Fourier Transform Ion Mobility Spectrometry - ACS Publications

of flight mass spectrometry. Ion mobility spectrometry (IMS), also known as plasma chromatography, separates atmospheric pressure gas phase ionic spec...
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Anal. Chem. 1985, 57,402-406

Fourier Transform Ion Mobility Spectrometry F. J. Knorr, R. L. Eatherton, W. F. Siems, and H. H. Hill, Jr.* Department of Chemistry, Washington State University, Pullman, Washington 99164

A mobility Interferogram Is generated when the entrance and exit gates of a two-gate ion moblllty spectrometer are simultaneously opened and closed by a frequency sweeping square wave generator. Fourier transformatlon of the Interferogram recovers the normal moblllty spectrum. A theory for the method is developed, and transformed spectra are obtained for the posltlve background reactant Ions and for l-methylnaphthalene In N, drlft gas. Potential benefHs of the method for moblllty detection In gas chromatography include rapid collection of complete mobility spectra and Increased detector sensltlvlty. The new method should be generally applicable to other tlme dlsperslve technlques such as tlme of flight mass spectrometry.

Ion mobility spectrometry (IMS), also known as plasma chromatography, separates atmospheric pressure gas phase ionic species on the basis of their mobilities ( 1 ) . The importance of IMS for analytical chemistry derives from its potential as a versatile and ultrasensitive detector for trace organics (2). Since the first use of IMS for gas chromatographic detection (IMD) (3), emphasis has shifted from qualitative analysis via complete mobility scans of peaks to quantitative determinations using various selective and nonselective continuous mobility monitoring modes (4). Now that design changes in the IMD have made it compatible with high-resolution capillary columns (5), even the fastest IMS data collection technique is too slow to obtain a complete mobility spectrum of a single chromatographic peak. Currently there are three methods of recording ion mobility spectra (2)--single scan, signal averaging, and moving second gate. In all three methods an entrance gate is pulsed open for a short time admitting ions to the drift region. In the single scan method the mobility spectrum, typically a 20-ms wave form, is monitored directly with an oscilloscope. Noise levels are severe and the method is unusable with high-resolution chromatographic separations. In the signal averaging method many single scans are summed with a computer. Generally 500-1000 repetitions are required for acceptable S I N levels, so 10-20 s are needed to generate an ion mobility spectrum. This is an order of magnitude too slow for high-resolution chromatography. In the moving second gate method an exit gate, located a t the end of the drift region, is repeatedly pulsed open with a particular phase delay relative to the entrance gate. An electrometer with its time constant set too long to track high-frequency noise or individual ion pulses, measures the average ion current. An ion mobility spectrum is generated by slowly sweeping the phase delay of the exit gate. In general it is difficult to obtain moving second gate spectra with acceptable S I N in less than 1 or 2 min. None of these three methods make efficient use of the available ions. With typical entrance pulse durations of -0.2 ms, only about 1%of the available ions can contribute to the mobility spectrum. Furthermore, in the moving second gate method with exit gate durations also -0.2 ms, on the average only about 1% of the ions which pass the entrance gate contribute to the mobility spectrum. Opening the gates for longer periods of time increases the signal but lowers the 0003-2700/85/0357-0402$01.50/0

resolution of the mobility spectrum. In this study an alternative Fourier transform (FT) operating mode for a two-gate ion mobility spectrometer is presented. The potential of this method, in which 25% of the available ions contribute to the measured signal, was evaluated with respect to sensitivity, scan time, and resolution. The minimum scan time so far achieved with the F T mode is 10

-

S.

THEORY A two-gate ion mobility spectrometer (5, 6 ) modified to operate in the FT mode is shown schematically in Figure 1. The drift tube assembly is unchanged from the normal instrument. The F T instrument differs from the normal spectrometer in four ways: (1)the gating signal generator produces a binary (on, off) square wave rather than a train of narrow pulses; (2) the entrance and exit gates are always driven simultaneously by the same square wave, with zero phase delay; (3) the scanning parameter is the square wave frequency rather than phase delay; and (4)the F T IMS interferogram is recorded with a microcomputer which also performs Fourier transformation of the data to recover the normal ion mobility spectrum. Gating Correlation Function. In both normal and FT mode operations of a two-gate spectrometer, a particular gate timing sequence is repeated many times before the scanning parameter is changed. The time constant of the damped picoammeter is too long to follow individual ion pulses or high-frequency noise. Its output represents the time averaged dc ion current at the present value of the scanning parameter. The gates themselves act to filter the ions streaming through the drift tube. Depending on the characteristic transit times of the different ions present and the actual gate timing sequence, some ions will reach the detector with maximum intensity, some with intermediate intensity, and some will not reach the detector a t all. The filtering and time averaging may be represented by a gating correlation function

where e ( t 3 is the entrance gate function, f(t? is the exit gate function, and T is the time constant of the detection electronics. The gate functions e(t? and f ( t ?represent the on-off action of the gates in real time, whereas the domain of t(t) is ion transit time. t ( t ) is a correlation function in the mathematical sense of the term (7). A value of t(t) represents the fraction of ions having transit time t that reach the detector. If a sample having the ion mobility spectrum m(t)is presented a t the entrance gate, the detected signal is

S = l m ( t )t(t) dt That is, the intensity of ions with transit time t , rn(t),is multiplied by the fraction of these ions which reach the detector and summed over all transit times to yield the detector signal. In both the normal and FT modes the gate functions have a characteristic periodicity (frequency u , period T = u-*) and 0 1985 American

Chemical Society

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Dr f t

ANALYTICAL CHEMISTRY, VOL. 57, NO. 2, FEBRUARY 1985

T m t

0;

53-wi

Control

=

1

_ _ _ - _

Electronics

and

403

F C’I

Ertrance Gat?

Gate Driver Ex t Gate

~

Time E ectrorneler

F a s t ADC S t o r a g e Scope

Transit Time

Figure 3. (a)Typical entrance and exit gate functions, FT mode. (b) Typical gating correlation function, FT mode.

Figure 1. Schematic diagram of the FT IMS apparatus. 7

-

height. On the other hand, if m ( t ) is an actual diffusion broadened spectrum, in the limit as w o 0

a

t(t, At)

0

-

wo

r [6(t - A t )

+ 6 ( t - (At +

Time

Transit Time

Figure 2. (a) Typical entrance and exit gate functions, normal mode. (b) Typical gating correlation function, normal mode.

a characteristic phase delay ( A t ) . In a normal scan frequency is held constant and phase delay is swept, while in an FT scan phase delay is held at zero while frequency is swept. In both cases the scanning parameter generates a family of gating correlation functions. In what follows t(t) will be labeled by the parameter of which it is a function. Normal Mode. Figure 2a shows typical gate functions for the normal mode and shows how they are characterized by a period T , phase delay A t , and gate open time wg. Figure 2b shows the corresponding correlation function t(t, At). Although only the positive part of the function is shown, strictly it extends into the negative transit time region with the same periodicity. The peaks in &, A t ) are triangular as is expected for the correlation of rectangular pulses. As an example of how to interpret ~ ( tA,t ) , the cutoff point on the low transit time side of the fiist peak is associated with fast ions that pass through the entrance gate just as it closes and pass through , the exit gate just as it opens. The maximum values of ~ ( tAt) are equal to w o / T , the fraction of time that the entrance gate is open. The signal obtained by scanning At may be written

S(At)= J m ( t )

t(t, At) d t

(3)

Peaks in beyond the first do not contribute to the measured signal unless some ion in the sample has a transit time longer than the gate period 7,a situation which is generally avoided. In the absence of broadening by diffusion and other nongate effects, m(t)is a series of 6 functions and the signal predicted by (3) is a series of triangular peaks, all of width woat half

+

6(t - ( A t -t 27)) + s(At)

I

T))

WO

+

-m(At)

...I

(4) (5)

T

FT Mode. Figure 3 illustrates the simultaneous square wave entrance and exit gate functions. Figure 3b shows the positive half of the corresponding gating correlation function. Since the gate functions are equal, t(t, u ) is an autocorrelation function, an even function with a negative transit time half mirroring the positive half shown. The maximum value of t(t, v ) is 0.5, the fraction of time the entrance gate is open. Again the correlation function represents the filtering action of the gates. With a gate modulation frequency u , the only ions that reach the detector with full intensity have transit times 0, l / v , 2 / v , 3/u, ... . The only ions which do not reach the detector a t all have transit times 1 / 2 u , 3 / 2 u , 5 / 2 v , ... . The signal obtained by scanning the square wave frequency is

S(u) = J m ( t )

4, u ) dt

(6)

where the integral is over all drift times. To imagine the general form to expect for S(u),suppose the mobility spectrum consisted of a single 6 function of intensity 1, at transit time t. As v is increased, t(t, v ) remains a triangle wave, but collapses accordion fashion toward the origin. Then S(v)is itself a triangle wave with maxima and minima Y = 0, l / t , 2 / t , 3 / t , ... s(u),,, = 0.51,

S(V),~,= 0

u = 1/2t, 3/2t, 5/2t,

...

(7)

If m(t)is a sum of 6 functions, S(u) will be a sum of interfering triangle waves. It should be anticipated at this point that in real situations these triangle waves will not continue to oscillate between extremes of 0 and 0.51, as u increases. Diffusional broadening of the ion pulses will subtract intensity from the maxima and add it to the minima until at some frequency S(v) will be indistinguishable from a steady dc level Of

0.251,.

F o u r i e r Transformation. The form of eq 6 suggests that S(v) and m ( t ) are “+transforms” of one another. However, since fast FT programs are readily available, we shall consider Fourier transformation of S(u). Since t(t, u ) is the autocorrelation of a periodic function, it is itself an even periodic function with period l/v. Therefore ~ ( tu ), may be expanded in a Fourier series to which only the

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cosine terms make nonzero contributions. The expansion coefficients are found t o be A , = 1/4; An = 0 ( n = 2, 4,6, ...)

2 A , = - (TI = 1, 3, 5 , ...)

(8)

x2n2

and the FT IMS signal may be written

2 S(v) = L j m m ( t ) d + t 4

L J m m ( t ) cos 2xnvt d t

a2n=1,3.5. ...n2

0

(9)

’t

Identifying Io = J m ( t )d t and changing variables in the higher cosine terms give

1 4

S(v) = -I,

2 +c L j m m ( t / n )cos 2avt d t a2n=1,3,5... n3 0 =

1 4

-I,

1 1 + -E--F,m(t/n)

n3

x2

1 -10

4

2 6(t)+ -

c

1 -m&/n)

(13)

-

=

e-idvl+uz)t

[F8(v)sinc ((v2 - vl)t)]

(14)

Thus the transform is shifted inphase and broadened by convolution with the sinc function. The experimental trace we finally extract is the positive part of the magnitude of the transform

1

IFS(v),,,I+ = -m(t)* b x*

1 + ---m(t/3)* 27x2

b

5

6

must be recovered from the interferogram. As in previous work the detector signal was amplified with a Keithley 417 high-speed picoammeter (Keithley Instruments, Cleveland, OH). In both normal and F T mode experiments the damping control of the instrument was set to give a bandwidth of -7 Hz. Data from both the normal and FT modes were collected with an Apple 2e microcomputer equipped with an Applescope data collection system (RC Electronics, Santa Barbara, CA). Essentially, the Applescope is a microcomputer emulation of a digital signal analyzer incorporating a modified tracking type 8 bit ADC with a 3.5-MHz maximum sampling rate. The Fourier transforms were obtained by using the SDL-001 Spectrum Analysis Software option (RC Electronics, Santa Barbara, CA). Interferograms were collected as 1024 points, the maximum number of points possible to use with the spectrum analysis software. Ion Mobility Studies. In order to compare the performance of the two data collection techniques, ion mobility spectra were obtained for the background reactant ions and l-methylnaphthalene using both the normal time dispersive and the FTtechniques. A stainless steel sample holder containing the 1methylnaphthalene was attached to the branch of a in. “tee” fitting inside the oven of a gas chromatograph. The tee fitting was connected to an unused injection port which supplied a flow of nitrogen gas. The nitrogen passed through the fitting, sweeping 1-methylnaphthalenevapors into a short length of noncoated fused silica transfer line used to connect the sampling apparatus to the ion mobility spectrometer. The amount of compound entering the IMS was controlled by setting the nitrogen head pressure and temperature of the GC oven. A concentration on the order of 1 ppm 1-methylnaphthalene was used. Operating parameters of the IMS common to all experiments were as follows: ion drift length, 7.60 cm; electric field gradient, 239 V/cm; gate voltage, A30 V; temperature, 150 “C; pressure 691.2 torr (702.3 torr for 1-methylnaphthalene study). Drift and makeup gases were both prepurified nitrogen (Liquid Air, Inc., San Francisco, CA). Gas flow rates were drift gas 600 mL/min and makeup gas 20 mL/min. 1-Methylnaphthalene (Chem Service, Inc., West Chester, PA) was used “neat”for the continuous bleed experiment.

where II is a rectangle function of value unity in the scan range v1 v2 and zero outside it. Before transforn_lation the dc level ~ ~ .the is subtracted, leaving the ac component S ( U ) ~Since tranform of 11 is a sinc function (7) the FT of eq 13 is taken &(v)erp

L

IkHzl

(11)

where mE(t) is the even part of m(t). Experimentally, all of S(v) is not measured. In practice scans begin at a few tens of a hertz and extend into the kilohertz range. The actual measured signal is

s(v),,p = S(v) Wl, v2)

3

Frequency

Figure 4.

(12)

x 2n=1,3,5 ...n3

2

(10)

where F, stands for the cosine transform. The FT IMS signal is nearly equal to the 0.251, dc level plus the cosine transform of the mobility spectrum. However, since ~ ( tv ), is in fact a triangle wave, the signal includes minor contributions from odd overtones of the ion mobility spectrum. The n = 3 term has 1/27ththe intensity of the n = 1 term. Fourier transformation of eq 11 yields

FSb) =

1

+ ... (15)

where b = Jsinc ( v 2 - u l ) t J .

EXPERIMENTAL SECTION Modification of the Ion Mobility Spectrometer. Design and construction of the ion mobility spectrometer with a 63Ni ionization source have been previously reported (5,6). This design was used to obtain results in the normal mode. For the Fourier transform mode, the AIM 65 microcomputer (Rockwell International, Anaheim, CA) was replaced by a H P 3325A synthesizer/function generator (Hewlett-Packard, Palo Alto, CA). It was operated in its square wave mode a t an output level of 5 V peak to peak with a 2.5-V offset to create the proper logic levels required to trigger the gate driver. The output was connected to both inputs of the gate driver in order to drive both gates at the same frequency. The frequency scans were accomplished by using the function generator in its single linear sweep mode. The initial frequency of 10 Hz was chosen to lie outside the bandwidth of the electrometer. The frequency range was selected to produce less than 0.2-ms peak broadening. Square wave scan rate R (Hz s?) were chosen to be less than f ~ / t - ,where f~ is the electrometer bandwidth in Hz and t , is the longest transit time (0.020 s) which

Mobility interferogram, positive background reactant ions: square wave scan range, 10-6000 Hz; total scan time, 36 s.

RESULTS AND DISCUSSION Interferograms and Transforms. Figure 4 shows a typical mobility interferogram, in this case for the positive background reactant ions formed in the N, drift gas. The triangular wave form conforms to the predictions of eq 6 and 7 . As anticipated the wave form is damped a t high frequencies because of diffusional broadening of the ion packets. If the IMS spectrum m ( t ) is taken to be a 6 function spectrum broadened by convolution with some function d ( t ) that describes the diffusion, then in the transform domain S(u) is modulated by multiplication with D ( v ) ,the transform of d ( t ) . In particular, if m ( t )is convoluted with a Gaussian function of width u = wd, then S ( V )will be damped by a Gaussian envelope of width u = 1 / t u d . For the interferogram of Figure

ANALYTICAL CHEMISTRY, VOL. 57,NO. 2, FEBRUARY 1985

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I

5

5

15

10 D r i f t Time

Figure 7. FT mode spectrum,

L

._.. --.-

5

15

10 Drift Time

20

(rnsl

Figure 6. FT mode spectrum, positive background reactant ions: obtained by transformation of interferogram in Figure 4;reduced mobilities, 2.93,2.80,2.54 cm2 V-l s-'.

4 the difference between the maxima and minima has decreased by a factor of 2 at about 2.0 kHz, so we can estimate 0.25 ms. the diffusional broadening as t d Figure 5 is a normal mode mobility spectrum of the positive background reactant ions. Noise is evident in the normal mode scan because the signal levels are lower than those in Figure 4. The scan in Figure 5 is about as rapid as possible with the normal mode. The bandwidth of the electrometer is such that faster scans would begin to distort and broaden the peaks. Increasing the bandwidth would increase the noise levels and swamp the minor peaks. Figure 6 is the result of transforming the interferogram of Figure 4. Aside from the broad band at 0-1 ms, it is equivalent to the normal mode spectrum. Transit times of the peaks correspond and the minor peaks are well-resolved. The 0-1 ms band corresponds to a slow decrease in the dc level of the interferogram. We attribute this to a "gate depletion effect"-a lower concentration of ions just outside the entrance gate due to the high electric field of the gate. At low square wave frequencies, sampling extends deep into the reaction region, but a t high frequencies the depleted region supplies a larger proportion of the sample. This interpretation was supported by experiments in which the gate voltage was varied. When the differential voltage on the gate wires is increased to f45 V, the drop in dc level at high frequencies becomes much more noticeable and the low drift time band in the interferogram increases in intensity. In normal mode mobility spectra peaks are broadened by ion diffusion and by the gate width w,,.To increase resolution to the diffusion controlled limit, womust be decreased with a proportional loss in signal strength (see eq 5 ) . Thus in the normal mode there is a trade-off between resolution and sensitivity. The FT mode spectrum is affected by diffusion broadening to the same extent as the normal mode. However the instrumental contribution to the peak broadening arises not from the gate width but from the frequency range scanned (see eq 15). The diffusion controlled limit is approached by

-

15

20

D r i f t Time lrnsl

Ims)

Figure 5. Normal mode spectrum, positive background reactant ions: total scan time, 54 s; T = 20 ms; w o = 0.15 ms; reduced mobilities 2.95,2.79,2.55 cm2 V-' s-I.

\--

10

20

-

1 ppm 1-methylnaphthalene,in N, drift gas: square wave scan range, 10-6000 Hz; total scan time, 36 s; reduced mobility of major product ion, 1.99 cm2 V-' s-'.

scanning a wider range of frequencies, which may be done without loss of signal. Thus an advantage of the F T method is that there is no trade-off between resolution and sensitivity. Comparing the half height widths of the major peak in Figures 5 and 6 shows the two to be indistinguishable. This is as expected since wo= 0.15 ms and ( u 2 - ul)-l = 0.17 ms. Equation 15 predicts a satellite spectrum of 1/27threlative intensity with transit times corresponding to the major spectrum multiplied by three. Thus we expect to see a small peak at about 22 ms. The full transform of Figure 4,which has information about drift times out to -42 ms, does have a small peak at 22 ms with intensity about that predicted by the theory. Figure 7 is the FT mode mobility spectrum obtained by continuously bleeding 1ppm 1-methylnaphthalene into the IMS apparatus. It is equivalent in transit times, peak widths, and relative intensities to the normal mode spectrum. Thus it appears that the FT mode is capable of recovering complex mobility spectra. Rapid Scanning. An 18 s scan, with all other parameters including the -7 Hz electrometer bandwidth equal to those for Figure 4,yielded a mobility spectrum virtually identical with that of Figure 6. This is about as rapid a scan as possible with the 7-Hz bandwidth. With faster scans the electrometer is too slow to track the interferogram component of an ion of 0.020 s transit time. If f E is the electrometer bandwith in Hz and R is the square wave scan rate in Hz s-l, then

-

where t,,, is the longest transit time that can be accurately recovered by Fourier transformation of the inteferogram. Using bandwiths wider than 7 Hz, mobility spectra of positive background reactant ions have been obtained with scan times under 10 s. The transformed spectra have lower intensity than those in Figure 6, but the transit times and peak widths are unchanged. T o obtain mobility spectra of high-resolution chromatographic peaks, scan rates perhaps as high as 10 kHz s-l and an electrometer bandwidth of 200 Hz would be needed. The potential for rapid scanning of high-resolution chromatographic peaks via the the F T method arises from the signal levels obtained and the multiplex advantage. The A signal levels are high enough to reduce concern about noise problems and amplifier speed. Also, since the interferogram is a multiplex signal, changing sample concentration in the IMD should result in a low-frequency modulation of the interferogram but not distortion of relative intensities of peaks in the spectrum. On the other hand, the multiplexing may result in the loss of low-intensity peaks in the transform, a problem common to other FT methods. The recovery of minor peaks in Figures 6 and 7 is encouraging in this regard. With scan rates as high as 10 kHz s-l an assumption implicit in our interpretation of eq 1 breaks down. The assumption is that during the time it takes ions to traverse the drift region

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Anal. Chem. 1985, 57. 406-411

the square wave frequency does not change appreciably. This condition is well met in the work reported here, but it would not be correct a t all with very fast scans. Preliminary experimental and theoretical work indicates that in very fast scans individual interferogram components lose intensity and are shifted in phase by amounts determined by transit time and scan rate, but that the FT method is still valid. However, further theoretical and experimental investigations are needed before very rapid scanning can be employed. Other Applications. Although this work centers on FT IMS, the same general approach is applicable to any time dispersive technique. A time dispersive technique separates the components of a mixture on the basis of propagation times of the individual components through some medium. In addition to IMS, time dispersive techniques include chromatography, electrophoresis, time of flight mass spectrometry, TOF spectrophotometry, RADAR, and LIDAR. TOF mass spectrometry in particular could benefit from the FT method. In any appication the essential elements of the FT method are (1)modulation of the source (or injector or transmitter) by a continuous frequency rather than a narrow pulse, (2) multiplication of the detected signal by the source modulation function and long time constant averaging of the product function, (3) obtaining a signal S(v) by sweeping the modulation frequency, and (4) recovering the time dispersed signal as normally measured by calculating the magnitude of the FT of S(v). In a particular application the potential benefits of the FT method would arise from one or more of the following:

(1) increased duty cycle of the sample source, which could be used to increase signal levels, increase sensitivity, or speed data collection, (2) reduction of measurement broadening without loss of sensitivity, (3) multiplexing, since signals from all components of a sample are detected simultaneously, or (4) reduction of need for fast detection and recording electronics, since the recording electronics need be at most only as fast as the sweep of the modulation signal. ACKNOWLEDGMENT We wish to express our appreciation to Steven D. Brown and John M. Frame for helpful discussions. LITERATURE CITED Cohen. M. J.; Karasek, F. W. J . Chromatogr. Sci. 1970, 8 , 330. Hill, H. H.. Jr.; Baim, M. A. I n "Plasma Chromatography"; Carr, T. W., Ed.; Plenum: New York, 1984; p 143. Karasek, F. W.; Keller. R. A. J . Chromatogr. Sci. 1972, 10, 626. Karasek, F. W.; Hill. H. H., Jr.; Kim, S. H.; Rokushika, S. J. J . Chromatogr. 1977, 135. 329. Baim, M. A.; Hill, H. H., Jr. Anal. Chem. 1982, 5 4 , 38. Baim, M. A,; Eatherton, R. L.; Hill, H. H., Jr. Anal. Chem. 1983, 55, 1761. Bracewell, R. N. "The Fourier Transform and Its Applications", 2nd ed.; McGraw-Hill: New York, 1978; Chapters 3 and 4.

RECEIVED for review July 23,1984. Accepted October 19,1984. This work was supported in part by a grant from the Public Health Service. The work was presented in part at the Northwest Regional Meeting, American Chemical Society, June 8. 1984.

Tree Ring Wood Analysis after Hydrogen Peroxide Pressure Decomposition with Inductively Coupled Plasma Atomic Emission Spectrometry and Electrothermal Vaporization Henryk Matusiewicz' and Ramon M. Barnes*

Department of Chemistry, University of Massachusetts, Amherst, Massachusetts 01003-0035

A method utlllzlng pressure decompodtlon to mlnhnlze sample pretreatment Is described for the lnductlvely coupled plasma atomic emlsslon spectrometric analysis of red spruce and sugar maple. Cores collected from trees growlng on Camels Hump Mountain, Vermont, were dlvided Into decade lncrements In order to monltor the temporal changes In concentrations of 21 elements. Dried wood samples were decomposed In a bomb made of Teflon wiih 50% hydrogen peroxlde heated In an oven at 125 OC for 4 h. The dlgestlon permitted use of aqueous standards and mlnlmlzed any potentlal matrlx effects. The element concentrations were obtained sequentlally by electrothermal vaporlratlon ICP-AES uslng 5 pL sample allquots. The method preclslon varied between 3 and 12%. Elements formlng oxyanlons (AI, As, Fe, Ge, Mn, SI, V) were found at elevated concentratlons durlng the most recent three decades, whlle other metal (e.g., Mg, Zn) concentrations were unchanged or decreased.

Many studies have been carried out to investigate the uptake of various elements by plants, especially in forest ecoOn leave from Technical University of Poznafi, Department of Analytical Chemistry, 60-965 Poznaii, Poland. 0003-2700/85/0357-0406$01 S O / O

systems (1). Tree rings, which represent a chronological record of elemental changes that are not contaminated naturally by outside sources like lake-core sediments or glacial cores, can be considered indicators that record environmental disturbances. The occurrence of elevated trace and especially toxic metals concentrations in accurately dated tree-ring sequences from trees in certain regions is closely linked to environmental effects (e.g., acid rain), and these rings represent records of environmental influence during the past several years ( 2 ) . Thus, analysis of tree rings for metals is an important indicator of atmospheric pollution. Some effort has been devoted recently to detecting the presence of heavy metals in wood (3-16). A new method of sample preparation for cellulose materials was sought in this research that would be applicable to wood and yield a solution from which elements could be determined by inductively coupled plasma atomic emission spectrometry (ICP-AES). Bomb digestion with hydrogen peroxide was evaluated because it provides a relatively rapid means of decomposition that assures complete recovery of elements in tree ring wood. Analysis for trace and major elements in solid samples generally requires decomposition of the organic matter followed by dissolution leading to a solution for subsequent analytical determination. This ashing may be achieved by 0 1985 American Chemical Society