Development of photocatalytic and photothermal steam reforming of methane / 光触媒的および光熱変換的メタン水蒸気改質反応の開発

SARWANA, WIRYA

23 March 2023

京都大学 / 新制・課程博士 / 博士(人間・環境学) / 甲第24693号 / 人博第1066号 / 新制||人||250(附属図書館) / 2022||人博||1066(吉田南総合図書館) / 京都大学大学院人間・環境学研究科相関環境学専攻 / (主査)教授 吉田 寿雄, 教授 田部 勢津久, 教授 中村 敏浩, 教授 寺村 謙太郎 / 学位規則第4条第1項該当 / Doctor of Human and Environmental Studies / Kyoto University / DFAM

Carbon monoxide

Lanthanum doped sodium tantalate

Potassium hexatitanate

Photothermal steam reforming of methane

Supported nickel catalyst

Light size-dependent activity

361

Cinétique de formation et stabilité des domaines ferroélectriques créés par un Microscope à Force Atomique : étude de films minces monocristallins de LiTaO3 en vue d'applications mémoires / Growth and stability of ferroelectric domains in the field of an atomic force microscope : study of single crystal thin films of LiTaO3 for memory application

Brugère, Antoine

14 January 2011

Les matériaux ferroélectriques sont caractérisés par l'existence d'une polarisation électrique spontanée, dont l'orientation peut être inversée par l'application d'un champ électrique adéquat. Permettant de coder l'information sous la forme d'un domaine ferroélectrique, i.e. une région du matériau avec une certaine orientation de la polarisation, les ferroélectriques ouvrent la voie au stockage de masse de très haute densité (>10 Tbit/in ²). Dans ce contexte, nous avons employé la Piezoresponse Force Microscopy (PFM), un mode particulier de Microscope à Force Atomique (AFM), permettant la manipulation et la détection des domaines ferroélectriques à l'échelle du nanomètre. Avec pour objectif d'étudier les mécanismes de formation des domaines par l'intermédiaire d'une pointe AFM, nos travaux ont mis en valeur la cinétique de croissance des domaines dans des films minces monocristallins de LiTaO3, avec une approche complémentaire de celle thermodynamique, dépendante du champ électrique et soulignant le rôle de l'humidité dans une possible conduction de surface. En parallèle, les films de LiTaO3 ont permis d'appréhender davantage la nature électro-mécanique de la réponse PFM, pour notamment relier l'amplitude du signal mesuré à la géométrie du domaine sous pointe. PFM et domaines ferroélectriques se sont en effet révélés tour à tour, objet d'étude et outil de caractérisation. / Ferroelectric materials are characterized by their spontaneous polarization, whose direction can be reversed by the application of a suitable electric field. Using domains, i.e. regions of uniform polarization orientation, as information bits, ferroelectrics opens the pathway towards ultrahigh storage densities (>10 Tbit/in²). In this respect, Piezoresponse Force Microscopy (PFM), a technique derived from Atomic Force Microscopy (AFM), was used to manipulate and detect ferroelectric domains on the nanometer scale. Our study was focused on the domains formation mechanism in the local electric field of a nanosized tip. Within an approach complementary to the thermodynamic one, we underlined the kinetics of domains growth in single-crystal LiTaO3 thin films, and the role of humidity in a possible surface conduction. In parallel, the LiTaO3 thin films were used to better understand the PFM response, in particular the relation between the measured signal and the geometry of the domain below the tip. This way, PFM and ferroelectrics domains alternately appeared as object of study and characterization tool.

Electronique

Mémoire à très haute densité

Matériau ferroélectrique

Microscopie à Force Atomique

Piezoresponse Force Microscopy - PFM

Film mince

Tantalate de Lithium - LiTaO3

Electronics

Very high density memory device

Ferroelectric Material

AFM - Atomic force microscopy

PFM - Piezoresponse Force Microscopy

LiTaO3 - Lithium Tantalate

537.244 807 2

Investigations Into The Bulk Single Crystals, Nano Crystal Composites And Thin Films Of Ferroelectric Materials For Pyroelectric Sensor Applications

Satapathy, Srinibas

07 1900

In this thesis, the results pertaining to various investigations carried out on Triglycine sulphate (TGS) single crystals, polyvinylidene fluoride (PVDF) films, lithium tantalate (LT)/PVDF nanocomposites and LT thin films are presented with emphasis on the characteristics that are crucial for their use in pyroelectric sensors. TGS single crystals (size 68 x 45 x 42 mm3), which have high pyroelectric coefficients, were grown by slow cooling method using newly designed platform technique based crystal growth work stations. The problem of slow growth rate along c-direction was overcome by placing (010) oriented seeds on the platform. The grown TGS crystals were used for the fabrication of the laser energy meter and temperature sensor. One drawback of TGS is its low Curie temperature (490C). As a consequence when the operating temperature approaches the Curie temperature, the crystals start depolarizing owing to the movement of domains. As a result the linearity of the devices gets affected and restricts the use of TGS. Therefore pyroelectric materials possessing higher Curie temperatures and larger pyroelectric coefficients than that of TGS are desirable. LT in single crystalline form having Curie temperature of ≈6000C has already been in use for pyroelectric device applications. However, growing stoichiometric LT single crystal is very difficult. On the other hand PVDF polymer films (Tc≈1800C) have low pyrolectric coefficients and difficult to pole electrically. Therefore efforts were made to prepare LT/PVDF nanocrystal composites to increase the pyroelectric coefficient of PVDF and to reduce the poling field. Nanoparticles of LT were prepared using sol-gel route. Spherical nanoparticles of size 20-40nm were prepared from sol by adding oleic acid to it. These nanoparticles were characterized using XRD, TEM, DSC and Raman spectroscopy. PVDF films with large percentage of β-phase (ferroelectric phase) were fabricated from solutions prepared using dimethylsulphoxide (DMSO) solvent. PVDF films (30µm thick), embedded with 20-40nm sized nanocrystallites of LT were fabricated to utilize them for pyroelectric sensor applications. The ferroelectric and pyrolectric properties of nano composite films were studied for sensor applications point of view. As a replacement for the single crystals of LT in pyroelectric sensors, investigations were carried out on oriented LT thin films. The studies on LT thin films yielded promising results which could be exploited for pyroelectric sensor applications.

Sensors

Pyroelectric Sensors

Ferroelectric Sensors

Thin Films - Deposition

Crystal Growth

Pyroelectric Materials

Triglycine Sulphate (TGS)

Ferroelectric Materials

Pyroelectricity

Lithium Tantalate Nano Particles

Nanoparticles - Synthesis

Nano Composite Films

Polar Materials

LiTaO3

Lithium Tantalate(LT)

TGS Crystals

Materials Science

Electrocaloric materials and devices

Crossley, Samuel

January 2013

The temperature and/or entropy of electrically polarisable materials can be altered by changing electric field E. Research into this electrocaloric (EC) effect has focussed on increasing the size of the EC effects, with the long-term aim of building a cooler with an EC material at its heart. Materials and experimental methods are briefly reviewed. A ‘resetting’ indirect route to isothermal entropy change ∆S for hysteretic first-order transitions is described. An indirect route to adiabatic temperature change ∆T, without the need for field-resolved heat capacity data, is also described. Three temperature controllers were built: a cryogenic probe for 77-420 K with ∼5 mK resolution, a high-temperature stage with vacuum enclosure for 295-700 K with ∼15 mK resolution, and a low-temperature stage for 120-400 K with electrical access via micropositioners. Automation enables dense datasets to be compiled. Single crystals of inorganic salts (NH4)2SO4 , KNO3 and NaNO2 were obtained. Applying 380 kV cm−1 across (NH4)2SO4 , it was found that |∆S| ∼ 20 J K−1 kg−1 and |∆T | ∼ 4 K, using the indirect method near the Curie temperature TC = 223 K. Without the ‘resetting’ indirect method, |∆S| ∼ 45 J K−1 kg−1 would have been spuriously found. Preliminary indirect measurements on KNO3 and NaNO2 give |∆S| ∼ 75 J K−1 kg−1 for ∆E ∼ 31 kV cm−1 near TC = 400 K and |∆S| ∼ 14 J K−1 kg−1 for ∆E ∼ 15 kV cm−1 near TC = 435 K, respectively. A cation-ordered PbSc0.5Ta0.5O3 ceramic showing a nominally first-order transition at 295 K was obtained. The Clausius-Clapeyron phase diagram is revealed via indirect measurements where |∆S| ∼ 3.25 J K−1 kg−1 and |∆T | ∼ 2 K, and direct measurements where |∆T | ∼ 2 K. Clamped samples show broadening of the field-induced transition. Epitaxial, ∼64 nm-thick SrTiO3 films were grown by pulsed laser deposition on NdGaO3 (001) substrates with a La0.67Sr0.33MnO3 bottom electrode. The indirect method gives |∆S| ∼ 8 J K−1 kg−1 and |∆T | ∼ 3.5 K near 180 K with |∆E| = 780 kV cm−1. Finite element modelling (FEM) was used to optimise the geometry of multilayered capacitors (MLCs) for EC cooling. Intrinsic cooling powers of 25.9 kW kg−1 are predicted for an optimised MLC based on PVDF-TrFE with Ag electrodes.

620.1

Conductive Domain Walls in Ferroelectric Bulk Single Crystals / Leitfähige Domänenwände in ferroelektrischen Einkristallen

Schröder, Mathias

13 May 2014

Ferroic materials play an increasingly important role in novel (nano-)electronic applications. Recently, research on domain walls (DWs) received a big boost by the discovery of DW conductivity in bismuth ferrite (BiFeO3 ) and lead zirconate titanate (Pb(Zrx Ti1−x )O3) ferroic thin films. These achievements open a realistic and unique perspective to reproducibly engineer conductive paths and nanocontacts of sub-nanometer dimensions into wide-bandgap materials. The possibility to control and induce conductive DWs in insulating templates is a key step towards future innovative nanoelectronic devices [1]. This work focuses on the investigation of the charge transport along conductive DWs in ferroelectric single crystals. In the first part, the photo-induced electronic DC and AC charge transport along such DWs in lithium niobate (LNO) single crystals is examined. The DC conductivity of the bulk and DWs is investigated locally using piezoresponse force microscopy (PFM) and conductive AFM (c-AFM). It is shown that super-bandgap illumination (λ ≤ 310 nm) in combination with (partially) charged 180° DWs increases the DC conductivity of the DWs up to three orders of magnitude compared to the bulk. The DW conductivity is proportional to the charge of the DW given by its inclination angle α with respect to the polar axis. The latter can be increased by doping the crystal with magnesium (0 to 7 mol %) or reduced by sample annealing. The AC conductivity is investigated locally utilizing nanoimpedance microscopy (NIM) and macroscopic impedance measurements. Again, super-bandgap illumination increases the AC conductivity of the DWs. Frequency-dependent measurements are performed to determine an equivalent circuit describing the domains and DWs in a model system. The mixed conduction model for hopping transport in LNO is used to analyze the frequency-dependent complex permittivity. Both, the AC and DC results are then used to establish a model describing the transport along the conductive DW through the insulating domain matrix material. In the last part, the knowledge obtained for LNO is applied to study DWs in lithium tantalate (LTO), barium titanate (BTO) and barium calcium titanate (BCT) single crystals. Under super-bandgap illumination, conductive DWs are found in LTO and BCT as well, whereas a domain-specific conductivity is observed in BTO.

Domänenwand

Domänen

ferroelektrisch

Ferroelektrika

Lithiumniobat

Lithiumtantalat

Bariumtitanat

Barium-Kalzium-Titanat

Rasterkraftmikroskopie

Impedanz

Leitfähigkeit

domain walls

domain

ferroelectric

lithium niobate

lithium tantalate

barium titanate

barium calcium titanate

atomic force microscopy

conductivity

impedance

nanoimpedance microscopy

conductive AFM

PFM

Kelvin

ddc:530

rvk:UP 6300

Conductive Domain Walls in Ferroelectric Bulk Single Crystals

Schröder, Mathias

07 March 2014

Ferroic materials play an increasingly important role in novel (nano-)electronic applications. Recently, research on domain walls (DWs) received a big boost by the discovery of DW conductivity in bismuth ferrite (BiFeO3 ) and lead zirconate titanate (Pb(Zrx Ti1−x )O3) ferroic thin films. These achievements open a realistic and unique perspective to reproducibly engineer conductive paths and nanocontacts of sub-nanometer dimensions into wide-bandgap materials. The possibility to control and induce conductive DWs in insulating templates is a key step towards future innovative nanoelectronic devices [1]. This work focuses on the investigation of the charge transport along conductive DWs in ferroelectric single crystals. In the first part, the photo-induced electronic DC and AC charge transport along such DWs in lithium niobate (LNO) single crystals is examined. The DC conductivity of the bulk and DWs is investigated locally using piezoresponse force microscopy (PFM) and conductive AFM (c-AFM). It is shown that super-bandgap illumination (λ ≤ 310 nm) in combination with (partially) charged 180° DWs increases the DC conductivity of the DWs up to three orders of magnitude compared to the bulk. The DW conductivity is proportional to the charge of the DW given by its inclination angle α with respect to the polar axis. The latter can be increased by doping the crystal with magnesium (0 to 7 mol %) or reduced by sample annealing. The AC conductivity is investigated locally utilizing nanoimpedance microscopy (NIM) and macroscopic impedance measurements. Again, super-bandgap illumination increases the AC conductivity of the DWs. Frequency-dependent measurements are performed to determine an equivalent circuit describing the domains and DWs in a model system. The mixed conduction model for hopping transport in LNO is used to analyze the frequency-dependent complex permittivity. Both, the AC and DC results are then used to establish a model describing the transport along the conductive DW through the insulating domain matrix material. In the last part, the knowledge obtained for LNO is applied to study DWs in lithium tantalate (LTO), barium titanate (BTO) and barium calcium titanate (BCT) single crystals. Under super-bandgap illumination, conductive DWs are found in LTO and BCT as well, whereas a domain-specific conductivity is observed in BTO.

info:eu-repo/classification/ddc/530

ddc:530