{Zdravko Stoynov – the scientist who created new scientific horizons}


http://dx.doi.org/10.5599/jese.775   65 

J. Electrochem. Sci. Eng. 10(2) (2020) 65-78; http://dx.doi.org/10.5599/jese.775  

 
Open Access: ISSN 1847-9286 

www.jESE-online.org 
Review 

Zdravko Stoynov – the scientist who created new scientific 
horizons 

Daria Vladikova 

Institute of Electrochemistry and Energy Systems, Bulgarian Academy of Sciences,  
10 Acad. G. Bonchev St., 1113 Sofia, Bulgaria 

Corresponding author: d.vladikova@bas.bg 

Received: January 7, 2020; Accepted: January 14, 2020 
 

Abstract 
This paper is in the memory of the big Bulgarian scientist Professor Zdravko Stoynov. An 
original and non-standard personality with the spirit of a gentleman, he turned all that he 
touched into a masterpiece. His innovative thinking which made him one of the world’s 
leaders in Electrochemical Impedance Spectroscopy, chiseled away at the scientific taboos 
and created new scientific horizons. Zdravko Stoynov left us an abundant heritage – his 
spirit, his interminable capacity to wonder, his developments and inventions – all that he 
has taught us and brought up with. It has no dimensions but rather carries a unique value. 

Keywords 
Electrochemical impedance spectroscopy; 4-D analysis; rotating Fourier transforms; differen-
tial impedance analysis; differential resistance analysis. 

 

About Zdravko Stoynov 

Zdravko Stoynov left our world abruptly – engulfed in the ebullience of his latest series of 

advanced inventions. However, he left us an abundant heritage – his spirit, his interminable wonder 

and scientific curiosity which gave birth to remarkable developments and inventions which we must 

preserve, cherish, and augment. An original and non-standard personality with the spirit of a 

gentleman, he turned all that he touched into a masterpiece. His innovative thinking often made 

him feel like a scientific loner. Some of his developments were highly evaluated only 15-20 years 

after their invention, while others are still waiting to be accepted and implemented. 

At the age of 24, Zdravko Stoynov builds the first in Bulgaria analog computer to calculate 

differential equations to the 12th order. For over half a century right until his passing, he continues 

to create and develop algorithms & solutions, which he integrates into his nonstandard equipment, 

to unveil new key phenomena in electrochemical power sources – the primary zone of his 

professional interest. 

http://dx.doi.org/10.5599/jese.775
http://dx.doi.org/10.5599/jese.775
http://www.jese-online.org/
mailto:d.vladikova@bas.bg


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Zdravko Stoynov’s scientific achievements are not only numerous and significant, but also cross 

between different disciplines to redefine problems outside normal boundaries and reach solutions 

based on a new understanding of complex processes - a novel approach in modern science which 

usually involves different teams of scientists from diverse backgrounds and fields. Zdravko Stoynov’s 

research combined electrochemistry with engineering, mathematics, computer sciences… he suited 

the equipment he created to his experimental goals – from the development of unique hardware 

and software to original methods for data analysis. For deeper insight into the underpotential pre-

nucleation of Ag on dislocation free surface of single crystal face which could be observed in 

potential range 2-6 mV, he constructed an ultra-sensitive potentiostat with a voltage range of 10 

mV and precise control, stability and sensitivity of the potential, thus ensuring amplitude of the AC 

signal of 0.05 mV. His precise equipment and methodology were able to register impedance of a 

single dislocation. 

Zdravko Stoynov’s extensive inter-disciplinary knowledge and skills are reflected in his academic 

degrees: Ph.D. in engineering (automation of the experiment) from the Bulgarian Academy of 

Sciences (BAS), Doctor of Technical Sciences (Technical Cybernetics) from Swiss Federal Institute of 

Technology Zurich, and Doctor of Chemical Sciences from BAS.  
 

 
2010:  Zdravko Stoynov in his cabinet as director of the Institute of Electrochemistry and Energy Systems, 

BAS, Sofia, Bulgaria 

There is an unavoidable question put by many of Zdravko Stoynov’s colleagues: what is the source 

of such limitless scientific curiosity and inexhaustible constructive energy to define new topics and 

undertake seemingly insoluble problems, transforming them into fertile and attractive research 

fields? The answer can be found in the words of the renowned physical chemist Ivan Stransky: “A 

scientist must possess the capability to wonder. He has to see voids where others see nothing. ” 

These words are perfectly suitable for Zdravko Stoynov who managed to preserve and develop his 

childish curiosity and disregard for limits and taboos which, combined with exceptional intelligence 

and multidisciplinary knowledge accumulated during the years, made him an extraordinary scientist. 

The scientist 

Zdravko Stoynov graduated from the Technical University of Sofia in 1960 by constructing the 

first analog computer in Bulgaria as his master’s thesis. In the next 2 years, he established the 

“Computing and Modeling Laboratory” at the Technical University and constructed a larger analog 

computer to calculate non-linear differential equations up to the 120th order [1]. At the same time, 



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he developed non-standard equipment for researchers at the BAS. As a result, in 1963 he was 

introduced to Evgeni Budevski, who in that time feverishly worked with his team on growing a 

dislocation-free single crystal, an extremely sensitive object. If they succeeded, the first “perfect 

crystal” in the world would be produced, experimentally confirming the Stransky-Kaischew theory 

of two-dimensional nucleation. Thus, Zdravko Stoynov became a part of a talented world-renowned 

research team on the verge of significant scientific discovery. In a matter of months, he considerably 

increased sensitivity, precision, and stability of the measuring equipment and although coming from 

a completely different scientific field, he started to participate actively in the scientific work. In a 

contribution about Academician Evgeni Budevski’s life and scientific achievements [2], Zdravko 

Stoynov describes expressively the atmosphere, emotions, and dedication of the entire team during 

those exiting times. In 1965, thirty-three years after the publication of the Stransky-Kaischew 

theory, its experimental proof was finally obtained.  First in the world, Budevski’s team successfully 

grew the dislocation-free single crystal. This accomplishment has sparked extensive electrochemical 

studies in a new, experimentally unexplored system with completely different behaviour from 

systems with dislocations in the crystal lattice. Zdravko Stoynov is in the heart of this research, 

developing models for surface diffusion and monoatomic layer growth [3,4].   

With such a strong scientific start, what to do next?  

The exceptional engineering and mathematical background give Zdravko Stoynov the unique 

independence to develop targeted task specific equipment. From then, he has the freedom to 

choose what scientific peak to overcome next, and he selected a difficult and little exploited, but 

yet exciting field, full of potential and enormous opportunities – Electrochemical Impedance 

Spectroscopy (EIS). In parallel, he continues to work in a pure engineering field - automation of the 

scientific experiment. 

In 1967, the Central Laboratory of Electrochemical Power Sources (CLEPS) was established, with 

director Prof. Evgeni Budevski. The young experienced engineer Zdravko Stoynov, a head of the 

newly founded Department of Electrochemical Methods, builds the needed equipment. Thus, CLEPS 

laboratories started operating with automated powerful testing stations which could not be 

purchased on the market and were also implemented in the Bulgarian lead acid battery plants.  

Currently the equipment of Department of Electrochemical Methods covers the range from 0.1 

to 1000 A. 
 

 
Zdravko Stoynov’s computerized testing laboratory in CLEPS (1975) 

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Electrochemical Impedance Spectroscopy 

Gradually, the development of non-standard original equipment for specialized electrochemical 

studies turned from a target into a tool, while the objectives shifted towards the invention of 

sophisticated experimental methods. Zdravko Stoynov started to develop innovative approaches and 

techniques for electrochemical studies and characterization of different systems. Despite his interest 

and work in various scientific fields, his greatest and undying love remained to be electrochemical 

impedance. Very soon he becomes one of the world leaders in EIS which today is evaluated as a 

powerful method for thorough investigations of a wide scope of systems and processes.  

What has attracted Zdravko Stoynov to EIS method? ... the unique information opportunities and 

numerous challenges that he tried to overcome during the course of over half a century - to his last 

breath. 

Nowadays, measuring electrochemical impedance with frequency response analyzers is the 

mainstream method used in thousands of laboratories. However, only the few know that Zdravko 

Stoynov implemented this equipment into electrochemical measurements after a visit to the 

Solartron company in 1968. The same year, the first two frequency response analyzers were bought 

and introduced by Prof. Israel Epelboin in his laboratory in Paris (CNRS-UPMC, Université Pierre et 

Marie Curie) and Zdravko Stoynov in CLEPS (BAS).  

The next challenge was “impedance of batteries” – an experiment which correlates with both the 

applied and research activities of CLEPS, and which was considered impossible at that time. 

However, Zdravko Stoynov starts to systematically chisel away at the scientific taboos…. till his last 

day…. with never ending enthusiasm and dedication. For a start, he introduces measurements out 

of equilibrium. Today this is customary, but 40 years ago it was unacceptable. He builds specialized 

equipment and with his colleagues at CNRS in Paris measure, for the first time in the world, 

impedance of batteries– galvanostatically and quasi-stationary [5]. The year is 1977. Today, 40 years 

later, every company for electrochemical equipment produces systems for impedance testing of 

batteries. Obviously, science does not allow “taboos” and despite big and powerful expert teams 

that work today, it also needs pioneers. 
 

 

First publication on impedance of batteries, ref. [5] in 1977; 27 years later at the POEMES 
Workshop in Bulgaria, the co-authors Zdravko Stoynov and Hissasi Takenouti continue to 

enthusiastically discuss impedance (2004). 

The next challenge comes from the non-steady state of batteries during impedance measu-

rements. The solution is the development of the non-stationary (4-D) impedance analysis [6-13] 

which is quickly evaluated and adopted for testing of lithium-ion batteries by Mitsubishi [14,15], and 

later for studies of other time evolving processes [16,17]. Recently, 4-D impedance analysis was 

included in the software portfolio of Bio-Logic [18]. 



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Zdravko Stoynov and Massimo Schiavetti in front of Stoynov’s prototype equipment for „in operando“ 

impedance testing of large batteries for accumulation of energy from solar cells (ENEL- Pisa, 2014). 

Other innovative approaches 

The list of Zdravko Stoynov’s innovative approaches for electrochemical data analysis with 

enhanced information capabilities is long. Differential Coulometry Spectroscopy (DCS) [19] is intro-

duced in the analytical package of the software version V11.01 of Bio-Logic Science Instruments [20]. 

Differential Impedance Analysis (DIA) in which structural identification which does not require 

preliminary hypothesis, is applied for the first time in impedance data analysis [21-27]. Rotating 

Fourier Transforms (RFT) is initially developed during his doctorship in Zurich [28,29] - he concen-

trates on it again in his last and very creative year introducing new opportunities for impedance 

analysis at low and ultra-low frequencies where “many important and still hidden interesting 

phenomena can be measured precisely“ [30]. His goal is the development of a new, “4th Generation” 

marketable impedance analyser, applying RFT and MRFT (Multiple RFT). He was expecting this to 

happen in the near future and was working hard to accelerate its coming. Zdravko Stoynov’s latest 

invention is Differential Resistance Analysis based on original data processing from current-voltage 

curves. This method surprises and fascinates with simplicity and originality that provide over 10 

times higher sensitivity when assessing degradation rate. This approach could eliminate some 

difficult and risky accelerated stress tests on batteries and fuel cells [31-33]. 

 

  

Bio-logic Science Instruments (Grenoble 2017): Zdravko Stoynov explaining visually his  
Rotating Fourier Transforms 

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International activities 

Although engulfed in science, Zdravko Stoynov is no less valued as a “social scientist” with an 

acute sense of establishment, with excellent teaching skills, and with a never- ending enthusiasm to 

educate and pass on his knowledge and know-how. He is one of the international impedance society 

founders - a similarly minded enthusiastic group of colleagues fascinated by the potential of 

electrochemical impedance. For over 30 years, the society has been gathering within the framework 

of two international conference chains: 

• The International Electrochemical Impedance Spectroscopy Symposia (EIS), dating from 1989,  

• The International Electrochemical Impedance Analysis Symposia (EIA), dating from 1988.  
 

 
10th International Symposium on Electrochemical Impedance Spectroscopy (EIS), A Toxa, 

Galicia, Spain (2016). Lecture on Rotating Fourier Transforms (Zdravko Stoynov’s last 
participation in EIS) 

On a regional level, Zdravko Stoynov was one of the driving forces behind the establishment of 

the Regional Symposium of Electrochemistry - South-East Europe (RSE-SEE) in 2007, and acted as 

its co-organizer in Bulgaria, 2015. The 7th Symposium held in May 2019 in Croatia was dedicated 

to his memory. Starting in 1996, Zdravko Stoynov also establishes the National electrochemical 

event with international participation “Sofia Electrochemical Days”. Till his last day, Zdravko 

Stoynov continued to invigorate these scientific forums with his innovative and avantgarde ideas. 

Recognition 

It is a quite rewarding experience to be able to reap what you have sown. Zdravko Stoynov could 

reap the respect and appreciation of his friends and colleagues from IEES, BAS, and all over the 

world, who joined together physically and virtually to celebrate his 80th birthday, turning it into a 

joyous and heartwarming event. The Bulgarian Academy of Sciences honored his exceptional service 

with the special medal of the President of BAS, crowning and completing his BAS honors collection. 

The international electrochemical community and the Bulgarian colleagues expressed their 

respect and gratitude to Zdravko Stoynov, who was named by his associate Digby McDonald from 

Berkeley-California as “a giant in the electrochemical impedance spectroscopy”. The special issue of 

Bulgarian Chemical Communications has been dedicated to his 80th anniversary and includes 30 

publications by scientists from 13 countries.  

Philosophers say that a man dies only when the memory of him is gone. The memory of Zdravko 

Stoynov will not fade. It will not be gone. It remains strong within the large international family of 

his students, colleagues, and friends from all over the world who honor, respect, and appreciate 

him. They named the Electrochemical Impedance Analysis Symposium and the Internet Center for 



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Impedance Spectroscopy after him. The “Zdravko Stoynov” Prize in his honor will be awarded at 

each Meeting of the EIA to foster and promote creative out-of-the-box thinking in young 

researchers. The memory of Zdravko Stoynov is persistent, as are his deeds. All that he has sown 

and nurtured will continue to bear fruit into the future. 
 

  
“Zdravko Stoynov” 

Young Scientist Prize 
Awarding of “Zdravko Stoynov” Prize to its first recipient at the 11th International 

Symposium of Electrochemial Impedance Anlysis (Camogli, Italy, Nov. 2017) 

Zdravko Stoynov’s methods 

Non-stationary (4-D) impedance analysis 

Based on the classical method of the transfer function, Electrochemical Impedance Spectroscopy 

gives a local, linearized and full (in a frequency aspect) description of the investigated electrochemical 

system, which is assumed to be in steady-state. However, batteries behave as big statistical systems 

with distributed parameters on a macro and micro scale. During cycling, processes of mass and energy 

transfer take place. They change the object’s structure and parameters. Thus, batteries show non-

steady state behavior, which is the basic restriction for correct impedance studies. 

For further development of batteries, a liberation from the restriction of steady-state condition is 

generally needed. This motivated Zdravko Stoynov to develop the non-stationary (4-D) impedance 

analysis - an approach that eliminates the delay errors during frequency sweep by introducing the 

time for each measurement as the fourth parameter in the experimental data set [6-9] (Figure 1).  
 

  
Figure 1. Simulated complex-plane impedance diagrams of time evolving simple Faradaic 

reaction deformed by measurement delay errors: a) iso-frequency dependence for the lowest 
frequency; b) fifth iso-frequency dependence (starting from the lowest frequency). 

Reproduced from ref. 13 with permission from D. Vladikova 

This approach improved significantly the impedance studies of batteries and other non-steady 

state systems [10-13]. Zdravko Stoynov approximates every iso-frequency dependence with a 

formal model and applies two orthogonal iso-frequency cubic splines for the real and the imaginary 

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components, respectively. The interpolation (or extrapolation) for a given time, tj, and a set of 

frequencies ωi, gives the corresponding estimates of the real and imaginary parts. Thus, the data of 

each time evolving diagram are reconstructed, and the corresponding impedance diagrams already 

represent the impedances measured virtually at the same time for all frequencies.  

4-D impedance analysis was introduced in the battery testing software and successfully applied in 

Li-ion battery research [14,15,18], and also for studies of some other time-evolving systems [16,17]. 

Rotating fourier transform (RFT) 

Non-steady state condition of electrochemical systems during impedance measurements pene-

trates deeper, affecting the Fourier Transform (FT), which is the mathematical kernel of every impe-

dance analyzer of our days. The FT is the best estimator of sinusoidal signals in steady-state conditions. 

However, out of those conditions, the FT produces specific errors dependent on the frequency. 

After an in-depth analysis of those errors, Zdravko Stoynov succeeds to develop theoretically an 

advanced generalized form of this transform – the Rotating Fourier Transform (RFT). This is the topic 

of his doctoral dissertation in the Federal Institute of Technology – Zurich [28,29]. The implementation 

of the RFT in impedance spectroscopy provides for precise measurements of time-evolving systems 

out of steady state conditions. It opens a new horizon for studies of batteries and fuel cells, corrosion 

and numerous other systems, far beyond the usually applied frequency range where “4-D impedance 

method seems to be the only method to easily remove the effect of time-variance” [18]. 

During the last year of his life, Zdravko Stoynov refocuses on further theoretical and experimental 

development of his advanced mathematical RFT tool, introduced 30 years ago. He describes it as a 

“powerful engine for non-stationary impedance spectroscopy which opens up the exploration of the 

low and infra-low frequencies where many important and interesting phenomena, still hidden, can 

be measured precisely”. Expecting the development of new “4th Generation” marketable impedance 

analysers through the application RFT and MRFT (Multiple RFT) in the near future, he labours over 

both the mathematical tool and his experimental verification (Figure 2) in order to accelerate the 

coming of this “near future” and to be able to see it. An unedited version of his last unpublished 

work on this topic, written months before his passing, is presented in the Proceedings of the 10th 

International Symposium of Electrochemical Impedance Analysis (Section “Letters to the Editor”) 

[30]. His colleagues from IEES are very much hopeful and will support the continuation of his efforts 

and the realization of his idea. 
 

  
Figure 2. Complex-plane impedance diagrams of Li-ion battery 2000 mAh during charge with 100 mA: (a) 

produced by conventional Impedance analyser (Solartron 1260) using Fourier Transform. Frequency 
range 1 kHz – 1 mHz, 5 points/decade, AC signal 11 mA; (b) produced by Rotating Fourier Transform of 

the data from Fig. 2a. Frequency range 10 mHz to 1 mHz, 5 points/decade [30]. 

Differential coulometry spectroscopy (DCS) 

Battery testing is an important application-oriented tool for evaluation of their operational 

capability and performance as sources of energy and power. The typical testing results give general 



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information that represents the overall behaviour and thus does not support the analytical 

understanding of the processes taking place. To fill this gap, Zdravko Stoynov develops Differential 

Coulometry Spectroscopy (DCS) [19], which extracts valuable information about the batteries 

internal kinetics, electrochemical design, and life degradation.  

The DCS technique requires measurements of the voltage changes with time followed by 

precise analysis with the technique of Spectral Transform (ST) of aperiodic functions [24,26]. In 

order to separate the thermodynamic kinetics from the masking dynamic effect of the intrinsically 

connected transport limitations, very slow-rate galvanostatic testing (charge/discharge) is required. 

In principle, the galvanostatic mode of testing is a sweep coulometry and provides for the evaluation 

of the quantity of electricity necessary for the propagation of the investigated process or its steps. 

The voltage-time (U/t) dependence (Figure 3a) of an electrochemical cell measured during charge (or 

discharge) can be easily converted into a voltage – quantity of electricity dependence. The final 

relation can be presented as capacity/voltage (C/U) applying the ST tool (Figure 3b).  

The coulometric peak analysis provides for capacity evaluation of the different charge or 

discharge steps. The mapping of the peaks position and coulometric capacity and the analysis of 

their time dependence can be used for evaluation of battery state of health (SoH). The DCS can also 

provide valuable information about the degradation processes. It is useful tool for electrochemical 

studies of rechargeable batteries based on intercalation materials. Recently, DCS was included in 

the analysis package of BioLogic Science Instruments’ EC-Lab software version V11.01 [20]. 
 

a 

 

b 

 
Figure 3. Four volts Li-ion sample with nominal capacity of 2200 mAh: a) slow sweep voltage–time charge 
curve (h = 100 hours); b) capacity spectrum of the slow sweep voltage–time charge and discharge curves 

(h = 100 hours). Reproduced from ref. 19 with permission from D. Vladikova 

Differential impedance analysis (DIA) 

The introduction of Differential Impedance Analysis (DIA) method for electrochemical systems is 

one of the most advanced inventions of Zdravko Stoynov, in which for the first time the structural 

identification approach is applied in EIS. 

As a transfer function, electrochemical impedance provides a local, linear, and complete 

description of the system under investigation. However, this information has to be extracted from 

the experimental data, since impedance does not directly measure the processes under study, i.e. 

the physical reality, but gives information about the response of the system on an external 

perturbation. The most commonly used approach for analysis of experimental data is the develop-

ment of one or several working models followed by their validation. The model structure is chosen 

a priori, and thus the identification procedure is only parametric. The main efforts towards the 

improvement of the impedance data analysis are focused on the advancement of the identification 

procedure [33]. 

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In technical cybernetics, the structural identification approach is applied for data analysis. It does 

not require an initial working hypothesis and provides both structural and parametric identification. 

Zdravko Stoynov develops the technique of Differential Impedance Analysis (DIA), introducing the 

structural identification approach in the frequency domain [21-27]. This is one of his biggest 

breakthroughs and example of his out-of-the-box thinking. 

DIA procedure starts with the initial set of experimental data (angular frequency, real and 

imaginary components of the impedance), and thus can be applied to previously measured data. The 

kernel is the local scanning analysis, performed with the so-called local operating model (LOM) with a 

simple structure consisting of a resistance R1 in series with a parallel connection of capacitance C and 

a second resistance R2. The effective time-constant T = RC is also introduced as a LOM parameter.  

In contrast to the classical parametric identification performed over the entire frequency range 

which estimates the parameters’ vector as a preliminary chosen model structure, the identification of 

the LOM parameters’ vector by local analysis is carried out within a narrow frequency range, regarded 

as an operating window. When the window width is a single frequency point, the solution is purely 

deterministic. The following steps describe the procedure of the structural and parametric 

identification: 

• Scanning with the LOM throughout the whole frequency range with a scanning window of a 

single frequency point; 

• Parametric identification of the LOM at every working frequency. Since the number of the in-

dependent data available inside the observation window is smaller than the number of unknown 

parameters, the initial set of impedance data is extended with two additional terms – the 

derivatives of the real and imaginary components of the impedance with respect to the frequency. 

Thus, the set of equations determining the LOM parameters estimation becomes solvable; 

• Frequency analysis of the LOM parameters’ estimates (Figure 4). 
 

  

  
Figure 4. DIA of a three-step reaction: (a) complex-plane impedance diagram; (b) temporal plots  

(c) spectral plots; d) time-constant spectra of motor oil Mobil Delvac MX 15W40: new (▀); 
after 10000 km. (▀). Reproduced from ref. [26] with permission from D. Vladikova 

The results are presented in so called temporal plots, which give the frequency dependence of 

the LOM parameters estimates (Figure 4b). If the LOM parameters’ estimates are frequency 

independent in a given frequency region, the sub-model corresponding to this frequency segment 



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follows the LOM structure, i.e. it is described with a parallel combination of capacitance and 

resistance, which determine a time-constant. Thus, the number of the plateaus gives the number 

of the time-constants in the model (Figure 4b).  
The results may be presented in the more illustrative spectral form by the Spectral Transform 
procedure which converts the plateaus into spectral peaks by accumulating similar values of the 
respective parameters (Figure 4c) [24,26,27]. In principle the spectral transform is not simply a 
presentation of the same data in different coordinates. By its nature it is a type of regression analysis, 
filtering the statistical noises coming from the object itself and from the performed measurements, as 
well as the non-statistical noises. Its high power of filtration is eliminating the possible wild points and 
the resulting “black” noise, since the presence of an outlier introduces a fuzzy low intensity line, 
located away from the spectral kernel of the assembly, representing the investigated phenomenon. 
The amplitude of the spectral line is proportional to the frequency range with similar values of the 
corresponding parameters estimates. 

The presence of frequency dependence in the temporal plots marks either the regions of mixing 

between two phenomena, or frequency-dependent behaviour. Instead of spectral peaks, the spectra 

form fuzzy spectral “tails”. Those segments are additionally examined by Secondary DIA [25-27]. The 

procedure, known as Differential Temporal Analysis, includes the differentiation of the LOM 

parameters’ estimates with respect to the log frequency. It recognizes frequency-dependent elements 

(CPE, Warburg, Bounded Warburg etc.), as well as their presence in more complicated models. 

With DIA, Zdravko Stoynov opened new horizons for the impedance spectroscopy, increasing its 

objectivity, reliability and information capabilities (Figure 4d). The method is highly appreciated by 

the experts in the field of impedance spectroscopy and presented in recent monographs and surveys 

[35-38]. As an advanced development, DIA gradually enters in the impedance analysis and is already 

successfully applied for studies of electrochemical energy sources and other systems [39-48]. 

Differential resistance analysis 

Zdravko Stoynov’s final invention, developed in the last months of his life, is related to the most 

severe hurdles facing the deployment of batteries and fuel cells – lifetime and durability, and more 

precisely – their reliable evaluation.”  

The State-of-the-Art degradation already requires long-term testing, which can take several years 

– a huge restriction to market deployment. For the moment, the problem-solving approach consists 

in the development of accelerated stress test (AST) procedures and protocols, which should shorten 

the testing time in conditions activating the same aging mechanisms as in non-accelerated testing. 

This is a critical moment, since the measured degradation should be transferred to the real-life 

behaviour of the tested system. Thus, the selection of the acceleration parameters and the level of 

acceleration are of critical importance and may differ significantly between systems and applications. 

Zdravko Stoynov offers a new and original approach that decreases the testing time by 

increasing the sensitivity and accuracy of the standard monitoring and diagnostic tools, providing reliable 

quantitative information. For this purpose, he introduces new performance indicator with increased 

sensitivity in respect to degradation evaluation. It is based on analysis of the standard current-

voltage characteristics, which describe the interrelation between the power components – voltage 

and current. One effective direction which Zdravko Stoynov develops is the analysis of the 

differential resistance - an approach which is not still effectively exploited.  

The form of the volt-ampere characteristics depends on the operating parameters and the 

degradation processes. Under constant operating conditions, its changes are due to degradation. 

The next step is the introduction of an algorithm for their characteristic description. For this 

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purpose, Zdravko Stoynov developed differential analysis of current-voltage curves (DiVA). The 

method operates with the differential resistance Rd = dU/dI, i.e. with the derivative of the potential 

U with respect to the current I, which changes its value according to the working point, following 

the shape of the volt-ampere curve [31-33].  

The analysis of the Differential Resistance (DRA) as a function of the applied current Rd = f (I) 

(Figure 5a) works with derivatives, which increases the sensitivity in respect to the small deviations 

which should be recorded. The new functional dependence defines a new characteristic point for 

the cell performance - the minimum of the differential resistance Rd,min. In general, it reflects the 

state of health (SoH) at constant operating conditions, since it is determined by the intrinsic 

properties of the system and not by the external conditions (for instance current load). It is supposed 

that for deeper insight, impedance measurements should be performed also in a working point 

corresponding to Rd,min. 
 

  
Figure 5. Differential Resistance Analysis - schematic representation:  

a) U-I curve (-) and R vs. I dependence (-); b) spectral transform 

The impedance of the investigated electrochemical system depends on the selected working 

point, i.e. measurements carried out in different working points are not comparable. Usually when 

the degradation rate is under studies, they are performed at constant current corresponding to the 

one selected for the testing. However, the extraction of Rd,min defines a working point which is 

constant in respect to the internal state of the system, i.e. to its state of health, characterized with 

the smallest internal differential resistance for the conditions of the i-U curve. In addition, due to 

the analysis of derivatives, the changes in Rd,min will be observable much earlier than changes in 

other parameters, which are used for evaluation of SoH. 

The introduction of a spectral transform procedure additionally increases the noise immunity and 

sensitivity of the method (Figure 5b) [32,33]. The intensity of the individual spectral peak (A Ω-1 cm-4) 

is proportional to the length of the current range with similar values of the differential resistance. 

The operation with derivatives increases the data noise. In order to provide high quality data, Z. 

Stoynov developed recommendations for current-voltage measurements when applying DiVA [49]. 

The Differential Resistance Analysis, which uses the new characteristic indicator Rd,min, is several 

times more sensitive than the classical approach for measurement of the degradation rate based on 

the voltage change over time at constant current [30-32]. Figure 6 demonstrates the high selectivity 

and sensitivity of the method that makes visible changes in the system which are unnoticeable in 

the current-voltage characteristics and ensures their quantitative evaluation. The combination of 

Differential Resistance Analysis with impedance measurements in selected characteristic working 

points can provide information about the origin of the dominating degradation processes. 



Daria Vladikova J. Electrochem. Sci. Eng. 10(2) (2020) 65-78 

http://dx.doi.org/10.5599/jese.775  77 

d 

  
Figure 6. Differential Resistance Analysis of a Solid Oxide Fuel Cell: (a) i-U curve measured in the 

beginning of the testing and after 600 hours; b) spectral transform of the differential resistance Rd. 

Instead of conclusion 

The memory of Zdravko Stoynov is persistent, as are his methods. All that he has 

sown and nurtured will continue to bear fruit into the future. 

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