This page has only limited features, please log in for full access.

Mr. Nils Haneklaus
Td-Lab Sustainable Mineral Resources, Danube University Krems, 3500 Krems, Austria

Basic Info


Research Keywords & Expertise

0 diffusion bonding
0 TLP bonding
0 Diffusion brazing
0 Hot isostatic pressing (HIP)
0 Printed circuit heat exchanger (PCHE)

Fingerprints

diffusion bonding
TLP bonding
Hot isostatic pressing (HIP)

Honors and Awards

The user has no records in this section


Career Timeline

The user has no records in this section.


Short Biography

The user biography is not available.
Following
Followers
Co Authors
The list of users this user is following is empty.
Following: 0 users

Feed

Review
Published: 12 February 2021 in Metals
Reads 0
Downloads 0

Diffusion bonding is a solid-state welding technique used to join similar and dissimilar materials. Relatively long processing times, usually in the order of several hours as well as fine polished surfaces make it challenging to integrate diffusion bonding in other production processes and mitigate widespread use of the technology. Several studies indicate that varying pressure during diffusion bonding in contrast to the traditionally applied constant load may reduce overall processing- and bonding times. Such processes are referred to as impulse pressure-assisted diffusion bonding (IPADB) and they are, for the first time, reviewed in this work using the PRISMA (Preferred Reporting Items for Systematic Reviews and Meta-Analysis) methodology. Results of the review indicate that varying pressure can indeed reduce bonding times in diffusion bonding and reduce the requirements for pre-bond surface preparation. Additional research is required and should go beyond small and simple sample geometries to concentrate on making IPADB accessible to industrial applications.

ACS Style

Abdulaziz AlHazaa; Nils Haneklaus; Zeyad Almutairi. Impulse Pressure-Assisted Diffusion Bonding (IPADB): Review and Outlook. Metals 2021, 11, 323 .

AMA Style

Abdulaziz AlHazaa, Nils Haneklaus, Zeyad Almutairi. Impulse Pressure-Assisted Diffusion Bonding (IPADB): Review and Outlook. Metals. 2021; 11 (2):323.

Chicago/Turabian Style

Abdulaziz AlHazaa; Nils Haneklaus; Zeyad Almutairi. 2021. "Impulse Pressure-Assisted Diffusion Bonding (IPADB): Review and Outlook." Metals 11, no. 2: 323.

Journal article
Published: 28 January 2021 in Renewable and Sustainable Energy Reviews
Reads 0
Downloads 0

Some phosphate rock contains elevated concentrations of natural uranium. China is the largest phosphate rock producing country in the world and will soon have the largest uranium requirements in the world as well. Most phosphate rock deposits in China show low uranium concentrations (20–30 mg/kg) so that the recovery of radiotoxic heavy metals is neither economically appropriate nor ecologically necessary. China does, however, also have elevated uranium concentrations (≥90 mg/kg) in phosphate rock deposits in Sichuan and Yunnan. We estimate that China could have recovered nearly 648 metric tU (1.43 million lb U3O8) from those mines in 2016. The amount corresponds to 9.7% of the total reported uranium requirements in this year or 39.3% of reported domestic uranium production in 2016. The future uranium recovery potential may be even higher in total numbers (1158 tU or 3.01 million lb U3O8 in 2030). The main reason are potentially increasing imports of phosphate rock from large exporting countries such as Morocco that show higher average uranium content. In addition, medium- to lower-grade domestic phosphate rock resources with larger shares of accompanying heavy metals, that include rare earths and uranium, will have to be processed. Although the uranium supply for China is currently not at risk, the supply security could be further increased by obtaining unconventional uranium from domestic and imported phosphate rock.

ACS Style

Delei Shang; Bernhard Geissler; Michael Mew; Liliya Satalkina; Lukas Zenk; Harikrishnan Tulsidas; Lee Barker; Adil El-Yahyaoui; Ahmed Hussein; Mohamed Taha; Yanhua Zheng; Menglai Wang; Yuan Yao; Xiaodong Liu; Huidong Deng; Jun Zhong; Ziying Li; Gerald Steiner; Martin Bertau; Nils Haneklaus. Unconventional uranium in China's phosphate rock: Review and outlook. Renewable and Sustainable Energy Reviews 2021, 140, 110740 .

AMA Style

Delei Shang, Bernhard Geissler, Michael Mew, Liliya Satalkina, Lukas Zenk, Harikrishnan Tulsidas, Lee Barker, Adil El-Yahyaoui, Ahmed Hussein, Mohamed Taha, Yanhua Zheng, Menglai Wang, Yuan Yao, Xiaodong Liu, Huidong Deng, Jun Zhong, Ziying Li, Gerald Steiner, Martin Bertau, Nils Haneklaus. Unconventional uranium in China's phosphate rock: Review and outlook. Renewable and Sustainable Energy Reviews. 2021; 140 ():110740.

Chicago/Turabian Style

Delei Shang; Bernhard Geissler; Michael Mew; Liliya Satalkina; Lukas Zenk; Harikrishnan Tulsidas; Lee Barker; Adil El-Yahyaoui; Ahmed Hussein; Mohamed Taha; Yanhua Zheng; Menglai Wang; Yuan Yao; Xiaodong Liu; Huidong Deng; Jun Zhong; Ziying Li; Gerald Steiner; Martin Bertau; Nils Haneklaus. 2021. "Unconventional uranium in China's phosphate rock: Review and outlook." Renewable and Sustainable Energy Reviews 140, no. : 110740.

Journal article
Published: 22 October 2020 in Minerals
Reads 0
Downloads 0

Low-grade phosphate rock from Sra Ouertane (Tunisia) was beneficiated using a thermal treatment consisting of calcination, quenching, and disliming. Untreated phosphate rock samples (group 1), calcined phosphate rock samples (group 2), as well as calcined, quenched, and dislimed (group 3) phosphate rock samples, were investigated using inductively-coupled plasma atomic emission spectroscopy (ICP-AES), inductively-coupled plasma mass spectrometry (ICP-MS), thermogravimetric analysis (TGA), and X-ray powder diffraction (XRD). Besides, the particle size distribution of the aforementioned three groups was determined. The proposed thermal treatment successfully increased the P2O5 content of the untreated phosphate rock from 20.01 wt% (group 1) to 24.24 wt% (group 2) after calcination and, finally, 27.24 wt% (group 3) after calcination, quenching, and disliming. It was further found that the concentration of relevant accompanying rare earth elements (Ce, La, Nd, Pr, Sm, and Y) was increased and that the concentration of Cd could be significantly reduced from 30 mg/kg to 14 mg/kg with the proposed treatment. The resulting phosphate concentrate showed relatively high concentrations in metal oxides: Ʃ MgO, Fe2O3, Al2O3 = 3.63 wt% and silica (9.81 wt%) so that it did not meet the merchant grade specifications of a minimum P2O5 content of 30 wt% yet. Removal of these elements could be achieved using additional appropriate separation techniques.

ACS Style

Noureddine Abbes; Essaid Bilal; Ludwig Hermann; Gerald Steiner; Nils Haneklaus. Thermal Beneficiation of Sra Ouertane (Tunisia) Low-Grade Phosphate Rock. Minerals 2020, 10, 937 .

AMA Style

Noureddine Abbes, Essaid Bilal, Ludwig Hermann, Gerald Steiner, Nils Haneklaus. Thermal Beneficiation of Sra Ouertane (Tunisia) Low-Grade Phosphate Rock. Minerals. 2020; 10 (11):937.

Chicago/Turabian Style

Noureddine Abbes; Essaid Bilal; Ludwig Hermann; Gerald Steiner; Nils Haneklaus. 2020. "Thermal Beneficiation of Sra Ouertane (Tunisia) Low-Grade Phosphate Rock." Minerals 10, no. 11: 937.

Review
Published: 08 May 2020 in Metals
Reads 0
Downloads 0

Similar and dissimilar material joints of AISI grade 304 (1.4301) and AISI grade 316 (1.4401) austenitic stainless steel by solid state diffusion bonding and transient liquid phase (TLP) bonding are of interest to academia and industry alike. Appropriate bonding parameters (bonding temperature, bonding time, and bonding pressure) as well as suitable surface treatments, bonding atmosphere (usually high vacuum or protective gas) and interlayers are paramount for successful bonding. The three main parameters (temperature, time, and pressure) are interconnected in a strong non-linear way making experimental data important. This work reviews the three main parameters used for solid state diffusion bonding, TLP bonding and to a smaller degree hot isostatic pressing (HIP) of AISI grade 304 and AISI grade 316 austenitic stainless steel to the aforementioned materials (similar joints) as well as other materials, namely commercially pure titanium, Ti-6A-4V, copper, zircaloy and other non-ferrous metals and ceramic materials (dissimilar joints).

ACS Style

Abdulaziz AlHazaa; Nils Haneklaus. Diffusion Bonding and Transient Liquid Phase (TLP) Bonding of Type 304 and 316 Austenitic Stainless Steel—A Review of Similar and Dissimilar Material Joints. Metals 2020, 10, 613 .

AMA Style

Abdulaziz AlHazaa, Nils Haneklaus. Diffusion Bonding and Transient Liquid Phase (TLP) Bonding of Type 304 and 316 Austenitic Stainless Steel—A Review of Similar and Dissimilar Material Joints. Metals. 2020; 10 (5):613.

Chicago/Turabian Style

Abdulaziz AlHazaa; Nils Haneklaus. 2020. "Diffusion Bonding and Transient Liquid Phase (TLP) Bonding of Type 304 and 316 Austenitic Stainless Steel—A Review of Similar and Dissimilar Material Joints." Metals 10, no. 5: 613.

Journal article
Published: 26 December 2019 in Environmental Science & Technology
Reads 0
Downloads 0
ACS Style

Gerald Steiner; Bernhard Geissler; Nils Haneklaus. Making Uranium Recovery from Phosphates Great Again? Environmental Science & Technology 2019, 54, 1287 -1289.

AMA Style

Gerald Steiner, Bernhard Geissler, Nils Haneklaus. Making Uranium Recovery from Phosphates Great Again? Environmental Science & Technology. 2019; 54 (3):1287-1289.

Chicago/Turabian Style

Gerald Steiner; Bernhard Geissler; Nils Haneklaus. 2019. "Making Uranium Recovery from Phosphates Great Again?" Environmental Science & Technology 54, no. 3: 1287-1289.

Journal article
Published: 14 May 2019 in Resources Policy
Reads 0
Downloads 0

Argentina's nuclear reactor fleet provides about 10% of the country's electricity, and it is foreseen to increase nuclear power production in the future. Although most Argentinians accept nuclear power generation, public opinion is not in favor of uranium mining and all uranium needs are presently met by uranium imports at costs above international market prices (both spot and long-term contracts). Argentina also imports considerable amounts of phosphate rock and phosphate fertilizer to supply its agricultural industry. It is well-known that phosphate rocks and phosphate fertilizers can contain elevated amounts of associated uranium that is dissipated on agricultural soils if it is not recovered during fertilizer production. In this work, we estimate the amount of uranium that can be recovered from imported phosphate rock, determine the amount of uranium that could theoretically be recovered from all phosphate fertilizers used in Argentina and discuss potential uranium recovery from identified domestic phosphate rock resources.

ACS Style

Luis López; Liliana N. Castro; Roberto A. Scasso; Luminita Grancea; Harikrishnan Tulsidas; Nils Haneklaus. Uranium supply potential from phosphate rocks for Argentina's nuclear power fleet. Resources Policy 2019, 62, 397 -404.

AMA Style

Luis López, Liliana N. Castro, Roberto A. Scasso, Luminita Grancea, Harikrishnan Tulsidas, Nils Haneklaus. Uranium supply potential from phosphate rocks for Argentina's nuclear power fleet. Resources Policy. 2019; 62 ():397-404.

Chicago/Turabian Style

Luis López; Liliana N. Castro; Roberto A. Scasso; Luminita Grancea; Harikrishnan Tulsidas; Nils Haneklaus. 2019. "Uranium supply potential from phosphate rocks for Argentina's nuclear power fleet." Resources Policy 62, no. : 397-404.

Journal article
Published: 19 February 2019 in Resources Policy
Reads 0
Downloads 0

Most European countries import phosphate rocks for mineral phosphate fertilizer production. In 2017, approximately 5.5 million t phosphate rocks were imported into the EU-28 and subsequently processed. Phosphate rock can contain relevant amounts of accompanying uranium as well as rare earth elements that can be recovered during phosphate fertilizer production. Recovering uranium from phosphate rock is a proven process that has been used on an industrial scale in North America, Europe, and Asia in the 1980s until decreasing uranium prices in the 1990s made this practice uneconomic. In this work, we estimate the amount of uranium contained in EU phosphate rock imports in 2017 using publicly available data from Eurostat as well as average uranium concentrations found in the exporting countries and discuss potential recoverable quantities. Results of this estimate indicate that a maximum of 334 t natural uranium could have theoretically been recovered from 2017 EU phosphate rock imports. This amount of uranium could have supported approximately 2.1% of the EU nuclear power fleets 2016 natural uranium requirements and is of the same order of magnitude as domestic EU uranium production.

ACS Style

Harikrishnan Tulsidas; Sophie Gabriel; Katarzyna Kiegiel; Nils Haneklaus. Uranium resources in EU phosphate rock imports. Resources Policy 2019, 61, 151 -156.

AMA Style

Harikrishnan Tulsidas, Sophie Gabriel, Katarzyna Kiegiel, Nils Haneklaus. Uranium resources in EU phosphate rock imports. Resources Policy. 2019; 61 ():151-156.

Chicago/Turabian Style

Harikrishnan Tulsidas; Sophie Gabriel; Katarzyna Kiegiel; Nils Haneklaus. 2019. "Uranium resources in EU phosphate rock imports." Resources Policy 61, no. : 151-156.

Project report
Published: 17 January 2018 in Sustainability
Reads 0
Downloads 0

A number of primary ores such as phosphate rock, gold-, copper- and rare earth ores contain considerable amounts of accompanying uranium and other critical materials. Energy neutral mineral processing is the extraction of unconventional uranium during primary ore processing to use it, after enrichment and fuel production, to generate greenhouse gas lean energy in a nuclear reactor. Energy neutrality is reached if the energy produced from the extracted uranium is equal to or larger than the energy required for primary ore processing, uranium extraction, -conversion, -enrichment and -fuel production. This work discusses the sustainability of energy neutral mineral processing and provides an overview of the current progress of a multinational research project on that topic conducted under the umbrella of the International Atomic Energy Agency.

ACS Style

Frederik Reitsma; Peter Woods; Martin Fairclough; Yongjin Kim; Harikrishnan Tulsidas; Luis Lopez; Yanhua Zheng; Ahmed Hussein; Gerd Brinkmann; Nils Haneklaus; Anand Kacham; Tumuluri Sreenivas; Agus Sumaryanto; Kurnia Trinopiawan; Nahhar Al Khaledi; Ahmad Zahari; Adil El Yahyaoui; Jamil Ahmad; Rolando Reyes; Katarzyna Kiegiel; Noureddine Abbes; Dennis Mwalongo; Eduardo Greaves. On the Sustainability and Progress of Energy Neutral Mineral Processing. Sustainability 2018, 10, 235 .

AMA Style

Frederik Reitsma, Peter Woods, Martin Fairclough, Yongjin Kim, Harikrishnan Tulsidas, Luis Lopez, Yanhua Zheng, Ahmed Hussein, Gerd Brinkmann, Nils Haneklaus, Anand Kacham, Tumuluri Sreenivas, Agus Sumaryanto, Kurnia Trinopiawan, Nahhar Al Khaledi, Ahmad Zahari, Adil El Yahyaoui, Jamil Ahmad, Rolando Reyes, Katarzyna Kiegiel, Noureddine Abbes, Dennis Mwalongo, Eduardo Greaves. On the Sustainability and Progress of Energy Neutral Mineral Processing. Sustainability. 2018; 10 (1):235.

Chicago/Turabian Style

Frederik Reitsma; Peter Woods; Martin Fairclough; Yongjin Kim; Harikrishnan Tulsidas; Luis Lopez; Yanhua Zheng; Ahmed Hussein; Gerd Brinkmann; Nils Haneklaus; Anand Kacham; Tumuluri Sreenivas; Agus Sumaryanto; Kurnia Trinopiawan; Nahhar Al Khaledi; Ahmad Zahari; Adil El Yahyaoui; Jamil Ahmad; Rolando Reyes; Katarzyna Kiegiel; Noureddine Abbes; Dennis Mwalongo; Eduardo Greaves. 2018. "On the Sustainability and Progress of Energy Neutral Mineral Processing." Sustainability 10, no. 1: 235.

Journal article
Published: 01 December 2017 in Energy
Reads 0
Downloads 0
ACS Style

Nils Haneklaus; Sarah Schröders; Yanhua Zheng; Hans-Josef Allelein. Economic evaluation of flameless phosphate rock calcination with concentrated solar power and high temperature reactors. Energy 2017, 140, 1148 -1157.

AMA Style

Nils Haneklaus, Sarah Schröders, Yanhua Zheng, Hans-Josef Allelein. Economic evaluation of flameless phosphate rock calcination with concentrated solar power and high temperature reactors. Energy. 2017; 140 ():1148-1157.

Chicago/Turabian Style

Nils Haneklaus; Sarah Schröders; Yanhua Zheng; Hans-Josef Allelein. 2017. "Economic evaluation of flameless phosphate rock calcination with concentrated solar power and high temperature reactors." Energy 140, no. : 1148-1157.

Journal article
Published: 03 November 2017 in Processes
Reads 0
Downloads 0

Mineral calcination worldwide accounts for some 5–10% of all anthropogenic carbon dioxide (CO2) emissions per year. Roughly half of the CO2 released results from burning fossil fuels for heat generation, while the other half is a product of the calcination reaction itself. Traditionally, the fuel combustion process and the calcination reaction take place together to enhance heat transfer. Systems have been proposed that separate fuel combustion and calcination to allow for the sequestration of pure CO2 from the calcination reaction for later storage/use and capture of the combustion gases. This work presents a new tube-in-tube helical system for the calcination of minerals that can use different heat transfer fluids (HTFs), employed or foreseen in concentrated solar power (CSP) plants. The system is labeled ‘flameless’ since the HTF can be heated by other means than burning fossil fuels. If CSP or high-temperature nuclear reactors are used, direct CO2 emissions can be divided in half. The technical feasibility of the system has been accessed with a brief parametric study here. The results suggest that the introduced system is technically feasible given the parameters (total heat transfer coefficients, mass- and volume flows, outer tube friction factors, and –Nusselt numbers) that are examined. Further experimental work will be required to better understand the performance of the tube-in-tube helical system for the flameless calcination of minerals.

ACS Style

Nils Haneklaus; Yanhua Zheng; Hans-Josef Allelein. Stop Smoking—Tube-In-Tube Helical System for Flameless Calcination of Minerals. Processes 2017, 5, 67 .

AMA Style

Nils Haneklaus, Yanhua Zheng, Hans-Josef Allelein. Stop Smoking—Tube-In-Tube Helical System for Flameless Calcination of Minerals. Processes. 2017; 5 (4):67.

Chicago/Turabian Style

Nils Haneklaus; Yanhua Zheng; Hans-Josef Allelein. 2017. "Stop Smoking—Tube-In-Tube Helical System for Flameless Calcination of Minerals." Processes 5, no. 4: 67.

Articles
Published: 02 September 2017 in Science & Global Security
Reads 0
Downloads 0

Phosphate rocks are predominantly mined for fertilizer production. However, they also contain considerable amounts of accompanying natural uranium that can exceed concentrations found at commercial uranium mines. Extracting uranium from phosphate rocks during fertilizer production is a technically mature process; it was used on an industrial scale in the United States and elsewhere before decreasing uranium prices made this practice unprofitable in the 1990s. Soon, technical improvements, potentially rising uranium prices, and anticipated environmental regulations may make uranium extraction from phosphates profitable again in the United States and emerging phosphate rock mining centers in Northern Africa and the Middle East. Extracting uranium during phosphate fertilizer production is desirable in a way that otherwise lost resources are conserved and fertilizers with reduced radiotoxic heavy metal content are produced. Phosphate rocks have also been subject to clandestine uranium acquisition. In this work, the relevance of unconventional uranium resources from phosphate rocks is reviewed. A brief overview of the extraction process, a list of the required materials, and a very simple estimation of the amounts of uranium that could be extracted using a container-sized pilot plant which can be integrated into existing fertilizer plants is provided. Lastly, past known unreported uranium extraction activities from phosphate rocks are discussed.

ACS Style

Nils Haneklaus; Anastasiya Bayok; Vitaly Fedchenko; Robert Kelley. Phosphate Rocks and Nuclear Proliferation. Science & Global Security 2017, 25, 143 -158.

AMA Style

Nils Haneklaus, Anastasiya Bayok, Vitaly Fedchenko, Robert Kelley. Phosphate Rocks and Nuclear Proliferation. Science & Global Security. 2017; 25 (3):143-158.

Chicago/Turabian Style

Nils Haneklaus; Anastasiya Bayok; Vitaly Fedchenko; Robert Kelley. 2017. "Phosphate Rocks and Nuclear Proliferation." Science & Global Security 25, no. 3: 143-158.

Journal article
Published: 25 May 2017 in Journal of Nuclear Engineering and Radiation Science
Reads 0
Downloads 0

This study suggests a new approach to diffusion bonding (DB) 316L stainless steel: a low-pressure procedure that includes a nickel interlayer. In this approach, relatively lower pressure is applied to the sample before the DB process, in contrast to the usual approach in which higher pressure is applied during the DB process. This new procedure was tested on mock-up 316L stainless steel tube-to-tubesheet joints, which simulated similar joints in coiled-tube heat-exchanger applications. This study confirms that the new procedure meets the overall success criteria, namely, a pull-out force exceeding the force required for tube rupture. It also shows that the DB joint is improved by the use of a Ni interlayer; the joint strength increased by approximately 33% for a 0.25 μm Ni interlayer and by approximately 18% for a 5 μm Ni interlayer. The joint cross sections were qualitatively examined using optical microscopy (OM) and scanning electron microscopy (SEM); the observations suggest that only portions of the interface were diffusion bonded, as a result of the low-pressure procedure and the surface roughness (due to the sample fabrication). The portions that were diffusion bonded, though, were sound, as characterized by the fact that the steel grains grew through the interface line to create a continuous metallographic structure.

ACS Style

Rony Reuven; Alan Bolind; Nils Haneklaus; Cristian Cionea; Charalampos Andreades; Grant Buster; Peter Hosemann; Per Peterson. Ni Interlayer to Improve Low-Pressure Diffusion Bonding of 316L SS Press Fit Tube-to-Tubesheet Joints for Coiled Tube Gas Heaters. Journal of Nuclear Engineering and Radiation Science 2017, 3, 030913 .

AMA Style

Rony Reuven, Alan Bolind, Nils Haneklaus, Cristian Cionea, Charalampos Andreades, Grant Buster, Peter Hosemann, Per Peterson. Ni Interlayer to Improve Low-Pressure Diffusion Bonding of 316L SS Press Fit Tube-to-Tubesheet Joints for Coiled Tube Gas Heaters. Journal of Nuclear Engineering and Radiation Science. 2017; 3 (3):030913.

Chicago/Turabian Style

Rony Reuven; Alan Bolind; Nils Haneklaus; Cristian Cionea; Charalampos Andreades; Grant Buster; Peter Hosemann; Per Peterson. 2017. "Ni Interlayer to Improve Low-Pressure Diffusion Bonding of 316L SS Press Fit Tube-to-Tubesheet Joints for Coiled Tube Gas Heaters." Journal of Nuclear Engineering and Radiation Science 3, no. 3: 030913.

News
Published: 28 December 2016 in Environmental Science & Technology
Reads 0
Downloads 0
ACS Style

Nils Haneklaus; Yajie Sun; Roland Bol; Bernd Lottermoser; Ewald Schnug. To Extract, or not to Extract Uranium from Phosphate Rock, that is the Question. Environmental Science & Technology 2016, 51, 753 -754.

AMA Style

Nils Haneklaus, Yajie Sun, Roland Bol, Bernd Lottermoser, Ewald Schnug. To Extract, or not to Extract Uranium from Phosphate Rock, that is the Question. Environmental Science & Technology. 2016; 51 (2):753-754.

Chicago/Turabian Style

Nils Haneklaus; Yajie Sun; Roland Bol; Bernd Lottermoser; Ewald Schnug. 2016. "To Extract, or not to Extract Uranium from Phosphate Rock, that is the Question." Environmental Science & Technology 51, no. 2: 753-754.

Journal article
Published: 01 September 2016 in Nuclear Engineering and Design
Reads 0
Downloads 0
ACS Style

Nils Haneklaus; Frederik Reitsma; Harikrishnan Tulsidas. High Temperature Reactors for a new IAEA Coordinated Research Project on energy neutral mineral development processes. Nuclear Engineering and Design 2016, 306, 198 -202.

AMA Style

Nils Haneklaus, Frederik Reitsma, Harikrishnan Tulsidas. High Temperature Reactors for a new IAEA Coordinated Research Project on energy neutral mineral development processes. Nuclear Engineering and Design. 2016; 306 ():198-202.

Chicago/Turabian Style

Nils Haneklaus; Frederik Reitsma; Harikrishnan Tulsidas. 2016. "High Temperature Reactors for a new IAEA Coordinated Research Project on energy neutral mineral development processes." Nuclear Engineering and Design 306, no. : 198-202.

Journal article
Published: 01 August 2016 in Journal of Materials Processing Technology
Reads 0
Downloads 0
ACS Style

Nils Haneklaus; Rony Reuven; Cristian Cionea; Peter Hosemann; Per F. Peterson. Tube expansion and diffusion bonding of 316L stainless steel tube-to-tube sheet joints using a commercial roller tube expander. Journal of Materials Processing Technology 2016, 234, 27 -32.

AMA Style

Nils Haneklaus, Rony Reuven, Cristian Cionea, Peter Hosemann, Per F. Peterson. Tube expansion and diffusion bonding of 316L stainless steel tube-to-tube sheet joints using a commercial roller tube expander. Journal of Materials Processing Technology. 2016; 234 ():27-32.

Chicago/Turabian Style

Nils Haneklaus; Rony Reuven; Cristian Cionea; Peter Hosemann; Per F. Peterson. 2016. "Tube expansion and diffusion bonding of 316L stainless steel tube-to-tube sheet joints using a commercial roller tube expander." Journal of Materials Processing Technology 234, no. : 27-32.

Journal article
Published: 01 January 2015 in Annals of Nuclear Energy
Reads 0
Downloads 0
ACS Style

Nils Haneklaus; Ewald Schnug; Harikrishnan Tulsidas; Bismark Tyobeka. Using high temperature gas-cooled reactors for greenhouse gas reduction and energy neutral production of phosphate fertilizers. Annals of Nuclear Energy 2015, 75, 275 -282.

AMA Style

Nils Haneklaus, Ewald Schnug, Harikrishnan Tulsidas, Bismark Tyobeka. Using high temperature gas-cooled reactors for greenhouse gas reduction and energy neutral production of phosphate fertilizers. Annals of Nuclear Energy. 2015; 75 ():275-282.

Chicago/Turabian Style

Nils Haneklaus; Ewald Schnug; Harikrishnan Tulsidas; Bismark Tyobeka. 2015. "Using high temperature gas-cooled reactors for greenhouse gas reduction and energy neutral production of phosphate fertilizers." Annals of Nuclear Energy 75, no. : 275-282.

Journal article
Published: 01 January 2014 in Procedia Engineering
Reads 0
Downloads 0
ACS Style

Ewald Schnug; Nils Haneklaus. Uranium, the Hidden Treasure in Phosphates. Procedia Engineering 2014, 83, 265 -269.

AMA Style

Ewald Schnug, Nils Haneklaus. Uranium, the Hidden Treasure in Phosphates. Procedia Engineering. 2014; 83 ():265-269.

Chicago/Turabian Style

Ewald Schnug; Nils Haneklaus. 2014. "Uranium, the Hidden Treasure in Phosphates." Procedia Engineering 83, no. : 265-269.