3.1. Kinetics of chlorophyll demetallation in microdroplets

Figure 1 a presents the acid-induced demetallation of chlorophyll a to form phaeophytin. The central Mg²⁺ ion in chlorophyll a is substituted by two hydrogen ions at high hydrogen ion concentration. ESI mass spectra of chlorophyll a before and after adding 35 mM HCl are shown in Figs 1 b and 1c. The chlorophyll a without treating with HCl exhibited a protonated mass peak ([M + H⁺]⁺) at m/z 893·53 with a sodiated peak ([M + Na⁺]⁺) at m/z 915·52. The chlorophyll a with potassium adduct ([M + K⁺]⁺) was observed at m/z 931·50. An oxidized species at m/z 925·53 was detected in a relatively low intensity. Chlorophyll a after treating for 20 min with 35 mM HCl exhibited a protonated phaeophytin mass peak ([M−Mg²⁺ + 2H ⁺ +H⁺]⁺) at m/z 871·57. Negligible molecular species with sodium and potassium adducts were detected in the demetallated chlorophyll a with HCl treatment. The high hydrogen ion concentration drove a major portion of formed ions to the protonated species. It is to be noted that oxidized peaks observed in intact chlorophyll a also disappeared in demetallated chlorophyll a, suggesting that acid-induced demetallation interferes with oxidation.

Fig. 1. (a) Reaction scheme of acid-induced demetallation of chlorophyll to form phaeophytin. Mass spectra of chlorophyll a, (b) before and (c) after adding 35 mM HCl.

The kinetics of chlorophyll a demetallation was recorded using microdroplet fusion mass spectrometry (Fig. 2). The two microdroplet streams containing chlorophyll a solution at 40 µM in methanol and aqueous HCl solution at concentrations that range from 0 to 50 mM were crossed to cause microdroplet fusion. The fused microdroplets traveled at a relatively constant speed of about 84 ± 18 m s⁻¹ and entered into the heated capillary inlet of the mass spectrometer where reactions were stopped. The reaction time in the fused microdroplets at a mean size of 14 ± 6 µm was controlled by adjusting the traveling distance x between the droplet fusion region to the mass spectrometer inlet. For 3 µs temporal resolution, the distance x was increased by 250 µm using a manual micro-positioner. Mass spectra of chlorophyll a with HCl at the final concentration of 35 mM at different distance x were provided in Fig. 2. The signal intensity at m/z 893·53 corresponding to chlorophyll a (Chl a) decreased while the signal intensity at m/z 871·57 corresponding to phaeophytin (Phe) increased as the distance x increased. The reaction time was calculated by integrating the speed of fused droplet over distance x as provided in our previous work (Lee et al. Reference Lee, Kim, Nam and Zare2015b).

Fig. 2. Experimental setup for chlorophyll demetallation kinetics using microdroplet fusion mass spectrometry.

Fig. 3. Mass spectra of chlorophyll a at different traveling distances of fused microdroplets. The intensity of chlorophyll a decreases, whereas the intensity of phaeophytin a increases as the traveling distance x, as defined in Fig. 2, and the corresponding reaction time t in the fused microdroplets increases.

The demetallation kinetics is first order in [Chl a] and second-order in [H⁺], so that

(1) $$d[{\rm Chl}\;a]/dt = - k[{\rm Chl}\;a][{\rm H}^ + ]^2, $$

where k denotes the reaction rate constant, respectively. Because the H⁺ concentration is in great excess compared with the concentration of Chl a, we replace k[H ⁺ ]² by k _app, and integrate Eq. (1) to yield the expression

(2) $$[{\rm Chl}\;a]_t = [{\rm Chl}\;a]_0 \exp ( - k_{{\rm app}} t).$$

In other words, the normalized signal intensity of chlorophyll a divided by the initial intensity of chlorophyll a follows a simple exponential decay function as a function of reaction time, which is the distance x divided by the microdroplet velocity (Fig. 4). The signal intensities at different distances x were normalized to the total ion current at each position to compensate for a signal loss caused by dispersion of fused microdroplets. The normalized chlorophyll a signal was fitted to an exponential decay curve shown by the red curve in Fig. 4. We expected evaporation of a fraction of solvent in the fused microdroplets, while they were traveling to the mass spectrometer inlet. However, a good fit to an exponential decay (R ² = 0·98) suggests that evaporation was minimal and played a negligible role in determining the kinetics.

Fig. 4. Kinetics of chlorophyll a demetallation recorded with microdroplet fusion mass spectrometry. The red line is the best fit to an exponential decay curve. EIC = extracted ion current.

The rate constant k of chlorophyll demetallation measured in microdroplets was 46 ± 6 mM⁻² s⁻¹. The reported rate constant measured in bulk solution is 0·048 ± 0·002 mM⁻² s⁻¹ (Wilson & Konermann, Reference Wilson and Konermann2003). Thus, the reaction rate constant in microdroplets is estimated to be 960 ± 120 times greater than the one measured in bulk solution. The apparent rate constants of chlorophyll a demetallation k _app measured at different concentrations of H⁺ are depicted in Fig. 5. The data fit well a quadratic curve (R ² = 0·96), as expected. The approximately thousand-fold acceleration was found to be constant regardless of the H⁺ concentration in the microdroplets. It is noted that there was a sizable rate of demetalation in microdroplets, even when no HCl was added. This behavior is discussed below in terms of enhanced H⁺ concentration on the surface of the microdroplets.

Fig. 5. Apparent rates of acid-induced chlorophyll a demetallation at different concentrations of hydrogen ion. The red line is the best fit to a quadratic dependence on [H⁺].

3.2. Factors influencing reaction acceleration

Several candidates are thought to be responsible for the reaction rate acceleration in microdroplets. These include charge, localization of reactants at the interface, charge separation, micro-confinement, electric field and evaporation of solvent (Bain et al. Reference Bain, Pulliam, Ayrton, Bain and Cooks2016; Banerjee & Zare, Reference Banerjee and Zare2015; Lee et al. Reference Lee, Banerjee, Nam and Zare2015a; Li et al. Reference Li, Yan and Cooks2016; Yan et al. Reference Yan, Bain and Cooks2016). We address the mechanism of this reaction acceleration by characterizing several factors among these candidates causing the reaction acceleration. First, we examined the effect of varying the voltage between 0 and 5 kV. The change in reaction rate acceleration in microdroplets compared to bulk solution is plotted as a function of the voltage in Fig. 6. The acceleration factor was about 600 without applying voltages to the microdroplets. The acceleration increased as the applied voltage increased. At 0·5 kV, the change in acceleration became almost saturated, meaning the introduced charge density at the surface of the microdroplets were almost saturated at the voltage as low as 0·5 kV. It should be noted that there was a considerate reaction acceleration occurring even without applying voltage to the microdroplets. This result suggests that a major portion of acceleration originates from other factors.

Fig. 6. Effect of voltage applied to microdroplets on reaction rate acceleration factor compared with that in bulk solution.

We then studied the effect of different solvent composition on the reaction acceleration. We measured demetallation rate constant in microdroplet with a different solvent mixing composition between water and methanol. The vapor pressure of water and methanol at 20 °C is about 17·5 and 98 torr. Therefore, the liquid in the microdroplets containing 70% methanol are expected to evaporate more rapidly than the microdroplets containing 30% methanol. The faster evaporation should lead to the increase of concentration of reactants, consequently, the increase of measured rate constant. The reaction rates increased by only about 20% as the percentage of methanol increased from 30 to 70% (Fig. 7). This behavior suggests that the influence of solvent evaporation was not significant.

Fig. 7. Effect of solvent composition on the demetallation rate of chlorophyll a. MeOH denotes methanol.

3.3. Different kinetics between chlorophyll a and b

We compared the demetallation kinetics between chlorophyll a and b to assess the effect of different chemical structures on reaction acceleration in microdroplets. Figure 1 b and c show the different chemical structures of chlorophyll a and b. A methyl group on the chlorin ring in chlorophyll a is replaced by a CHO group in chlorophyll b. Different side chains in chlorophylls exhibit different properties including absorption, redox potential, fluorescence, demetallation kinetics, etc. (Saga & Tamiaki, Reference Saga and Tamiaki2012). Chlorophyll b is more stable than chlorophyll a against proton attack (Hirai et al. Reference Hirai, Tamiaki, Kashimura and Saga2009). Therefore, the demetallation kinetics of chlorophyll b is known to be slower than chlorophyll a.

The kinetics of chlorophyll a and b in microdroplets were measured using microdroplet fusion mass spectrometry under the identical conditions of 40 µM chlorophyll concentration, 35 mM HCl concentration, and an applied voltage of 5 kV. Table 1 summarizes the comparison between chlorophyll a and b. The measured rate constant of chlorophyll b demetallation was lower than chlorophyll a, which is consistent with the literatures (Hirai et al. Reference Hirai, Tamiaki, Kashimura and Saga2009). However, the change in acceleration in microdroplets for chlorophyll b as a function of the H⁺ concentration was greater than chlorophyll a, suggesting that in the microdroplet environment chlorophyll b might be more susceptible to H⁺ attack.

Table 1. Comparison of demetallation rates between chlorophyll a and b in microdroplets. The kinetic measurements were conducted in fused water:methanol (1:1, v/v) microdroplets containing 35 mM HCl and 40 µM chlorophylls under 5 kV spray condition

^a Data taken from (Wilson & Konermann, Reference Wilson and Konermann2003).

^b Data taken from (Gerola et al. Reference Gerola, Tsubone, Santana, De Oliveira, Hioka and Caetano2011; Mazaki et al. Reference Mazaki, Watanabe, Takahashi, Struck and Scheer1992).