical Instrument Qualification for “fitness for purpose” (9). For example, in the “Instrument Control, Acquisition and Processing Software” section of <1058>, it states:

At the user site, integrated qualification of the instrument, in conjunction with validation of the software, involves the entire system. This is more efficient than separating instrument qualification from validation of the software (9).

However, there is a diversity of definitions for calibration, qualification, verification, and validation within the USP General Chapters that need to be harmonized to assist understanding and prevent user confusion. This is particularly true for the differentiation of holistic and modular calibration standards and the expression of acceptance criteria for establishing “fitness for purpose” (15,16).

The perennial question of “who does what and when” is answered in the lifecycle approach to calibration shown in Figure 4. The solid lines denote the primary process flows for establishing and confirming “fitness for purpose.” Dotted or dashed lines indicate either feedback loops triggered by data generated during the ongoing performance phase or, in the case of the URS, supported by the vendor.

The generic process of calibration and qualification should be designed to allow confirmation of “fitness for purpose” at all stages in the lifecycle including assurance of preventative maintenance and change control.

Users need to define their own control strategy to specify ongoing “fitness for purpose” by establishing the frequency of calibration, standards and acceptance criteria that will be employed and trend analysis of the ongoing performance data from the instrument.

One important aspect of the calibration and qualification lifecycle is the presence of change control feedback loops as part of the lifecycle. For example, if the qualified operational wavelength range for a UV spectrometer was originally 240 to 600 nm and the requirement is to extend this to 210 to 600 nm, then a new qualification standard is required to confirm “fitness for purpose” (17–19). In addition, the laboratory URS needs to be reviewed to ensure that the instrument was correctly specified originally to allow the revision of operational range.

Do You Specify Exactly What You Need the Instrument or System to Do?

 <1058> (9) is defined in a user specification. These are laboratory requirements for any analytical instrument with scientifically sound acceptance criteria. This does not mean simply copying the supplier’s specification, as discussed in an earlier column (18) but defining what is actually required. For example, if a UV-vis spectrometer has a supplier’s wavelength specification between 190 and 800 nm, what do you actually use? For example, if you only require measurement between 210 and 300 nm, then this should be your operating range. The requirement for wavelength accuracy is contained in 

 <857> (20) and this should be quoted in the specification document for the instrument. Testing wavelength accuracy using a CRM (for example, a holmium perchlorate solution or a glass filter) should demonstrate that this user requirement is met and that the instrument performs within scientifically sound acceptance criteria. Similar approaches need to be undertaken for the other technical requirements for the spectrometer.

Best Practices for Instrument Calibration

The best practice is to use the most stable artifact with the smallest uncertainty budget. For example, for routine monitoring of UV-vis and near infrared spectrometers, solid or liquid filters traceable to a national measurement institution (NMI), for both wavelength and absorbance accuracy qualification provide the most reliable option for the user.

For example, Figure 5 shows an overview of available standards for UV-vis-NIR over the overall spectral range available from one manufacturer. For example, to cover an operational wavelength range of 200 to 795 nm, two references would be required.

Articles

The calibration and qualification of analytical systems is a journey, not an event.

Are You Ready for a Life Cycle Approach for Analytical Instruments and Systems?

David Tuschel is a Raman applications manager at Horiba Scientific in Edison, New Jersey, where he works with Fran Adar. David is sharing authorship of the "Molecular Spectroscopy Workbench" column with Fran.

Fran Adar is the Worldwide Raman Applications manager for Horiba Jobin Yvon.

Group theory in conjunction with Raman polarization selection rules may be applied to the study and characterization of crystalline materials. The Polarization–Orientation (P-O) Raman method employs this relationship, and is useful for the identification of a material’s crystal class, orientation, degree of disorder, and determination of the symmetry species to which the Raman bands in a spectrum belong. Furthermore, it can be used to distinguish allotropes and polymorphs, differentiate single from polycrystalline materials, and determine whether materials at different locations in a fabricated device are crystallographically aligned. We discuss the theory and sensitivity of P-O Raman spectroscopy in the backscattering mode applied to crystals for which the nonzero Raman polarizability tensor elements of symmetry species are neither necessarily equal nor proportional. We demonstrate the effects of Raman polarizability tensor relative values and crystal orientation by calculating P-O Raman diagrams for the A and E symmetry species of the trigonal 

Raman crystallography is the application of group theory and Raman polarization selection rules to the study and characterization of crystalline materials. Characterizing crystalline materials by Raman spectroscopy is a good alternative when sample size or structure precludes one from doing so by X-ray diffraction. Where sample morphology or spatial variation of chemical composition or crystalline structure is on a scale that precludes or makes impractical the use of X-ray diffraction, polarized micro-Raman spectroscopy can often obtain crystallographic information. Applications of applied polarized Raman spectroscopy include characterization of minerals, integrated electronic and electro-optic devices, microelectromechanical systems (MEMS), and organic electronic devices including photovoltaics and organic light emitting diodes (OLEDs).

Most spectroscopists are familiar with Raman spectroscopy as a method of chemical analysis because of its sensitivity to the masses of a compound’s constituent atoms and their bond lengths and force constants. In addition, Raman spectroscopy can also be used for the characterization of the atomic structure of solids because Raman scattering depends on the polarization and direction of the incident light, the crystal symmetry and orientation of the solid sample, and the direction and polarization of the collected scattered light. Micro-Raman spectroscopic methods for determining local crystal orientation in silicon have been developed which take advantage of these properties (1,2). Raman crystallography can be applied to many materials, and the interested reader can find very elegant polarized Raman spectroscopic applications to characterize GaN (3), sapphire (4), and zirconia (5).

Polarization–Orientation Raman Spectroscopy

We discussed one method of Raman crystallography called Polarization–Orientation (P-O) Raman spectroscopy in a prior “Molecular Spectroscopy Workbench” installment (6). The P-O Raman method is useful for the identification of a material’s crystal class, orientation, degree of disorder, and determination of the symmetry species to which the Raman bands in a spectrum belong. To understand how this relationship can be applied to the characterization of crystals, we begin by considering the most fundamental expressions related to Raman scattering:

where α is the Raman polarizability tensor representing the vibrational modulation of the polarizability, 

 is the incident electric field vector, and 

 is the time varying dipole moment (also a vector) induced by the interaction of the incident electric field with the vibrationally modulated polarizability of the chemical bond. The Raman polarizability tensor is fixed relative to the positions of the atoms and the directions of the chemical bonds between them. Therefore, for a crystal fixed in space the relationship described by equations 1 and 2 is dependent upon the crystal symmetry and orientation of the sample relative to the direction and polarization of the incident and collected light. This relationship constitutes that part of the expression for Raman scattering intensity of interest to us in equation 3:

 is the intensity of the incident light, 

 is a factor incorporating the dependence on the frequency of the incident light, 

, the polarization of the incident light, and 

 and Ω are the polarization and solid angle, respectively, at which scattered light is collected. The significance of this expression for work with crystals is that Raman scattering intensity is proportional to the square of the dot product of the incident electric field vector, Raman polarizability tensor, and scattering vector.

The theory and general application of P-O Raman spectroscopy in the backscattering mode is based on the interdependence of incident electric field, Raman polarizability tensor and scattering vector. Most important is that the forms (whether elements are zero or nonzero) of the Raman polarizability tensors for crystals are dictated by the symmetry species of the crystal class to which the material belongs. The absolute magnitude of the tensor elements will be dictated by the specific chemical bonds between the atoms. However, whether a Raman tensor element is zero or nonzero is entirely dictated by the crystal symmetry. There are 32 crystal classes and the forms of the Raman polarizability tensors have been determined for all of them and tabulated in various publications (7–9).

In that previous introduction to P-O Raman spectroscopy, we demonstrated good agreement between the experimentally obtained results from single crystal Si and the calculated predictions for several crystallographic faces (6). The most common crystalline form of Si is cubic with two atoms in the primitive cell and belonging to crystal class 

. The first order optical phonon at 520 cm

 is triply degenerate and there are three 

 Raman polarizability tensors of the form:

where the letter d indicates a nonzero value. An experimental arrangement can be envisioned in which the laser beam is incident along the 

-axis with respect to the laboratory reference frame. This arrangement corresponds to the Raman microscope backscattering configuration. A cubic single crystal Si chip is positioned such that its crystallographic XY-plane is coplanar with the laboratory XY-plane. Backscattered light is collected in two configurations, with the analyzer either parallel or perpendicular to the polarization of the incident laser light. Raman scattering strengths (normalized) equal to the square of the dot product in equation 3 have been calculated for the analyzer parallel and perpendicular to the incident polarization as the crystal is rotated in the XY-plane. The calculated P-O diagram for Raman backscattering signal strength of the first order optical phonon at 520 cm

from the XY-face of cubic Si is shown in Figure 1.

The parallel and perpendicular responses are sinusoidal functions 45° out of phase, and, of course, because of the cubic symmetry the response is the same for the XZ- and YZ-faces. However, if the crystal is oriented out of these planes, one begins to see the effect of orientation on the P-O Raman plots. The method used to transform the Raman polarizability tensors from one crystal orientation to another is the transformation through Euler’s angles (10). The interested reader can refer to our previous publication to compare the P-O Raman results for the (100), (110) and (111) faces of cubic Si (6).

We have performed P-O Raman calculations for many other Si crystal orientations and have found the method to be very sensitive to crystal orientation. In fact, this sensitivity will be true for crystals of all symmetry classes because the P-O Raman diagrams depend only on the forms of the Raman polarizability tensors. Crystals of symmetry lower than that of the cubic system can have Raman polarizability tensors in which the nonzero elements are not equal, and in those cases, the P-O diagram will be affected by the relative magnitudes of the tensor elements. In fact, comparing calculated P-O Raman diagrams to the experimentally obtained P-O plots allows one to infer relative Raman scattering cross-sections of vibrational modes from crystals. The form or pattern of P-O Raman diagrams are dependent upon crystal symmetry and the relative magnitudes of the nonzero tensor elements, which depend upon the specific elemental, compositional, or molecular identity of the crystal. That is what makes the P-O Raman method a useful basis for Raman crystallography.

One can immediately recognize the application of this method for the characterization of crystal structure and orientation in either naturally occurring materials or fabricated devices. The P-O Raman method is complementary to X-ray diffraction, and should be considered when X-ray analysis is not practical or possible. P-O Raman spectroscopy may be used to identify vibrational modes, distinguish allotropes and polymorphs, distinguish single from polycrystalline materials, and determine orientation of the crystal and degree of disorder. Furthermore, one can determine whether materials at different locations in a fabricated device are crystallographically aligned based upon the phases of the experimentally obtained P-O Raman diagrams.

The nonzero elements of the triply degenerate 

 crystal class are all equal. Therefore, only the crystal orientation can affect the P-O Raman diagram for that symmetry species. The cubic system is a special case of high symmetry and all of the nonzero tensor elements of the various symmetry species of the cubic classes are either equal or proportional to each other. That is not the case for the other 27 crystal classes that do not belong to the cubic system.

Here, we discuss the theory and more general application of P-O Raman spectroscopy in the backscattering mode applied to crystals for which the nonzero Raman tensor elements of symmetry species are neither equal nor proportional. We demonstrate the effects of Raman tensor relative values and crystal orientation by calculating P-O Raman diagrams for the 

 crystal classes. The Raman tensors of these symmetry species are shown in equation 5. The 

 symmetry species is doubly degenerate and so there are two Raman polarizability matrices associated with that species.

 symmetry species in equation 5 and note that only the diagonal tensor elements are nonzero. Furthermore, α

, and, as we will see, the relative magnitudes of the tensor elements will affect the PO Raman diagram depending upon the sample’s crystal orientation. The P-O Raman experimental arrangement can be envisioned in which the laser beam is directed along the 

-axis, with respect to the sample’s crystallographic axes and at a crystal rotational angle of 0°. The XY-face of the trigonal 

 crystal is positioned coplanar with the XY-plane of the laboratory frame, and backscattered light is collected along the z-axis. Raman scattering strengths for α

 = 10 have been calculated for the analyzer parallel and perpendicular to the incident polarization as the crystal is rotated in the XY-plane. The calculated P-O diagram for Raman backscattering signal strength from the XY-face of the A symmetry species of a trigonal 

 crystal is shown in Figure 2. The P-O Raman responses for both parallel and perpendicular configurations are invariant with crystal orientation. The parallel Raman signal is allowed and always equal to the squared α

 values of 1, whereas the perpendicular response is forbidden, yielding a Raman signal of zero. Mathematically, the reason for these responses is that both diagonal tensor elements within the XY-plane of rotation are equal to 1, whereas α

 is perpendicular to the plane of rotation, and does not contribute to the signal in the backscattering configuration. In this experimental arrangement the specific value of α

, which in this example is 10, has no effect on the P-O Raman diagram.

Now, envision rotating the crystal 90° such that the laser is incident upon the YZ-face and is polarized along the 

-axis when the crystal rotation angle is at 0°. Relative Raman scattering strengths have been calculated for the analyzer parallel and perpendicular to the incident polarization as the crystal is rotated in the YZ-plane. In this configuration, the relative magnitudes of the α

 values directly affect the P-O Raman diagram, because the crystal rotation is in the YZ-plane and the dot product of equation 3 varies with crystal orientation. The calculated P-O diagrams for Raman backscattering signal strength from the YZ-face of the A symmetry species of a trigonal 

 values are shown in Figure 3. Note that the P-O Raman diagrams of the YZ- and XZ-faces are identical because the α

 values for the P-O Raman diagrams in Figure 3 are 0.01, 0.25, 0.5, and 0.75, all less than 1, the value we designated for α

. The Raman signal strengths for parallel and perpendicular configurations vary with crystal orientation, with the perpendicular response varying at twice the frequency as that of the parallel configuration. The P-O Raman diagrams of the A symmetry species obtained from the YZ-face are entirely different from that of the XY-plane, which was invariant with crystal angle. That is because the contributing Raman tensor elements are not equal when probing the YZ-face, whereas those contributing in the XY-plane are equal. The Raman signal reaches a maximum in the parallel configuration at 90° and 270°, whereas in the perpendicular configuration the Raman signal peaks at 45°, 135°, 225°, and 315°. The crystal angle separation between the maxima are 180° and 90° for the parallel and perpendicular polarization configurations, respectively. The P-O Raman response maxima remain at the same angles of crystal orientation for all α

. However, there are two noticeable variations in the P-O Raman diagrams, as the α

 values are changed relative to that of α

. The valley at 180° becomes less broad and more rounded with increasing α

 values. Also, the amplitudes of the parallel and perpendicular responses decrease, and the two functions separate, as the α

. These calculated P-O Raman diagrams demonstrate that experimentally obtained P-O Raman responses can be used to identify the crystalline face, assign the symmetry species of a particular Raman band, and determine the relative values of the α

 Raman polarizability tensor elements of the A symmetry species when α

Now, we examine those cases in which the Raman tensor values of the A symmetry species are α

 values for the P-O Raman diagrams in Figure 4 are 1, 1.5, 2.5, and 10, all greater than or equal to the value we designated for α

. The P-O Raman responses for both parallel and perpendicular configurations are invariant with crystal orientation when αxx = α

 = 1. The parallel Raman signal is allowed, and always equal to the squared α

 values of 1, whereas the perpendicular response is forbidden yielding a Raman signal of zero. This is the response that one would expect because, mathematically, the situation here is the same as for the XY-face P-O Raman diagram shown in Figure 2, where the contributing diagonal Raman tensor elements are equal. Looking back at Figure 3 with Figure 4a in mind, one can see the progression of the P-O Raman diagrams culminating in the invariant response of Figure 4a as the value of α

. The P-O Raman diagram of Figure 4b, with α

 = 1.5, appears similar to that of Figure 3d, with α

 = 0.75, with respect to the separation of the parallel and perpendicular responses. However, the phases of the parallel responses in Figures 4b–d are shifted 90° relative to those in Figure 3. Now the Raman signal reaches a maximum in the parallel configuration at 0°, 180°, and 360°, whereas in the perpendicular configuration the Raman signal peaks at 45°, 135°, 225°, and 315°, just as it did for α

. The phase shift of the A symmetry species P-O Raman parallel response informs us whether the α

 value is greater or less than that of α

, and the amplitudes and separations of the parallel and perpendicular responses allow us to determine the relative magnitudes of the contributing Raman polarizability tensor elements.

Thus far, we have discussed the P-O Raman response of only the A symmetry species. Now we turn our attention to the Raman active doubly degenerate E symmetry vibrational modes. The two 

 Raman polarizability tensors shown in equation 5 both apply when calculating the P-O Raman diagram for this symmetry species because of its double degeneracy. You can see from equation 5 that the 

 symmetry species is more complicated, because it has both diagonal and off-diagonal Raman tensor elements that are nonzero. Also, there are both positive and negative tensor element values. Nevertheless, there are only two absolute values or magnitudes in the two Raman tensors indicated by the letters 

 in equation 5. The differences of the magnitudes of tensor elements 

 can yield a wide variety of P-O Raman diagrams. We show just a sampling here so that you can get a sense of how sensitive the P-O Raman method is to crystal orientation and the relative values of the Raman tensor elements.

The P-O Raman experimental arrangement can be envisioned in which the laser beam is directed along the 

-axis with respect to the sample’s crystallographic axes and at a crystal rotational angle of 0°. The XY-face of the trigonal 

 crystal is positioned coplanar with the XY-plane of the laboratory frame, and backscattered light is collected along the z-axis. Raman scattering strengths for αxx = 2, α

 = -1 have been calculated for the analyzer parallel and perpendicular to the incident polarization as the crystal is rotated in the XY-plane. The calculated P-O diagram for Raman backscattering signal strength from the XY-face of the 

crystal is shown in Figure 5. The P-O Raman responses for both parallel and perpendicular configurations are invariant with crystal orientation and each is equal to a Raman signal of 4, the square of the tensor values α

 = -2. Mathematically, the reason for these responses is that only the Raman tensor 

elements within the XY-plane of rotation contribute to the Raman signal, and they all have the same absolute value of 2. The nonzero Raman tensor elements α

 are perpendicular to the plane of rotation, and do not contribute to the signal in the backscattering configuration. In this experimental arrangement the specific value of α

, which in this example is 1, has no effect on the P-O Raman diagram.

Note that the P-O Raman diagrams of both the 

symmetry species are invariant with crystal orientation within the XY-plane. Nevertheless, the two symmetry species can be differentiated and assigned to Raman bands from P-O Raman plots experimentally obtained from the XY-face of a crystal belonging to a trigonal 

 crystal class. That is because the perpendicular response of the 

 symmetry species is not allowed, whereas that of the 

 symmetry species is allowed and is equal to the parallel configuration response.

Now, envision rotating the crystal 90° such that the laser is incident upon the YZ-face and is polarized along the z-axis when the crystal rotation angle is at 0°. Relative 

Raman scattering strengths have been calculated for the analyzer parallel and perpendicular to the incident polarization as the crystal is rotated in the YZ-plane. Figure 6 shows the P-O Raman diagram for the YZ-face of a trigonal 

 = -1. Here, the P-O Raman diagram is no longer invariant with crystal orientation, even though the nonzero tensor absolute values contributing to the YZ-plane are 

all equal to 1. The P-O Raman diagram is oscillatory, and the parallel and perpendicular responses differ from each other in phase by 45°. The last two maxima of the parallel and perpendicular responses are labeled, and you can see that their separation within each configuration is 90°. Of course, the 

 nonzero tensor elements of equation 5 are not likely to be equal for a real uniaxial crystal. However, setting them equal demonstrates that the oscillatory response of the P-O diagram as shown in Figure 6 arises primarily from the contribution of the nonzero off-diagonal tensor elements to the YZ-plane, whereas equal values assigned to the diagonal and off-diagonal tensor elements within the XY-plane as in Figure 5 generate a P-O Raman diagram invariant with crystal rotation.

Having reviewed the P-O Raman response when the absolute values of the nonzero Raman tensor elements are equal, now let us analyze the effects when the relative magnitudes of the c and d nonzero tensor elements of equation 5 are varied. Figure 7a shows the P-O Raman 

 = -1; the absolute value of the Raman tensors in the XY-plane equals 1.5, and that in the XZ- and YZ-planes equals 1. We can see the effect of the increase in tensor magnitudes in the XY-plane by comparing this P-O Raman diagram with that of Figure 6. There are two noticeable differences between the two. The first is that the parallel and perpendicular responses in Figure 7a are shifted -5° relative to those in Figure 6 (the last two maxima of the parallel and perpendicular responses are labeled to assist in recognizing this shift). Also, the first and third maxima of the parallel configuration in Figure 7a peak at a lower signal strength than that of the corresponding maxima in Figure 6. Increasing the absolute value of the Raman tensors in the XY-plane to αxx = 5, α

 = -1 advances this progression, as shown in Figure 7c. Both parallel and perpendicular responses are shifted -15° relative to those in Figure 7a. Also, the first and third maxima of the parallel configurations in Figures 6 and 7a have now vanished.

It is useful to reverse the Raman tensor magnitudes of the XY-plane and the XZ- and YZ-planes, as shown in Figures 7b and 7d, to see the effects on the P-O Raman diagram. Compare the P-O Raman diagrams of Figures 7a and 7b in which the magnitudes of the Raman tensor elements 

have been maintained but simply reversed for the planes containing the ordinary axes (

). The parallel and perpendicular responses in Figure 7b appear similar to those in Figure 7a but are not identical. Several differences are clear. First, the phases of both the parallel and perpendicular responses of Figure 7b are shifted +10° relative to those in Figure 7a. Additionally, the first and third maxima of the parallel configurations in Figure 7b are more intense than the corresponding maxima in Figure 7a. Finally, the perpendicular response in Figure 7b is relatively stronger than that in Figure 7a. We see a similar progression when comparing the P-O Raman diagrams of Figures 7c and 7d. The phases of both the parallel 

and perpendicular responses of Figure 7d are shifted +32° relative to those in Figure 7c. Also, the perpendicular response in Figure 7d is relatively stronger than that in Figure 7c.

These subtle effects of the Raman tensor magnitudes on the phases and amplitudes of the P-O Raman diagrams are not intuitive. One might expect that such changes would occur if a crystal is rotated to some degree off of its crystallographic axis with respect to the direction of laser 

propagation, but not from changes in the Raman tensor magnitudes. P-O Raman calculations help one to anticipate and understand these effects. This observation is important, because more Raman spectroscopists are using experimental methods of laser polarization in conjunction with sample orientation to infer crystal phase and orientation along with the assignment of symmetry species to particular Raman bands. The calculated P-O Raman 

diagrams show how significantly the magnitudes of the Raman tensor elements affect the P-O Raman results and make clear that such calculations are necessary to properly interpret the experimentally obtained results of polarized Raman measurements obtained from crystals whose Raman tensor elements are not equal.

In this article, we discussed the application of group theory and Raman polarization selection rules to the study and characterization of crystalline materials. Specifically, we described one method of Raman crystallography called polarization–orientation Raman spectroscopy. The P-O Raman method has been shown to be useful for the identification of a material’s crystal class, orientation, degree of disorder, and determination of the symmetry species to which the Raman bands in a spectrum belong. Here, we discussed the theory and more general application of P-O Raman spectroscopy in the backscattering mode applied to crystals for which the nonzero Raman polarizability tensor elements of symmetry species are neither necessarily 

equal nor proportional. We demonstrated the effects of Raman polarizability tensor relative values and crystal orientation by calculating P-O Raman diagrams for the A and E symmetry species of the trigonal 

 crystal classes. The calculated P-O Raman diagrams show how significantly the magnitudes of the Raman polarizability tensor elements affect the P-O Raman results, and make clear that such calculations are necessary to properly interpret and understand the experimentally obtained results of polarized Raman measurements obtained from crystals whose Raman polarizability tensor elements are not equal.

(3) H.C. Lin, Z.C. Feng, M.S. Chen, Z.X. Shen, I.T. Ferguson, and W. Lu, 

(4) M.C. Munisso, W. Zhu, and G. Pezzotti, 

(5) K. Fukatsu, W. Zhu, and G. Pezzotti, 

 (Academic Press, New York, New York, 1972), pp. 358–361.

, D.J. Gardiner and P.R. Graves, Eds. (Springer-Verlag, New York, New York, 1989), pp. 22–24.

(10) E.B. Wilson, Jr., J.C. Decius, and P.C. Cross, 

Molecular Vibrations: The Theory of Infrared and Raman Vibrational Spectra

 (McGraw-Hill, New York, New York, 1955), p. 285.

l is a Raman applications scientist at Horiba Scientific, in Piscataway, New Jersey, where he works with Fran Adar. David is sharing authorship of this column with Fran. He can be reached at: 

Raman spectroscopy is extremely useful for characterizing crystalline materials.

Raman Crystallography and the Effect of Raman Polarizability Tensor Element Values

Non-destructive mobile spectroscopic instrumentation is proving useful for examining components of cultural heritage objects—such as fibers, pigments, dyes, and inks—for quantitative and qualitative results. Mary Kate Donais of Saint Anselm College, in Manchester, New Hampshire, recently conducted a study using portable spectroscopy techniques to characterize historic fabrics from a turn-of-the-19th century New England mill that belonged to the Amoskeag Manufacturing Company, one of the largest textile producers in the world at its prime. We recently spoke to Donais about this work.

How did the opportunity to examine these samples come about?

I attended an exhibit opening featuring locally made quilts at our local history museum. I spoke to the co-curator on the exhibit about our work with cultural heritage and portable spectroscopy, and she was intrigued. The museum’s director overhead our conversation, and mentioned the fabric sample books in the museum’s collections. We were all hooked!

Having access to both the handwritten dye recipes and the corresponding fabrics was a perfect coming together of history and chemistry. The first part of the project involved a history student examining the recipes, and doing the archival research to make some sense of them from a historic perspective. The next step was to examine the fabrics using spectroscopy to try to connect the chemical information to the written word. The terms used for dye production at the turn of the century are not those used today. So, verifying things through spectral information was our main goal.

Were there any challenges using Raman spectroscopy in the study? 

Raman spectroscopy can damage more delicate materials, including natural fibers, if the laser power is too high. So, yes, we were concerned about using Raman to examine the fabrics. We were able to find some fabric scraps from the same time period to explore different instrument settings, and to make sure we didn’t cause any burn holes. As it turned out, however, we were not able to detect any Raman signal for the dyes. This is likely due to their low concentrations. Portable X-ray fluorescence (XRF) was much easier to use, and produced much more encouraging results. The biggest challenge with the XRF was its instrument window size, which allowed us to only examine certain fabrics with larger single-dye areas in the patterns.

What conclusions were you able to draw from these findings?

We have identified some specific fabric colors that have similar elemental profiles. For example, red, maroon, and brown fabrics all produced signals for iron. This suggests the possibility of a common iron-containing chemical within these dye processes.

We need to follow up with a more careful examination of the dye recipes, and spend more time trying to link the spectroscopic information to the turn-of-the-19th-century terms and documented dye processes. Also, we had some success with Fourier transform infrared (FT-IR) microscopic analysis of a few of the dyes. While not a portable technique, the results are encouraging, and worth further efforts.

You have also studied pigments found on frescoes at various sites in Italy (1), as well as Roman glass studies (2). How did the challenge of these studies differ from the New England study?

Each different sample type has given our research team the opportunity to learn about a new cultural heritage material, and how best to approach its characterization. Each has had its own unique challenges. The fresco data were collected in a field laboratory, which had a lower level of control compared to a typical science laboratory. To better understand the Roman glasses, we needed access to instrumentation such as a micro-Raman spectrometer not available in our college’s laboratories. Collaboration with Peter Vandenabeele’s group at Gent University solved that situation.

(1) M.K. Donais, D. George, B. Duncan, S.M Wojtas, and A.M. Daigle, 

(2) M.K. Donais, J. Van Pevenage, A. Sparks, M. Redente, D.B. George, L. Moens, L. Vincze, and P. Vandenabeele, 

 is a professor of chemistry at Saint Anselm College in Manchester, New Hampshire. ●

Chemistry can help us understand the past.

Using Mobile Spectroscopic Instruments to Characterize Historic Artifacts

Laura Bush is the Editor in Chief for BioPharm International

In 2009, a group of researchers conducted a study using inductively coupled plasma–mass spectrometry (ICP-MS) to determine if heavy metal contaminants were present in pet foods (1,2). The team conducted a follow-up study in 2019, using updated cryogenic and microwave technologies for sample preparation before ICP-MS analysis. We spoke to the study’s lead author, Patricia Atkins about these investigations.

What prompted the original study (1,2) and the update?


In my role at Spex CertiPrep I am tasked with creating new and interesting research projects, I often draw from my life experiences and interests for topics. In 2009, I was a grieving pet owner. I felt that I had fed my cats the best foods, but one had died from cancer. I wondered if the food was as good as purported. This was just a year or two after the melamine scandal in pet food. I had the ability to do some testing, so I did.

Since that original study, 10 years had passed and the U.S. Food Safety Modernization Act (FMSA) had been enacted. It seemed time to revisit the study.

In the new study, we focused only on dry food, as opposed to wet and dry food of the first study. We primarily did that to unify our preparation and analysis. Our dry foods were purchased or donated by employees and ground using cryogenic milling. Each pet food was sampled three times, and run in triplicate with cleaning runs and blanks between samples. All replicates were examined by ICP-MS, and if one replicate appeared contaminated, it was either rerun or eliminated.

Did you see any significant changes since the first study? Have you changed your sample preparation or analysis method over time?

Overall, we found that the levels of heavy metals had not significantly changed in 10 years. Both dog and cat foods had higher levels of arsenic and nickel than what had been found in 2009. Arsenic in 2009 had a maximum of 290 ppb, while in 2019 we saw it up to 690 ppb. Nickel in 2009 had a maximum of 3200 ppb, but in 2019 we found up to 5900 ppb. The levels of lead overall in the 2019 samples had decreased compared to 2009 from a maximum of 5.9 ppm to 0.5 ppm. In our first study, we had surprisingly found uranium up to 0.9 ppm in our dog food samples; in this study, we have found cat and dog food samples containing up to 1.7 ppm of uranium.

Our sample preparation and analysis methods over the decade have change some with new advances in microwave and ICP-MS technologies. Our instruments are more sensitive, and see smaller amounts with the ability to filter out interferences, which in turn increases accuracy.

The first study attracted attention. Did you get any pushback from manufacturers, or any response from any governmental bodies? Do you expect any additional response from this study?

Yes, the first study did receive a lot of attention, both good and bad. I spoke with many pet food manufacturers at conferences, and while they would not publicly comment, many personally agreed with our findings. We also had the Royal Military College of Canada request our pet food samples to try analysis with a new type of instrumentation. We shared our samples, and, overall, their results corresponded with ours. Some of the governmental bodies, including the FDA, did have some feedback. I take these responses and any that may come from our current study as helpful criticism to create better studies in the future. Some requests from this current study was to bring back the wet food studies and include new frozen or refrigerated pet foods.

Have you had any regulatory group or pet food supplier criticize your work on a scientific basis?

There were a few points of contention from the FDA in our 2009 study, based upon how we chose to prepare samples and compare them to feeding amounts and regulatory limits. The criticisms focused around calculating for dry weight of wet food samples, and the amount we standardized to feed pets and using human limits for pets. So, in this study, we focused only on dry food, and used pet food manufacturer feeding guide- lines, but still kept the human reference dosage models.

(1) P. Atkins, L. Ernyei, W. Driscoll, and R. Thomas, 

(2) P. Atkins, L. Ernyei, W. Driscoll, R. Obenauf, and R. Thomas, 

A 2009 study found many heavy metals in pet food. Has anything changed?

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