• Univ Angers, CNRS, MOLTECH-Anjou, Angers, France
• Laboratoire de Physique des Solides, Université Paris-Saclay, CNRS, Université Paris-Sud, Orsay, France.
• Univ Rennes, CNRS, ISCR (Institut des Sciences Chimiques de Rennes), Rennes, France
• Aix-Marseille Université, Univ. de Toulon, CNRS, Institut Matériaux Microélectronique Nanosciences de Provence, Marseille, France
• Physikalisches Institut, Universität Stuttgart, Stuttgart, Germany
• Materials Science Divisions, Argonne National Laboratory, Argonne, USA
• Litvinenko Institute of Physical-Organic Chemistry and Coal Chemistry The National Academy of Science of Ukraine, Kiyv, Ukraine
• Faculty of Chemistry, University of the Basque Country UPV/EHU, Donostia International Physics Center (DIPC), Donostia, Euskadi, Spain
• Department of Pharmacognosy, Poznan University of Medical Sciences, Poznań
• Faculty of Chemistry, University of Bialystok, Białystok
• Faculty of Chemistry, Adam Mickiewicz University, Poznań
• Faculty of Mathematics and Natural Sciences; Institute of Chemistry, Jan Kochanowski University, Kielce
• Institute of Organic Chemistry Polish Academy of Sciences, Warszawa
• Institute of Low Temperature and Structure Research Polish Academy of Sciences, Wrocław
• The Faculty of Materials Engineering and Technical Physics, Poznan University of Technology, Poznań
• Academic Centre for Materials and Nanotechnology, AGH University of Science and Technology

Promoted doctorates

Malgorzata Widelicka

Defense Date: 2020-07-06 / Date of degree conferral: 2020-07-13

Subject: Optical, thermal, and transport properties of proton conductors of salts of dicarboxylic acids with different dimensionality of the hydrogen bonding network

Promoter: assoc. prof. Andrzej Łapiński, PhD, DSc

Reviewers: prof. Jan Baran, Ph.D., DSc, prof. Grażyna Bator, PhD, DSc

Aneta Pindela (née Suseł)

Defense date: 2020-07-02/ Date of degree conferral: 2020-08-26

Subject: Studies of the phenomenon of proton amine-imine tautomerism and stereoisomerism in 4-amino-1,3-thiazol-2(5H)-one derivatives

(interdisciplinary doctoral dissertation)

Promoters: prof. Andrzej Gzella, PhD, DSc,  assoc. prof. Andrzej Łapiński, PhD, DSc

Reviewers: prof. Michał Marszał, PhD, DSc, prof. Maciej Kozak, PhD, DSc

Arkadiusz Frąckowiak

Defense Date: 2015-12-02 / Date of degree conferral: 2016-02-16

Subject: Charge localization in organic conductors with hydrogen and halogen bonds - studies by optical spectroscopy methods

Promoter: prof. Roman Świetlik, PhD, DSc

Reviewers: prof. Bolesław Kozankiewicz, , PhD, DSc, prof. Jacek Ulański, PhD, DSc

Damian Jankowski

Defense Date: 2013-06-10 / Date of degree conferral: 2013-06-25

Subject: Spectroscopic studies of charge localization in one-dimensional organic conductors formed by TTF derivatives

Promoter: prof. Roman Świetlik, PhD, DSc

Reviewers: prof. Juliusz Sworakowski, PhD, DSc, prof. Jacek Ulański, PhD, DSc

Bolesław Barszcz

Date of defense: 2008-09-30 / Date of degree conferral: 2008-10-28

Subject: Normal vibrations and intramolecular excitations in selected organic conductors of TTF derivatives

Promoter: prof. Andrzej Graja, PhD, DSc

Reviewers: prof. Bolesław Kozankiewicz, PhD, DSc, prof. Juliusz Sworakowski, PhD, DSc

Master's degrees promoted

• Sc. Agata Piotrowska (2021)

• Sc. Adam Mizera (2017)

• Sc. Jacek Matysiak (2017)

• Sc. Natalia Rosiak (2017)

• Sc. Natalia Zborowska (2017)

• Sc. Sylwia Zięba (2017)

• Sc. Bartłomiej Gromadziński (2005)

• Sc. Alicja Gąsecka (2005)

• Sc. Krystian Klemt (2004)

• Sc. Bolesław Barszcz (2003)

• Sc. Roman Wesołowski (2002)

• Sc. Anna Szutarska (2001)

Promoted engineers

• Agata Piotrowska (2020)

• Michał Walczak (2017)

• Anna Wójcik (2017)

• Natalia Zborowska (2017)

• Adam Mizera (2016)

• Jacek Matysiak (2016)

• Natalia Rosiak (2016)

• Sylwia Zięba (2016)

• Michał Soja (2015)

Educational and popularization activities

• Lectures for doctoral students of the International Doctoral Program at IMP PAS entitled "Molecular Spectroscopy" delivered by Prof. Roman Swietlik (winter semester 2000/2001, summer semester 2001/2002 ).

• A series of lectures for doctoral students of the International Doctoral Program at IMP PAS entitled "Interactions of light with matter" delivered by Assoc. Prof. Andrzej Łapiński, (winter semester 2018, winter semester 2013).

• Laboratory classes entitled. "The phenomenon of light absorption in everyday life" was organized in 2018 for high school students at IMP PAS in Poznań - Sylwia Zięba, M.Sc. Adam Mizera, M.Sc.

• Popular science seminar entitled. "Photovoltaic boom" delivered as part of the European Funds Open Days on 10-05-2019 at IMP PAS - Bolesław Barszcz, Ph.D.

• Participation in the organization of demonstrations for young people as part of the Night of Scientists organized at the IMP PAS in Poznan in 2019: "Lights in the Dark" - Sylwia Zięba, M.Sc., Boleslaw Barszcz, Ph.D., and "Nitrogen madness" - Iwona Olejniczak, Ph.D., Arkadiusz Frąckowiak, Ph.D.

• Popular science lecture entitled. "Journey to the interior of the Earth - high pressures" delivered as part of the series "Fizyka Warta Poznania" 2019 at IMP PAS in Poznań - Sylwia Zięba, M.Sc.

• Preparation and conduct of interactive demonstrations as part of the XXII Poznań Festival of Science and Arts, April 9, 2019 - Iwona Olejniczak, Ph.D.

• Participation in the organization of demonstrations for young people as part of the Researchers' Night organized at the IMP PAS in Poznań in 2020: entitled. "Nitrogen madness" - Iwona Olejniczak, PhD, DSc, Boleslaw Barszcz, PhD, Arkadiusz Frąckowiak, PhD and "On the trail of greenhouse gases" - Iwona Olejniczak, PhD, DSc, Boleslaw Barszcz, PhD, Arkadiusz Frąckowiak, PhD

• Participation in the organization of demonstrations for young people as part of the Night of Scientists organized at IMP PAS in Poznan in 2021: "Planet Earth - Warm, getting warmer" - Iwona Olejniczak, Ph.D., DSc, Boleslaw Barszcz, Ph.D. and "Meeting with light" - Boleslaw Barszcz, Ph.D., Sylwia Zięba, M.Sc., Adam Mizera, M.Sc.

• Popular science lecture entitled. "Solar energy" delivered as part of the series "Fizyka Warta Poznania" in 2021 at the IFM PAN in Poznan - Boleslaw Barszcz, PhD

  Popular science lecture entitled. "Changing the world for the better - how to take care of the climate and the environment" delivered as part of the series "Fizyka Warta Poznania" in 2022 at the IMP PAS in Poznań - Iwona Olejniczak, Ph.D., DSc.

• Participation in the organization of the finals of the "Physics in Motion" competition in 2022 at the IMP PAS - Iwona Olejniczak, Ph.D., DSc, Boleslaw Barszcz, Ph.D., Adam Mizera, M.Sc.

FT-IR spectrometer Bruker Equinox 55 combined with FT-IR microscope Bruker Hyperion 2000 and accessories

The measuring system allows for recording spectra in polarized light from 30 to 18 000 cm^-1. The radiation sources in the spectrometer are a tungsten halogen lamp (1800-18000 cm^-1) and a silicon carbide ceramic rod (30-7000 cm^-1). The system is equipped with the following detectors: Si (operating in the range 10000-20000 cm^-1), InSb (3000-12500 cm^-1), MCT (400-7500 cm^-1), DLaTGS (180-12000 cm^-1) and DTGS (10-700 cm^-1). The instrument is equipped with the following beam splitters: quartz (3300-18000 cm^-1), KBr (370-7500 cm^-1), and Mylar (30-700 cm^-1). The spectrometer operates with a maximum spectral resolution of 0.5 cm^-1. FT-IR microscope Hyperion 2000 from Bruker attached to the spectrometer allows measuring reflection and transmission spectra in polarized light of micro samples with dimensions of fractions of a millimeter in the spectral range from 600 to 18000 cm^-1 as a function of temperature from 10 to 870 K. The microscope is equipped with an objective for recording reflection-absorption spectra from thin films applied to metallic substrates (600-6500 cm^-1). The microscope table (controlled by stepper motors) enables to study of the spatial distribution of substances in the material (spatial resolution of 1 mm). The diamond anvils allow for recording mid-infrared transmission spectra as a function of pressure (up to 20 GPa) at room temperature.

The spectrometer equipment includes the following components:

• Parker dry air purge system (the system is connected to the spectrometer and microscope)
• Bruker variable-angle reflectance accessory (enables recording of reflectance spectra in polarized light in the range from 400 to 7000 cm^-1 for angles of incidence and reflection from 10° to 80°)
• Gateway™ Attenuated Total Internal Reflection (ATR) accessory (six reflections horizontal ATR sampling system) to record ATR spectra as a function of temperature from room temperature to 200 °C in the spectral range from 600 to 7000 cm^-1)
• Beckman reflectance spectra accessory (enables the registration of reflectance spectra in a spectrometer chamber in the spectral range from 400 to 7000 cm^-1)
• Perkin-Elmer Diffuse Reflection (DRIFT) accessory (allows registration of reflectance-absorption spectra in the range of 400 to 7000 cm^-1)
• mirrors, cuvettes, and polarizers

Raman spectrometer LabRAM HR 800 Jobin Yvon and accessories

The spectrometer contains two diffraction gratings (600 and 1800 lines/mm), input and filter optics, and a multi-channel detector (CCD 1024´256) operating at liquid nitrogen temperature. It is equipped with a He–Ne laser (λ_ext = 632.8 nm), a tunable Stabilite 2017 argon laser with a power supply (λ_ext=454.5, 457.9, 465.8, 472.7, 476.5, 488.0, 496.5, 501.7, 514.5 nm) and a NIR laser with power supply (λ_ext=785 nm). The spectrometer is equipped with "Notch" type VLFIE filter sets: for 457 mm line (allowing approach to Rayleigh line at 150 cm^-1), for 488 mm line (allowing approach to Rayleigh line at 50 cm^-1), for 514 mm line (allowing approach to Rayleigh line at 50 cm^-1), for 633 mm line (allowing approach to Rayleigh line at 50 cm^-1), and for 785 mm line (allowing approach to Rayleigh line at 100 cm^-1). The spectrometer is equipped with an L-BXFM confocal microscope containing the following objectives: plan-achromatic objective ´10, NA=0.25, WD=10.6 mm, plan-achromatic objective ´50, NA=0.75, WD=0.37 mm, plan-achromatic lens ´100, NA=0.90, WD=0.21 mm, long-focus lens ´10, NA=0.25, WD=21 mm, long-focus lens ´20, NA=0.25, WD=12 mm, and macro-sample lens WD=40 mm. The LabRAM HR 800 Jobin Yvon Raman spectrometer is used to study Raman scattering spectra as a function of temperature and pressure.

Hitachi U-2900 NIR/Vis/UV Spectrometer

It enables the registration of absorption spectra in polarized light in the spectral range from 190 to 1100 nm of solid and liquid phase samples. Transmission and reflection spectra can be recorded at scan rates of: 10, 100, 200, 400, 800, 1200, 2400, and 3600 nm/min. The instrument has two radiation sources: a tungsten lamp (measurements in the visible light range) and a deuterium lamp (measurements in the ultraviolet light range). A silicon photodiode is used as a radiation detector. The spectrum measurement accuracy changes with the absorbance range change and is as follows: in the range from 0 to 0.5 ±0.002, from 0.5 to 1.0 ±0.004, and 1.0 to 2.0 ±0.008. The measurement error of transmittance value is equal to ±0.3%.

Hitachi F-7000 Spectrofluorimeter

Enables measurements of fluorescence, luminescence, and phosphorescence of solutions and solid samples as a function of temperature (Optistat CF cryostat by Oxford Inst). It is possible to perform measurements of fluorescence lifetime up to 1 ms. It is equipped with two monochromators allowing continuous selection of excitation and fluorescence emission wavelengths. The spectrofluorimeter is fitted with a set of edge filters and polarizers, allowing emission and excitation spectra to be measured in the range from 900 to 200 nm.

Conductivity measuring station

Specific electrical conductivity measurements are made using the four-electrode method. A Keithley 220 programmable current source allows current variations in the range of 1 nA - 100 mA, and a Keithley 182 digital voltmeter will enable measurements in the range of 3 mV - 30 V with a resolution of 1 nV - 10 μV. Temperature measurements are made in the range of 1.8 - 370 K. A 40 μm silver wire is used to attach the sample to the copper paths using a silver paste, which is also used for the electrodes. We can use gold or carbon paste (and other wire than silver) depending on our needs. The system allows the measurement of samples smaller than 1 mm (maximum about 1 cm).

Thermo-optical Analysis (TOA) Workstation

The thermo-optical analysis is a visual aid to observe physical effects during thermal analysis measurements. It allows for the determination of the temperature of the phase transition in the condensed phase under the occurrence of apparent texture changes in the tested material. This method is complementary to DSC, TG, or infrared measurements as a function of temperature. The measurement system consists of the following elements: stereo microscope Delta Optical IPOS 810 WS (objective plan achromat ´2 - maximum magnification ´400 together with coaxial illuminator, dark field module, photographic adapter with microscope camera), cryostat Linkam TC92 with accessories, multimeter - HP 34401a (ranges: 10 mA, 100 mA, 1A, 3A; maximum resolution: 10 nA), diode - OSRAM BPW 21 (dark current: 2 nA; wavelength 350-820 nm) and computer.

Temperature testing systems

• System for testing as a function of temperature from 1.8 to 370 K
  (Optistat CF optical cryostat by Oxford Inst. (sets of windows - KBr, KRS-5, quartz), Oxford Inst. ITC 503 thermoregulator, transfer line GFS 650, flowmeter PKR 251/26001, helium dewar 50 l, pump system: turbomolecular pump TSH 071E, membrane pump MVP 015, circulating pump, pressure gauge PKR 251 / 26001)
  Enables recording of fluorescence spectra as a function of temperature and is used in conductivity measurements.

• System for testing as a function of temperature from 4.2 to 300 K
  (Optical cryostat CF 2102 by Oxford Inst., thermoregulator Oxford Inst. ITC 503, transfer line GFS 650, flowmeter PKR 251/26001, helium dewar 50 l, pump system: turbomolecular pump TSH 071E, membrane pump MVP 015, circulation pump, pressure gauge PKR 251 / 26001).
  Enables absorption and reflection spectra recording in polarized light (600 -18000 cm^-1) and Raman scattering spectra.

• System for testing as a function of temperature from 77 K to 870 K
  (cryostat from Linkam Corp. TC92, Linkam Inst. thermoregulator, nitrogen dewar with desiccants for blowing the cryostat, heating line for cryostat housing)
  It enables the recording of absorption and reflection spectra in polarized light (600 -18000 cm^-1) and Raman scattering spectra and is used in the thermo-optical analysis (TOA).
• System for testing optical properties simultaneously as a function of temperature (4.2-300 K) and pressure (from atmospheric pressure to 20 GPa)
  (Optical cryostat CF 2102 by Oxford Inst. with equipment, diamond anvil Diacell D-07 placed on a cold finger of the cryostat - max. pressure 100 GPa)
  It allows the recording of Raman scattering spectra as a function of temperature and pressure.

Equipment for sample preparation

• chemistry lab
• Laurell W5-650MZ-23NPPB Rotary thin-film coater
• mechanosynthesis ball mill
• laboratory dryer
• KBr Pellet Making Die Set
• hydraulic press,
• laboratory balance
• cuvettes for gases (l=10 cm) and liquids (l = 0.1 mm - 50 mm) made of glass, quartz, NaCl, KRS-5, BaF2, KBr, CsJ
• diamond anvils,
• ED wire cutting machine for making holes in gaskets,
• device for assembling gaskets,
• ultrasonic cleaner,
• stereo microscope (max. 20),
• soldering station
• stereo microscope Delta Optical IPOS 810 WS (objective plan achromat 2 - maximum magnification 400 with coaxial illuminator, dark field module, and camera adapter

Computing stations

The software we use (Gaussian and Crystal programs) enables us to perform lattice vibration (phonon), vibrational, and electron transition calculations.

Research objectives

We are searching for new proton conductors with high conductivity and thermal stability that could be used as sources of green energy. They could be used as electrolytes in fuel cells, where the only by-products are water and heat. The research aim of the Department of Molecular Crystals is to understand the nature of physical phenomena that occur in proton conductors. This will enable us to design new functional materials that could be used in an innovative economy. In the face of growing demand for electricity and rising prices, we are also undertaking activities related to searching for new alternative sources of energy, which should be inexhaustible, easily accessible, efficient, and environmentally friendly. Great hopes are raised by the possibility of using clean energy from solar radiation. Our research aims to design and produce a new donor-acceptor copolymer with a narrow energy gap, which could be used in efficient solar cells. For many years we have been investigating the physical properties of organic conductors that could find applications in future electronics. Our research is focused on understanding the nature of phase transitions induced by temperature or pressure, charge ordering phenomena, electron correlations, charge distribution fluctuations, and coupling of electrons to internal vibrations of molecules.

Research profile

Using experimental and theoretical methods of molecular spectroscopy, vibrational and electron structure studies of electronically and ionically conducting organic materials are conducted. Measurements are performed in a wide spectral range from far-infrared to ultraviolet as a function of temperature (from 1.8 to 900 K) and pressure (up to 20 GPa). In the Department of Molecular Crystals, we deal with calculation (DFT and TD-DFT methods) and interpretation of theoretical spectra. In our research, we use the following techniques and experimental methods of condensed phase physics: the technique of transmission/absorption spectra in polarized light, the technique of specular reflection spectra in polarized light in a wide range of incident and reflected angles, the technique of diffuse reflection spectra, the technique of attenuated total internal reflection, the technique of reflection-absorption spectra from thin films applied on a metallic substrate, the Raman scattering method, measurements of specific electrical conductivity by the four-electrode method, thermo-optical analysis, methods of fluorescence, luminescence and phosphorescence spectroscopy.

Research Profile

• Electron states, proton conductivity and molecular dynamics in organic materials for molecular electronics, fuel cells, and photovoltaics (statutory task 2021-2023)
• Chirality and electrical conductivity in novel multifunctional materials for electronics applications (grant task 2022-2023)
• Effect of temperature and pressure on the helical hydrogen bonding network of new solid electrolytes (grant task 2020-2023)
• Analysis of physicochemical properties of novel proton conductors of dicarboxylic acid derivatives (grant task 2017-2020)
• Fabrication and optoelectronic properties of graphene oxide-based composites (grant task 2016-2020)
• Synthesis and photo-electrochemical properties of novel hybrid systems of graphene oxide with organic modifiers for molecular optoelectronics applications (grant task 2015-2017)
• An investigation by IR and Raman spectroscopy of the role of hydrogen and halogen bonding in the formation of the Mott insulator state in low dimensional organic conductors formed by tetrathiafulvalene (TTF) derivatives (grant task 2012-2015)
• Photo-electrochemical characterization of thin films of organic semiconductors (grant task 2012-2015)
• Functionalization of "small" carbon nano-onions with polyphenolic compounds and their potential application in elastin/collagen biosensors (grant task 2011-2014)