A central effort to battle the increasing global warming and climate change is to reduce CO2 emissions to the atmosphere from baseload centralized coal-fired power plants. Currently, the state-of-the-art technology for such flue-gas CO2 capture utilizes amine scrubbing. Unfortunately, this “chemical washing” process is energy intensive, costly and cumbersome, which has become the major hurdle to a widespread deployment. The estimated parasitic energy for the current amine scrubbing process is 702 kilojoules per kilogram of carbon dioxide (kJ kgCO2−1), which is about four times the thermodynamic minimum. While significant progress toward cost reduction and energy savings has been made in recent years, a large-scale commercial deployment of amine technology for CO2 capture depends on whether the cost and efficiency penalties are acceptable by the market. Thus, developing alternative energy-efficient and cost-effective carbon capture technologies is still of great interest.
Dual-phase mixed O2−/e− and CO32− conductors represent a new class of membranes that have emerged in recent years for high-temperature, high-flux, and selective CO2 capture from flue gas and fuel gas. In contrast to conventional size-sieving inorganic and solution-diffusion organic low-temperature rivalries, this new class of membranes can directly capture CO2 from high-temperature combustion streams in the form of CO32− under the gradient of electrochemical potentials of CO2 (and O2) across the membrane. To charge balance the flow of CO32−, a flow of counter-ion moving in the opposite direction is necessary. In practice, the counter-ion can be provided by either a solid metal (e−) or a solid O2− conducting oxide, which in turn also serves as the porous framework to immobilize the molten carbonate. The former metal-carbonate composite is referred to as mixed electron and carbon-ion conductor (or MECC), whereas the latter oxide-carbonate is referenced as mixed oxide-ion and carbonate-ion conductor (or MOCC).
Among these two types of dual-phase mixed conducting membranes, MECC is of particular interest because of its ability to directly separate CO2 and O2 from flue gas, which is a major source of CO2 emission on the earth. The first proof-of-concept of a MECC membrane employed stainless steel as the electron conducting phase. However, due to the severe corrosion problem by molten carbonate (MC), the membrane could not maintain a stable flux for a prolonged period. Recently, silver, a metal that chemically inert to MC, has been utilized as the solid electron conducting phase, where high flux with much improved stability were achieved. However, one of the problems with silver-based MECC membranes is the silver's propensity to sinter at high temperatures, causing gradual degradation in flux. In addition, the high cost of silver is another concern for future scaled-up applications, even though the coarsening issue can be mitigated to certain degree by overcoating the porous silver matrix with a layer of Al2O3 or ZrO2.
As such, a need exists for an MECC membrane for use in the separation of CO2 that is easily fabricated, that is cost effective, and that can withstand high temperatures without exhibiting a degradation in flux.
In one embodiment of the present invention, a membrane for carbon dioxide and oxygen separation is provided. The membrane includes a solid porous matrix; a molten carbonate phase; and an interphase disposed between the solid oxide porous substrate phase and the molten carbonate phase, where the membrane is a mixed electron and carbon-ion conductor membrane, and where the membrane exhibits a selectivity for carbon dioxide and oxygen over nitrogen ranging from about 100 to about 500 at a temperature of about 850° C.
In another embodiment, the solid oxide porous substrate can include a metal oxide, where the metal oxide includes nickel oxide, iron oxide, manganese oxide, cobalt oxide, or copper oxide.
In still another embodiment, the solid porous matrix can be impregnated with the molten carbonate phase.
In yet another embodiment, a volume % ratio of the solid porous matrix to the molten carbonate phase is from about 1.1 to about 1.8 prior to activation of the membrane by application of heat.
In one more embodiment, the interphase can be self-formed upon increasing the temperature of the membrane to a temperature ranging from about 650° C. to about 850° C.
In an additional embodiment, the interphase can include a lithiated metal oxide having the following formula: LixB2-xO2 where B is nickel, iron, manganese, cobalt, or copper nickel oxide. For instance, the lithiated metal oxide can be a lithiated nickel oxide such as Li0.4Ni1.6O2.
In one particular embodiment, the membrane can have a thickness ranging from about 0.6 millimeters to about 4 millimeters.
In another embodiment, the interphase can have a thickness ranging from about 50 nanometers to about 150 nanometers.
In still another embodiment, the membrane can exhibit a carbon dioxide flux density ranging from about 0.95 milliliters/(minute·cm2) to about 1.5 milliliters/(minute·cm2) at a temperature of about 850° C.
In another embodiment of the present invention, a method of forming a membrane for carbon dioxide separation is provided. The method includes forming a solid porous matrix; impregnating the solid porous matrix with a molten carbonate phase; and heating the molten carbonate phase impregnated solid porous matrix to a temperature ranging from about 650° C. to about 850° C., where an interphase is formed in situ between the solid porous matrix and the molten carbonate phase, where the membrane is a mixed electron and carbon-ion conductor membrane.
In one embodiment, the membrane can exhibit a selectivity for carbon dioxide and oxygen over nitrogen ranging from about 100 to about 500 at a temperature of about 850° C.
In still another embodiment, the solid oxide porous substrate can include a metal oxide, wherein the metal oxide includes nickel oxide, iron oxide, manganese oxide, cobalt oxide, or copper oxide.
In yet another embodiment, the interphase can include a lithiated metal oxide having the following formula: LixB2-xO2, where B is nickel, iron, manganese, cobalt, or copper. For instance, the lithiated metal oxide can be a lithiated nickel oxide such as Li0.4Ni1.6O2.
In one more embodiment, the membrane can have a thickness ranging from about 0.6 millimeters to about 4 millimeters.
In an additional embodiment, the interphase can have a thickness ranging from about 50 nanometers to about 150 nanometers.
In another embodiment, the membrane can exhibit a carbon dioxide flux density ranging from about 0.95 milliliters/(minute·cm2) to about 1.5 milliliters/(minute·cm2) at a temperature of about 850° C.
In still another embodiment, a volume % ratio of the solid porous matrix to the molten carbonate phase can be about 1.1 to about 1.8 prior to heating the molten carbonate phase impregnated solid porous matrix.
A method of separating carbon dioxide, oxygen, or a combination thereof from a stream of flue gas is also contemplated, where the method includes contacting the stream of flue gas with the membrane described above.
Other features and aspects of the present invention are set forth in greater detail below.
A full and enabling disclosure of the present invention, including the best mode thereof to one skilled in the art, is set forth more particularly in the remainder of the specification, which includes reference to the accompanying figures.
Repeat use of reference characters in the present specification and drawings is intended to represent the same or analogous features or elements of the present invention.
Reference now will be made to the embodiments of the invention, one or more examples of which are set forth below. Each example is provided by way of an explanation of the invention, not as a limitation of the invention. In fact, it will be apparent to those skilled in the art that various modifications and variations can be made in the invention without departing from the scope or spirit of the invention. For instance, features illustrated or described as one embodiment can be used on another embodiment to yield still a further embodiment. Thus, it is intended that the present invention cover such modifications and variations as come within the scope of the appended claims and their equivalents. It is to be understood by one of ordinary skill in the art that the present discussion is a description of exemplary embodiments only, and is not intended as limiting the broader aspects of the present invention, which broader aspects are embodied exemplary constructions.
Generally speaking, the present invention is directed to a low-cost and easy-to-fabricate mixed electron and carbonate-ion conducting membrane for advanced high-flux and selective electrochemical CO2 separation from flue gas. The membrane can include a carbonate-ion conducting molten carbonate phase and an electron conducting lithiated nickel (Ni)-oxide interphase that is formed in situ during operation. The testing results in the examples below explicitly show that the membrane contemplated by the present invention is capable of achieving a CO2 flux density that is greater than about 0.95 milliliters/(minute·cm2) with a selectivity ranging from about 100 to about 500 at 850° C. and excellent stability for up to about 450 hours. Evidence is also provided to support that the self-formed interphase is Li04Ni1.6O2 is highly electron conducting and responsible for providing electrons to the co-reduction of CO2 and O2 into carbonate-ion (CO32−). Given the performance level demonstrated, this low-cost and easy-to-fabricate membrane is superior to the conventional “size-sieving” inorganic and “dissolution-diffusion” organic counterparts, promising it to be a very competitive technology for future advanced CO2 capture from flue gas.
Specifically, the membrane can include a mixed electron and carbon-ion conductor (or MECC) membrane that includes a solid porous matrix. The solid porous matrix can include a metal oxide such as a manganese (Mn) oxide, an iron (Fe) oxide, a cobalt (Co) oxide, a copper (Cu) oxide, or any suitable complex oxide that can be lithiated to form an interphase layer that includes a lithiated metal oxide as represented by the formula LixB2-xO2, where B is Fe, Mn, Ni, Co, or Cu. In one particular embodiment, the solid porous matrix includes a nickel oxide (NiO) matrix as the solid electron conducting phase, which is impregnated with a molten carbonate (MC) phase, where the molten carbonate serves as the carbon-ion conducting phase. The molten carbonate used to form the MECC membrane can, for example, include a eutectic mixture of Li2CO3 and Na2CO3 at a mole % ratio of Li2CO3 to Na2CO3 ranging from about 1.01 to about 1.3, such as from about 1.02 to about 1.2, such as from about 1.04 to about 1.1. In one particular embodiment, the molten carbonate can include about 52 mol % Li2CO3 and 48 mol % Na2CO3.
Further, the pre-activation NiO-MC MECC membrane can have a volume % ratio of NiO to MC ranging from about 1.1 to about 1.8, such as from about 1.2 to about 1.7, such as from about 1.3 to about 1.6. In one particular embodiment, the NiO can be present at volume % of about 60 vol %, while the MC can be present at a volume % of about 40 vol %. At high temperatures, such as a temperatures of about 750° C., the NiO phase spontaneously reacts with MC phase, self-forming an electron conductive lithiated NiO layer (e.g., Li0.4Ni1.6O2) at the interface of the NiO and MC to serve as an electron conductor and enable the CO2-capture reaction CO2+½O2+2e−=CO32− at the CO2—O2/e−/CO32− triple phase boundaries (TPBs). Such a self-forming MECC membrane is schematically illustrated in
The resulting membrane can have a thickness ranging from about 0.6 millimeters (mm) to about 4 mm, such as from about 0.7 mm to about 3.5 mm, such as from about 0.8 mm to about 3 mm. Further, the self-formed interphase can have a thickness ranging from about 50 nanometers (nm) to about 150 nm, such as from about 75 nm to about 125 nm, such as from about 90 nm to about 110 nm. In addition, the membrane can exhibit a selectivity for carbon dioxide and oxygen over nitrogen at a temperature of about 850° C. ranging from about 100 to about 500, such as from about 125 to about 495, such as from about 150 to about 490 over an extended time period, such as a time period ranging from about 1 hour to about 500 hours, such as from about 10 hours to about 475 hours, such as from about 100 hours to about 450 hours. Moreover, the membrane is capable of achieving a CO2 flux density ranging from about 0.80 milliliters/(minute·cm2) to about 1.5 milliliters/(minute·cm2), such as from about 0.85 milliliters/(minute·cm2) to about 1.4 milliliters/(minute·cm2), about 0.90 milliliters/(minute·cm2) to about 1.3 milliliters/(minute·cm2) at a temperature of about 850° C. and over an extended time period, such as a time period ranging from about 1 hour to about 500 hours, such as from about 10 hours to about 475 hours, such as from about 100 hours to about 450 hours. Further, it is capable of achieving an O2 flux density ranging from about 0.35 milliliters/(minute·cm2) to about 0.65 milliliters/(minute·cm2), such as from about 0.40 milliliters/(minute·cm2) to about 0.60 milliliters/(minute·cm2), about 0.45 milliliters/(minute·cm2) to about 0.55 milliliters/(minute cm2) at a temperature of about 850° C. and over an extended time period, such as a time period ranging from about 1 hour to about 500 hours, such as from about 10 hours to about 475 hours, such as from about 100 hours to about 450 hours. In contrast, silver and molten carbonate based membranes exhibit decreased selectivity and flux.
Further, the membrane of the present invention can exhibit a CO2 permeance of about 4.5×10−7 mol m−2 s−1 Pa−1 to about 7×10−7 mol m−2 s−1 Pa−1, such as from about 4.75×10−7 mol m−2 s−1 Pa−1 to about 6.75×10−7 mol m−2 s−1 Pa−1, such as from about 5×10−7 mol m−2 s−1 Pa1 to about 6.5×10−7 mol m−2 s−1 Pa−1 at 850° C. and at a selectivity ranging from about 430 to about 470. In addition, the interphase (e.g., the lithiated nickel oxide (LNO) layer) of the membrane of the present invention can exhibit a conductivity in air or argon (Ar) ranging from about 180 S/cm to about 300 S/cm, such as from about 190 S/cm to about 280 S/cm, such as from about 200 S/cm to about 260 S/cm at temperatures ranging from about 550° C. to about 850° C. Such high levels of electrical conductivity measurement confirm that LNO is a highly conductive phase and is responsible for the observed CO2 transport in the NiO-MC based MECC membrane contemplated by the present invention.
In order to form and activate the membrane of the present invention such that is at least partially conducting to enable the transport and separation of CO2 and O2 from flue gas, a solid porous matrix is first provided, where the solid porous matrix can include nickel oxide. Then, the solid porous matrix is impregnated with a molten carbonate phase, after which the solid porous matrix and molten carbonate are heated to a temperature ranging from about 650° C. to about 850° C., such as from about 675° C. to about 825° C., such as from about 700° C. to about 800° C., which results in the in situ formation of an interphase layer due to the spontaneous reaction of the nickel oxide matrix with the MC phase, self-forming an electron conductive lithiated NiO layer (e.g., Li0.4Ni1.6O2) at the interface of the NiO and MC to serve as an electron conductor and enable the CO2-capture reaction CO2+½O2+2e−=CO32− at the CO2—O2/e−/CO32− triple phase boundaries (TPBs). The resulting membrane can then be used to separate carbon dioxide and oxygen from a stream of flue gas by contacting the stream of flue gas with the membrane.
The present invention may be better understood with reference to the following example.
Example 1 discusses various test data compiled for the mixed electron and carbon-ion conductor (or MECC) membrane of the present invention.
Sample Preparation
The porous NiO matrix was prepared as follows. Briefly, NiO powder (99.9% metal basis, Alfa Aesar) were intimately mixed in ethanol with carbon black as a pore former at volume ratios of NiO powder to carbon black of 5:5, 6:4, 7:3 and 8:2, respectively. The dried powder mixtures were then pressed into pellets under 70 MPa pressure, followed by sintering at 1,350° C. for 12 hours in air to remove the carbon pore former and achieve good mechanical strength. The fabricated porous NiO matrix was then impregnated with a 52 mol % Li2CO3-48 mol % Na2CO3 molten carbonate (denoted as MC) at 650° C. for 2 hours to form a dense membrane. The weight increase of the pellet after MC impregnation was about 20%. After MC infiltration, the surface of the resulting NiO-MC membrane was thoroughly cleaned by sandpaper.
Flux Measurement
The flux densities of CO2—O2 permeation of the membrane were evaluated by a homemade permeation cell system as shown in
where CCO
X-Ray Diffraction
The room temperature phase compositions of NiO, MC and NiO-MC after firing at 850° C. were examined by an X-ray diffractometer (Rigaku, Japan) equipped with a graphite-monochromatized CuKa radiation (λ=1.5418 Å). The 2θ scans were performed at a rate of 8° min−1 in a range of 20°-90°. The high-temperature XRD was performed in a temperature range of 550° C.−800° C. in air using a high-temperature (HT) X-ray diffractometer (X1 Theta-Theta, Scintag, USA) equipped with graphite-monochromatized Cu Kα radiation (λ=1.5418 Å) over a 2θ=20°-90° range in a step size of 0.02° at a scanning rate of 1° per minute. During the measurement, approximately 1 hour of equilibrium time was given at each temperature before data collection.
SEM/TEM Examination
The cross-sectional views of the NiO-MC membrane before and after testing were characterized by a scanning electron microscope (SEM) (FESEM, Zeiss Ultra) equipped with Energy dispersive X-ray spectrometry (EDX). The Focused Ion Beam (FIB, Hitachi NB-5000) technique was used to prepare sample from a post-tested NiO-MC membrane for TEM (H-9500, Hitachi) imaging and chemical analysis. The procedure to prepare FIB sample includes: 1) deposition of a carbon layer (4×12 microns) using Ga-gun on top surface of the sample; 2) deposition of a W layer (4×12 microns) using Ga-gun on top of the C layer; 3) use of 40 kV and 68.36 nA to cut around the deposited layer; 4) tilting 58 degrees and cutting at the bottom of the sample; 5) placing the sample to the original position and welding one end of the sample to a probe; 6) cutting the arm on the left side of the sample; 7) placing the sample attached to the probe on the cross sectional surface of a half TEM grid, followed by welding to that surface; 8) cutting off the probe; 9) thinning the cut sample (4×12×12 microns) on the TEM grid by the following condition: 40 kV and 3.55 nA to about 0.7 microns thickness; 40 kV and 0.67 nA to around 200 nm thickness; 40 kV and 0.07 nA to less than 100 nm thickness; final cleaning the cut surfaces at 5 kV and 0.03 nA.
Electrical Conductivity Measurement
The conductivity of a NiO and LNO bar sample having of 25.8 mm×2.9 mm×5.0 mm was measured using a standard four-probe method in air and Ar from 550° C. to 850° C. with the E-I module in the CorrWare software within a Solartron 1287/1260 electrochemical workstation system.
CO2/O2 Permeation Rate Vs. Temperature
The initial “pre-activation” flux performance of a lithiated NiO-MC (NiO:MC=60:40 (vol %)) MECC membrane with a thickness of 1.0 mm is shown in
The theoretical selectivity of CO2+O2 for this electrochemical membrane should be 100% since only CO32− is allowed to pass through the dense MECC membrane. However, in reality there is always a small fraction of physical leakage associated with the membrane or gas seals, inadvertently mixing N2 into the permeated CO2+O2 stream and lowering product purity. To better evaluate the leakage issue and thus product selectivity, we use the ratio of (CO2+O2) flux density sum (JCO2+JO2) over N2 flux density (JN2), (JCO2+JO2)/JN2, as a measure of the selectivity for MECC membranes; the results are co-plotted with flux density in
Given the fact that NiO is by no means a good electronic conductor, all of the data shown so far suggest that there should be a new phase formed during operation with better electronic conductivity responsible for fast e− conduction needed for the co-reduction of CO2 and O2 into CO32−. The flux also increases with, which suggests that the formation of this electron conducting phase is kinetically limited. Upon full formation, the activation energy for CO2/O2 transport is also reduced. The data presented in
Effect of NiO/MC Volumetric Ratio
Since the membrane is a dual-phase composite, the volumetric ratio of the two phases may have impact on the performance.
Effect of Membrane Thickness
The effect of membrane thickness can be theoretically predicted from modified Wagner equation describing the permeation flux in the bulk of a dual-phase e−/CO32− conducting membrane:
where ε is the porosity of the porous NiO matrix; τp and τs are the tortuosity of pore (or MC phase) and solid NiO phases, respectively; R is the gas constant, 8.314 J mol−1 K−1; T is the absolute temperature, K; F is Faraday's constant, 96485 C mol−1; L is the thickness of the membrane, cm; σco
for all the measuring conditions, equation (3) can be simplified into
According to the stoichiometry requirement,
Since R, T, F, ε, τp, PCO
Flux Stability
Long-term flux stability is an important property of the membrane for practical applications. Therefore, the flux stability of the lithiated NiO-MC MECC membrane (1.2 mm thick) was tested at 850° C.; the results are shown in
The selectivity of the membrane was also calculated and is plotted in
At a higher membrane thickness (2.3 mm),
To compare the flux/selectivity performance of lithiated NiO-MC membrane with that of “size-sieving” and “dissolution-diffusion” types of membranes working under a substantial pressure differential, the flux densities of CO2 in
Microscopic Evidence of Self-Forming Electronic Phase
To understand the fundamental reason for the above flux behavior observed in the NiO-MC membranes, a detailed microscopic analysis on pre-test and post-test samples was performed. The original microstructure and elemental mapping of a fractured membrane before testing are shown in
To further examine the morphology and chemistry of this new interfacial phase, STEM imaging/EDX of a sample prepared by Focused Ion Beam (FIB) technique was performed.
X-Ray Diffraction
To determine the composition of the interphase, we performed an in situ high-temperature X-ray diffraction (HT-XRD) analysis on a NiO—Li2CO3 (NiO:Li2CO3=1.6:0.22 mol) mixture in a temperature range of room temperature to 850° C. and air. The collected XRD patterns are shown in
It is also noted from
Electrical Conductivity
Thus far, it has been confirmed that the new phase formed at NiO and MC interface is Li0.4Ni1.6O2 (LNO). A natural question to ask at this point is whether this phase responsible for the electronic conduction needed for CO2/O2 co-reduction to CO32−. To answer this question, we separately synthesized a LNO bar sample and measured its electrical conductivity with 4-probe techniques from 550° C. to 850° C. in air and argon (Ar). The results are presented in
In summary, this Example demonstrates a new type of low-cost and easy-to-fabricate self-forming NiO-MC based MECC membrane for high-flux and selective electrochemical CO2 capture from flue gas. The highly electron conducting phase Li0.4Ni1.6O2 (LNO) is formed in situ at the interface of NiO and MC during high temperature operation. Such a self-forming MECC membrane exhibits excellent CO2/O2 flux density and selectivity with outstanding stability. Given the fact that NiO is resistant to sintering and cost effective compared to silver, the NiO-MC based MECC membrane could replace the expensive Ag-MC rivalry and be a promising practical membrane candidate for advanced CO2 membrane reactors.
These and other modifications and variations to the present invention may be practiced by those of ordinary skill in the art, without departing from the spirit and scope of the present invention, which is more particularly set forth in the appended claims. In addition, it should be understood the aspects of the various embodiments may be interchanged both in whole or in part. Furthermore, those of ordinary skill in the art will appreciate that the foregoing description is by way of example only, and is not intended to limit the invention so further described in the appended claims.
The present application claims priority to U.S. Provisional Application Ser. No. 62/533,769 filed on Jul. 18, 2017, the disclosure of which is incorporated by reference herein.
This invention was made with Government support under Contract Nos. CBET-1340269 and CBET-1401280, awarded by the National Science Foundation. The Government has certain rights in the invention.
Number | Name | Date | Kind |
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6793711 | Sammells | Sep 2004 | B1 |
20080115667 | Lee | May 2008 | A1 |
20090101008 | Lackner | Apr 2009 | A1 |
20110168572 | Huang | Jul 2011 | A1 |
20120014852 | Huang | Jan 2012 | A1 |
20150090125 | Lin | Apr 2015 | A1 |
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Number | Date | Country | |
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20190022576 A1 | Jan 2019 | US |
Number | Date | Country | |
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62533769 | Jul 2017 | US |