Titanium fell to 47.50 CNY/KG on October 17, 2025, down 1.04% from the previous day. Over the past month, Titanium's price has fallen 3.06%, but it is still 7.95% higher than a year ago, according to trading on a contract for difference (CFD) that tracks the benchmark market for this commodity. This dataset includes a chart with historical data for Titanium.

This dataset contains the predicted prices of the asset Titanium over the next 16 years. This data is calculated initially using a default 5 percent annual growth rate, and after page load, it features a sliding scale component where the user can then further adjust the growth rate to their own positive or negative projections. The maximum positive adjustable growth rate is 100 percent, and the minimum adjustable growth rate is -100 percent.

Price-To-Book-Ratio Time Series for Osaka Titanium Tech Co Ltd. OSAKA Titanium technologies Co.,Ltd. manufactures and sells titanium products in Japan, the United States of America, China, and internationally. The company offers titanium sponges, titanium ingots, titanium tetrachloride, titanium tetrachloride aqueous solutions, and ferro-titanium products; and high-performance materials, including titanium powder, high-purity titanium, silicon monoxide, as well as gas-atomized titanium powder. Its products are used in aircraft and automobiles, LNG plants, seawater desalination plants, semiconductors, digital home appliances, and leisure and sporting goods industries. The company was formerly known as Sumitomo Titanium Corporation and changed its name to OSAKA Titanium technologies Co.,Ltd. in 2007. OSAKA Titanium technologies Co.,Ltd. was founded in 1952 and is headquartered in Amagasaki, Japan.

Imports of Titanium Ores & Concentrates in Mexico increased to 23160 USD Thousand in January from 8414 USD Thousand in December of 2023. This dataset includes a chart with historical data for Mexico Imports of Titanium Ores & Concentrates.

This dataset contains the predicted prices of IRON Titanium Token for the upcoming years based on user-defined projections.

This dataset contains the predicted prices of the asset IRON Titanium Token over the next 16 years. This data is calculated initially using a default 5 percent annual growth rate, and after page load, it features a sliding scale component where the user can then further adjust the growth rate to their own positive or negative projections. The maximum positive adjustable growth rate is 100 percent, and the minimum adjustable growth rate is -100 percent.

Cost-of-Goods-Sold-Including-Depreciation-and-Amortization Time Series for Osaka Titanium Tech Co Ltd. OSAKA Titanium technologies Co.,Ltd. manufactures and sells titanium products in Japan, the United States of America, China, and internationally. The company offers titanium sponges, titanium ingots, titanium tetrachloride, titanium tetrachloride aqueous solutions, and ferro-titanium products; and high-performance materials, including titanium powder, high-purity titanium, silicon monoxide, as well as gas-atomized titanium powder. Its products are used in aircraft and automobiles, LNG plants, seawater desalination plants, semiconductors, digital home appliances, and leisure and sporting goods industries. The company was formerly known as Sumitomo Titanium Corporation and changed its name to OSAKA Titanium technologies Co.,Ltd. in 2007. OSAKA Titanium technologies Co.,Ltd. was founded in 1952 and is headquartered in Amagasaki, Japan.

Rutile titanium dioxide is one of the most relevant oxide materials, where the impurity physics of hydrogen has recently been devoted much attention. Existing ab-initio calculations disagree with respect to the nature of the isolated hydrogen donor (shallow vs. deep) and it was not possible in previous muSR experiments to obtain a direct determination of the hyperfine interaction. In a previous Muon Xpress proposal, we checked the existence of shallow donor lines in a monocrystalline sample and now propose to characterize its hyperfine interaction, both by an orientation-dependence study in order to check for possible anisotropy, and by obtaining a full temperature-dependence curve.

Coarse columnar grains and heterogeneously distributed phases commonly form in metallic alloys produced by three-dimensional (3D) printing and are often considered undesirable because they can impart non-uniform and inferior mechanical properties. We demonstrate a design strategy to unlock consistent and enhanced properties directly from 3D printing. Using Ti−5Al−5Mo−5V−3Cr as a model alloy, we show that adding molybdenum (Mo) nanoparticles promotes grain refinement during solidification and suppresses the formation of phase heterogeneities during solid-state thermal cycling. The microstructural change due to the bifunctional additive results in uniform mechanical properties and simultaneous enhancement of both strength and ductility. We demonstrate how this alloy can be modified by a single component to address unfavourable microstructures, providing a pathway to achieve desirable mechanical characteristics directly from 3D printing., These datasets were collected at The University of Queensland (Australia) and Chongqing University (China) from 2021 to 2023. Details for each dataset are provided in the README file. Datasets included: 1) Tensile engineering stress-strain data for Ti-5553 horizontal specimens

Number of Ti-5553 horizontal specimens The engineering strain The engineering stress

2) Tensile engineering stress-strain data for Ti-5553 vertical specimens

Number of Ti-5553 vertical specimens The engineering strain The engineering stress

3) Tensile engineering stress-strain data for Ti-5553+5Mo horizontal and vertical specimens

Number of Ti-5553 horizontal and vertical specimens The engineering strain The engineering stress

4) TEM-EDX line scanning

The distance of TEM-EDX line scan The counts of element titanium (Ti) from the line scan The counts of element molybdenum (Mo) from the line scan

5) DICTRA simulation of the composition profile of molybdenum (Mo) at the interface of a Mo particle and titanium..., , This README file was generated on 2023-12-19 by Jingqi Zhang.

GENERAL INFORMATION

1. Title of Dataset: Ultra-uniform, strong and ductile 3D printed titanium alloy through bifunctional alloy design

2. Author Information

    **A. Corresponding Author Contact Information**
    * Name: Matthew Dargusch
    * Institution: The University of Queensland
    * Address: Level 6, Advanced Engineering Building (49), The University of Queensland, St Lucia, QLD 4072, Australia.
    * Email: m.dargusch@uq.edu.au
   
    **B. First Author Contact Information**
    * Name: Jingqi Zhang
    * Institution: The University of Queensland
    * Address: Room 634, Level 6, Advanced Engineering Building (49), The University of Queensland, St Lucia, QLD 4072, Australia.
    * Email: jingqi.zhang@uq.edu.au
   

3. Date of data collection (single date, range, approximate date): 2021-2023

4. Geographic location of data collection: The University of Queensland (Australia) an...

This proposal is part of the ongoing ERC PhD project “Size effect on the mechanical properties of polycrystalline materials in oxidizing and protective atmosphere”. The motivation of the project is to distinguish difference in strain distribution/grain orientation spread in “surface” grains and “core” grains of titanium-based materials and correlate these distributions to size effects in the presence of a free surface. Tensile and compression tests were already performed and surface EBSD characterisations were done to identify the anisotropic response of the material in tension (planar slip) versus compression (deformation twinning). Moreover, we propose an analysis of the effect of oxygen on the strain localisation and how it modifies the twinning behaviour of titanium. Our ambition is to extend and complement HR-EBSD and HR-DIC using SEM or LSCM with volumetric characterisations using a combination of diffraction contrast tomography (DCT) and topotomography (TT).

This archived Paleoclimatology Study is available from the NOAA National Centers for Environmental Information (NCEI), under the World Data Service (WDS) for Paleoclimatology. The associated NCEI study type is Paleoceanography. The data include parameters of paleoceanography with a geographic location of North Pacific Ocean. The time period coverage is from 1045269 to 0 in calendar years before present (BP). See metadata information for parameter and study location details. Please cite this study when using the data.

This archived Paleoclimatology Study is available from the NOAA National Centers for Environmental Information (NCEI), under the World Data Service (WDS) for Paleoclimatology. The associated NCEI study type is Lake. The data include parameters of paleolimnology with a geographic location of Michigan, United States Of America. The time period coverage is from 11037 to -60 in calendar years before present (BP). See metadata information for parameter and study location details. Please cite this study when using the data.

This archived Paleoclimatology Study is available from the NOAA National Centers for Environmental Information (NCEI), under the World Data Service (WDS) for Paleoclimatology. The associated NCEI study type is Lake. The data include parameters of paleolimnology with a geographic location of New Zealand. The time period coverage is from 17400 to 9625 in calendar years before present (BP). See metadata information for parameter and study location details. Please cite this study when using the data.

This data set contains files included in the detailed instructional demonstration paper submitted to Integrating Materials and Manufacturing Innovation. The detailed instructional demonstration paper includes documentation detailing how to configure and carry out a repeatable Rietveld Refinement with the software MAUD. The data set provides: diffraction data from two different neutron diffraction measurements, crystallographic information files, and configuration files for the refinement process. The authors provide this data set to enable new users of MAUD a better user experience, and provide a series of training opportunities to ensure users of MAUD understand how the software operates beyond treating it as a black box.

Title: Effect of Zr addition on the corrosion resistance of Ti-Mo alloy in the H2O2-containing inflammatory environment

Authors: Agata Sotniczuk, Agata Sotniczuk, Witold Chromiński, Damian Kalita, Halina Garbacz, Chenyang Xie, Junhui Tang, Baojie Dou, Marcin Pisarek, Aleksandra Baron-Wiecheć, Łukasz Kurpaska, Fan Sun, Kevin Ogle

Corresponding Author: Agata Sotniczuk ORCID: 0000-0002-3468-0468

This record contains files generated in the preparation process of the following publication:
Effect of Zr addition on the corrosion resistance of Ti-Mo alloy in the H2O2-containing inflammatory environment
Agata Sotniczuk, Agata Sotniczuk, Witold Chromiński, Damian Kalita, Halina Garbacz, Chenyang Xie, Junhui Tang, Baojie Dou, Marcin Pisarek, Aleksandra Baron-Wiecheć, Łukasz Kurpaska, Fan Sun, Kevin Ogle submitted to Applied Surface Science (Elsevier)

This research was funded in whole by National Science Centre, Poland [2023/48/C/ST11/00085]: Sonatina 7 grant.

Designations:
TiMo: titanium alloy with 12 weight % of molybdenum (Ti-12Mo) fabricated by arc melting technique followed by cold rolling and heat treatment
TiMoZr: titanium alloy with 12 weight % of molybdenum and 5 weight% of zirconium (Ti-12Mo-5Zr) fabricated by arc melting technique cold rolling and heat treatment (950 Celsius degrees/30 minutes) followed by water quenching
EBSD: Electron backscattered diffraction
PBS: Phosphate buffer saline solution
OCP: Open circuit potential
EIS: Electrochemical impedance spectroscopy
PSP: Potentiostatic polarization
ICP-AES: Inductively coupled plasma atomic emission spectrometer
AESEC: Atomic emission spectroelectrochemistry
XPS: X-ray photoelectron spectroscopy
SEM: Scanning electron microscope
TEM: Transmission electron microscope
HAADF STEM: High-angle annular dark-field imaging in a scanning transmission electron microscope
EDS: Energy dispersive spectroscopy
|Z|: impedance modulus [Ohm·cm^2]
vTi - dissolution rate for titanium [ng·s^-1·cm^-2]
vMo - dissolution rate for molybdenum [ng·s^-1·cm^-2]
vZr - dissolution rate for zirconium [ng·s^-1·cm^-2]
vƩ TiMo - total elemental dissolution rate for TiMo alloy[ng·s^-1·cm^-2]
vƩ TiMoZr - total elemental dissolution rate for TiMoZr alloy[ng·s^-1·cm^-2]
jƩ TiMo - total elemental current for TiMo alloy [µA·cm^-2]
jƩ TiMoZr- total elemental current for TiMoZr alloy [µA·cm^-2]
je TiMo - total electrochemical current for TiMo alloy [µA·cm^-2]
je TiMoZr - total electrochemical current for TiMoZr alloy [µA·cm^-2]

General remarks: Conditions of corrosion tests (OCP, EIS, AESEC):
1) Solution: PBS+0.1M H2O2
2) Temperature: 37 Celsius degrees
3) Electrodes: reference electrode - Ag/AgCl/KCl (sat), counter electrode-platinum plate
4) EIS: potential - OCP±10 mV, frequency range - 1000 Hz down to 0.01 Hz, surface area: 0.785 cm2
5) AESEC: tests were performed in a flow cell and the flow rate of solution was 1 ml/min, surface area: 1 cm2. AESEC procedure: step 1) OCP monitoring (1200s), step 2) PSP at -1V (1200s), step 3) OCP monitoring (2700s)

Files formats: Raw data and calculated results of OCP, EIS and AESEC tests: .xls, SEM micrographs: .tif, TEM micrographs/ EBSD /EDS maps: .jpg or .tif
Units are provided in brackets.

Content of data files is described in details in README_APSUC2024.txt file

DOI: 10.5281/zenodo.13903531

Data are published under Creative Commons Zero v1.0 Universal (CC0) license

How to cite Dataset: Sotniczuk, A., Chromiński, W., Kalita, D., Garbacz, H., Xie, C., Tang, J., Dou, B., Pisarek, M., Baron-Wiecheć, A., Kurpaska, Ł., Sun, F., & Ogle, K. (2024). Dataset: Effect of Zr addition on the corrosion resistance of Ti-Mo alloy in the H2O2-containing inflammatory environment [Data set]. Zenodo. https://doi.org/10.5281/zenodo.13903531

Summary of the estimated costs for the main components of the low-cost CT scanner–June 2021.

LME Index fell to 4,485.50 Index Points on October 17, 2025, down 0.60% from the previous day. Over the past month, LME Index's price has risen 4.79%, and is up 6.72% compared to the same time last year, according to trading on a contract for difference (CFD) that tracks the benchmark market for this commodity. LME Index - values, historical data, forecasts and news - updated on October of 2025.